Highlights
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The structure–property relationship of PdSe2 is discussed, i.e., layer number vs. tunable bandgap, pentagonal structure vs. anisotropy-based polarized light detection.
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The synthesis approaches of PdSe2 are thoroughly compared, including bottom-up methods such as chemical vapor transport for bulk crystals, chemical vapor deposition for thin films and single-crystal domains, selenization of Pd films. Besides, top-down strategies are discussed, covering the mechanical exfoliation of bulk crystals, plasma thinning, and vacuum annealing as well as phase transition.
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The emerging devices of PdSe2 and its van der Waals heterostructures have been delivered such as metal/semiconductor contact, Schottky junction transistors, field-effect transistors, photodetectors, p–n junction-based rectifiers, polarized light detector, and infrared image sensors.
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Future opportunities of PdSe2-based van der Waals heterostructures are given including logic gate-based digital circuits, RF-integrated circuits, Internet of Things, and theoretical calculation as well as big data for materials science.
Abstract
The rapid development of two-dimensional (2D) transition-metal dichalcogenides has been possible owing to their special structures and remarkable properties. In particular, palladium diselenide (PdSe2) with a novel pentagonal structure and unique physical characteristics have recently attracted extensive research interest. Consequently, tremendous research progress has been achieved regarding the physics, chemistry, and electronics of PdSe2. Accordingly, in this review, we recapitulate and summarize the most recent research on PdSe2, including its structure, properties, synthesis, and applications. First, a mechanical exfoliation method to obtain PdSe2 nanosheets is introduced, and large-area synthesis strategies are explained with respect to chemical vapor deposition and metal selenization. Next, the electronic and optoelectronic properties of PdSe2 and related heterostructures, such as field-effect transistors, photodetectors, sensors, and thermoelectric devices, are discussed. Subsequently, the integration of systems into infrared image sensors on the basis of PdSe2 van der Waals heterostructures is explored. Finally, future opportunities are highlighted to serve as a general guide for physicists, chemists, materials scientists, and engineers. Therefore, this comprehensive review may shed light on the research conducted by the 2D material community.
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1 Introduction
Significant research has been conducted on two-dimensional (2D) materials, including conductors (graphene) [1], semiconductors (MoS2), superconductors (NbSe2), and insulators (h-BN). The family of 2D-layered materials, possessing unique structures and extraordinary physical and chemical properties, has been continuously expanded with the addition of members such as transition-metal dichalcogenides (TMDCs) [2], phosphorene, borophene, and MXenes. These 2D materials have been widely employed in biomedical engineering [3], electronics and optoelectronics, photonics, optics, and related devices. Besides, 2D materials have boosted the field of smart sensing such as gas sensors [4]. They exhibit significant potential in devices such as photodetectors and photovoltaic cells; this is attributed to their distinct resonance absorption in the visible to near-infrared spectrum.
The family of TMDCs is an important component of 2D materials with a general formula of MX2, where M is a transition element and X is a chalcogen element. According to the International Union of Pure and Applied Chemistry (IUPAC) [5], transition elements generally comprise those from group 3 to group 12. TMDCs exhibit remarkable properties such as tunable bandgap, stability in air, and good charge transport, which is of great significance to the development of modern technology. Currently, more commonly discussed TMDCs are group-6 TMDCs [6], which primarily include MoS2, MoSe2, MoTe2, WS2, WSe2, and WTe2. Recently, 2D TMDCs and their heterojunction have attracted more and more research interest in the field of broadband photodetectors due to their excellent electronic and optoelectronic properties and show broadband photodetection from UV to IR [7]. In fact, TMDCs have retained significant research value for fundamental physics and device applications.
1.1 Emerging Noble Transition-Metal Dichalcogenides
Dichalcogenides of group-10 transition metals MX2 (M = Pd, Pt, X = S, Se, Te) have recently received increased research attention owing to their novel properties. They are often referred to as noble transition-metal dichalcogenides (nTMDCs) because all the metal elements in group 10 are noble metals [8]. Here, nTMDCs [9] primarily refer to PtS2, PdS2, PtSe2, and PdSe2, and they show a significant intrinsic nature resulting from rich d-electron content. Besides, PtTe2-based photodetectors demonstrate an air stable and high performance in MIR photodetection up to 10.6 µm [10].
The fundamental properties of the selected nTMDCs are listed in Table 1. The nTMDCs are, however, yet to be fully understood; therefore, there is much scope for research in this area.
Before introducing the PdSe2, we first look at the properties of other nTMDCs. PtS2 exhibits very strong interlayer interactions and layer-dependent indirect bandgaps ranging from 1.6 (monolayer) to 0.25 (bulk) eV. In recent years, few-layer PtS2 has become a promising material for field-effect transistors (FETs) with high mobility and on/off ratios. Furthermore, PtS2-based devices have demonstrated excellent performance with respect to photodetection and sensing. Similarly, 2D PtSe2 shows prominent layer-dependent properties, and the bandgap of monolayer PtSe2 is 1.2 eV, while that of bulk PtSe2 is zero. The carrier mobility of few-layer PtSe2 can theoretically exceed 103 cm2 V−1 s−1, and very high stability in air is demonstrated [11]. Few-layered PtSe2 has been utilized in a variety of applications, such as FETs and photodetectors. PtSe2 shows good potential in piezoelectric devices, saturable absorbers, and electrochemical energy conversion. The structure of PdS2 comprises a pentagonal network, which includes two Pd atoms and three S atoms distributed on the atomic plane [12]. Monolayer PdS2 has two stable structures: one is a standard 1 T structure and the other involves a bulk-like geometry [13]. Through predictions and calculations, monolayer PdS2 has been determined to possess a semiconducting feature with a bandgap of approximately 1.1 eV, while bilayer PdS2 possesses a semimetallic feature [14]. Through first-principle calculations, a few-layer PdS2 has been predicted theoretically with good electronic and optoelectronic properties. However, few experimental synthesis studies have been reported in this regard. Thus far, there remain good opportunities for the material optimization and device applications of PdS2. But PdS2 pentagonal structure is not thermodynamically stable, which limits its applications. Hence, PdSe2 becomes of importance for exploiting the polarization properties and related optoelectronic applications.
1.2 Importance of PdSe2
PdSe2 exhibits unique physical properties such as high carrier mobility, tunable bandgaps, and magnetic transport. PdSe2 has become a popular 2D material owing to its good stability [15], layer-dependent bandgap, and in-plane optical anisotropy [16]. PdSe2 (Scheme 1) has been integrated into electronic [17], thermoelectric, optical [18], and optoelectronic devices [19]. The diverse polymorphisms of PdSe2 provide the platform for investigating the topological states and the applications of quantum information devices [20].
PdSe2-based van der Waals heterostructures (vdWHs) have been widely incorporated in current rectifier, polarized light photodetector, and infrared image sensor applications. First, the direct synthesis of PdSe2-based vdWHs has been investigated via deposition of PdSe2 over other 2D materials such as graphene [21], MoS2 [22], MoSe2 [23], GeSe [24], and SnSe2. The stacking with arrayed nanomaterials gives rise to heterostructure devices such as ZnO nanorods and Si nanowires [25]. A perovskite [26] heterostructure can be formed with PdSe2 using a self-powered image sensor.
In this review, we discuss the most recent developments with regard to PdSe2 and its vdWHs, including approaches for its synthesis and its application in electronics, optoelectronics, and optics. We believe that this comprehensive contribution may attract the attention of research communities as well as industrial engineers interested in PdSe2 material development and device integration.
2 Structure and Properties of PdSe2
This section introduces in detail the crystalline structure, electronic structure, energy band, vibrational phonon modes, and phase transition of PdSe2, which are the bases of its application in various fields.
2.1 Crystal Structure
As a 2D-puckered pentagonal material, PdSe2 possesses orthorhombic lattices and a low symmetry, and it was identified as the first TMDC with a pentagonal structure [27]. The crystalline structure of PdSe2 has been studied from as early as 1952 [28], owing to which a good foundation for current research has been laid. Most recently, 2D materials with pentagonal structures have attracted much research attention. Examples include penta-graphene, penta-PdS2 [12], penta-SnS2, penta-silicene, and penta-germanene. The structures of these pentagonal materials differ from most hexagonal structures in 2D materials with high symmetry. They can still possess a relatively low symmetry in regular corrugated modes. Therefore, unique physical properties emerge with pentagonal structures, leading to novel electronic applications.
Figure 1a shows the top and side views of the monolayer PdSe2 structure; it can be clearly seen that the one-unit cell contains four Pd atoms and eight Se atoms (top plane). In one PdSe2 layer, the two Se atoms cross the Pd layer in the form of a Se–Se dumbbell (bottom plane).
The uncommon layered structure is composed entirely of pentagonal rings, in which each Pd atom binds to four Se atoms, and two adjacent Se atoms form a covalent bond in one layer [23]. Hence, there exists no dangling bond in one PdSe2 layer, and these layers interact via van der Waals forces, resulting in excellent stability in air. The lattice parameters a, b, and c are, respectively, 5.75, 5.87, and 7.69 Å for PdSe2. Each layer of PdSe2 crystal has a vertical puckering height of 1.6 Å, where Pd atoms exhibit an unusual planar tetra-coordination [15].
Figure 1b shows the corresponding three-dimensional (3D) schematic of a monolayer PdSe2 structure from a projected top view and side view [15], which is similar to that of black phosphorus (BP).
Figure 1c, d exhibits the annular dark-field (ADF) image of the PdSe2 crystals, as generated via scanning transmission electron microscopy (STEM), as well as the corresponding image simulations (Fig. 1e, f) [15]. This approach can well prevent the formation of the disordered region of PdSe2 flakes due to the transfer process onto the TEM grid. As can be seen, owing to the difference in symmetry, the even and odd layers of PdSe2 flakes can give rise to a variation in the ADF images. Nonetheless, these patterns are in good agreement with the corresponding image simulations [15]. Moreover, the STEM images verify the puckered structure with waved Pd–Se layers of PdSe2.
The morphology and structure of PdSe2 have shown satisfactory property–structure correlation. Indeed, the anisotropic orientation of the PdSe2 domains results in polarized light detection [29]. The strain engineering influences the phonon response, which demonstrates its potential in the field of flexible electronics. Defect engineering such as vacancies could affect the air stability of the PdSe2 transistor as well as the Ohmic contact. The phase transition mechanism should be investigated for a better understanding, and more new phases of PdSe2 can be exploited for further applications. The high-pressure induced phase of PdSe2 renders a photovoltaic material. The hexagonal T phase of PdSe2 resulted in a high-efficiency solar cell. The pyrite phase PdSe2 exhibits superconductivity induced by high pressure.
Bulk PdSe2 crystals display D2h point group symmetry and Pbca space group symmetry [28]. The pentagonal PdSe2 belongs to the phase of marcasite in the crystal system of orthorhombic [27]. By comparison, thin PdSe2 flakes with an odd number of layers are allocated to space group P21/c (No. 14) and point group C2h (2/m), which possess inversion symmetry, while thin PdSe2 flakes with an even number of layers are allocated to space group Pca21 (No. 29) and point group C2v (mm2), which do not possess inversion symmetry [15].
2.2 Electron Orbital Properties
The conventional hexagonal structures are featured with isotropy, e.g., MoS2. The symmetrical hexagons lead to weak interlayer interaction due to the d4sp hybridization in TMDCs [20]. Here, the Mo and W elements are in lack of d orbital electrons. Besides, the d orbital of Pt atom and pz orbital of S atom are hybridized into d2sp3 type, which accounts for the strong interlayer interaction in PtS2 [30].
But the hybridization between Pd and Se orbitals is complicated in PdSe2. First, one need to understand the electron configuration of these two elements. The Pd metal has a fully occupied d orbital with electron configuration of [Kr]4d10. And the Se is a p-block element, with an electron configuration of [Ar]3d104s24p4. In a single-layer PdSe2, one Pd atom is coordinated to four Se atoms, forming a square-planar structure [31]. Quite often, the Pd2+ results in the d8 configuration such as PdCl2. Therefore, the PdSe2 possesses a phase of marcasite analogous to the FeS2 [27]. The weak hybridization occurs between the 4dz2 orbitals of Pd atom and 4pz/3dz2 orbitals of Se atom, which led to the low symmetry [31].
The hybridization of Pd 4d orbit and Se 4p orbit has resulted in the covalent bond in PdSe2 [32]. The bands near Fermi level are contributed by the p orbitals of Se element. The conductance band minimum and valence band maximum of monolayer PdSe2 have stemmed from the p states of Se and d states of Pd. The spin–orbital coupling does not influence the electronic structure of monolayer PdSe2 [33]. But, with increasing the layer number, the interlayer coupling becomes strong and decreases the bandgap of bilayer and trilayer PdSe2 compared with monolayer PdSe2 [32]. Besides, the stacking types determine the bandgap of PdSe2, e.g., the AA and AB stacking for bilayer PdSe2 and the AAA, ABA, and ABB stacking for trilayer PdSe2 [32].
Indeed, the pentagonal PdSe2 is analogous to other puckered 2D materials, i.e., phosphorene and silicene, which feature with anisotropy [15]. The buckling of puckered 2D materials lead to a strong spin–orbital coupling between adjacent two layers, which is accounted for the topological quantum phase transition.
With the doping of transition-metal atoms such as Cr and Mn, new energy levels were introduced into the band structure of PdSe2 [34], which decrease its bandgap and introduce new spin nondegenerate states. These spin states around the Fermi level could cause the spin polarization.
After knowing the electron orbital theory, we now come to discuss the band structure of PdSe2.
2.3 Electronic Band Structure
This section discusses the electronic energy band structures and density of states (DOSs) of PdSe2. Similar to that of most layered TMDCs, the indirect bandgap of PdSe2 largely depends on the number of layers.
The bandgap of PdSe2 has been calculated [33] via the approaches of generalized gradient approximation (GGA), density functional theory (DFT) of Perdew, Burke, and Ernzerhof (PBE). Here, the bandgap of PdSe2 is defined as the energy difference between the valence band (VB) and the conduction band (CB). The indirect bandgap of monolayer PdSe2 with semiconducting characteristics is 1.33 eV (Fig. 2a), and this decreases with the increase in the number of PdSe2 layers until the bulk PdSe2 has no bandgap (0 eV) with semimetallic characteristics (Fig. 2d).
In the cases of TMDCs and phosphorene, the valence band maximum (VBM) and conduction band minimum (CBM) are located along the high-symmetry lines. However, in the electronic structure of PdSe2 [35], VBM is located between the high-symmetry Γ and X, while the CBM is located between M and Γ (Fig. 2a).
Meanwhile, the effects of strain, particularly biaxial strains, have been investigated on the electronic and optical properties of PdSe2 [36]. Figure 2b, c shows the evolution of the monolayer PdSe2 energy bands under compressive and tensile strains, respectively. The black line represents the energy band of PdSe2 in the unstrained state, while the other colors represent the energy bands of PdSe2 in the various strained states. The compressive and tensile strains decrease the CBM and increase the VBM of monolayer PdSe2, and the VBM and CBM rise to a maximum value for compressive or tensile strains of –10%, leading to the minimum bandgap of monolayer PdSe2 [35]. Moreover, under compressive strain along the x-direction, the monolayer PdSe2 shows a negative Poisson’s ratio, possibly resulting from the Se–Se bond [37].
Figure 2d shows the energy band of bulk PdSe2, where the electronic structure shows a negative indirect bandgap with semimetallic characteristics at the DFT level. However, VB and CB are not entangled around the Fermi level [33]. A semimetallic feature of bulk PdSe2 can be observed through ultraviolet photoemission spectroscopy [26] and optical absorption [25]. However, bulk PdSe2 exhibits semiconducting characteristics from resistivity experiments [38]. Hence, further research is necessary to understand the bandgap of bulk PdSe2 better owing to this contradiction.
Figure 2e reveals the electronic band structure of bulk PdSe2 calculated via DFT under the tensile stress of –1.0 GPa, whereby a bandgap of 0.48 eV is observed. When uniaxial tensile stress is applied to bulk PdSe2 along the out-of-plane direction, the lattice parameter c and interlayer distance increase [33]. In orthorhombic PdSe2, the bandgap is positively correlated with the interlayer distance, indicating that the interlayer interaction has a significant influence on the electronic structure. Figure 2f shows the interlayer spacing (dlayers) and bandgap of bulk PdSe2 as a function of the uniaxial tensile stress. As the interlayer spacing increases, VBM decreases dramatically, while CBM increases slightly, resulting in an increase in the bandgap of bulk PdSe2.
Figure 3 depicts the electronic DOSs for both bulk and monolayer PdSe2 calculated in denser k meshes with values of 23 × 23 × 17 and 40 × 40 × 1, respectively [27]. In the inset of Fig. 3a, the bandgap of bulk PdSe2 is 0.03 eV, while that of monolayer PdSe2 is approximately 1.43 eV (Fig. 3b). These values are slightly higher than the bandgap values obtained through the traditional GGA-PBE functional, indicating an underestimation of the bandgap value. This uncertainty of the bandgap may be because PdSe2 has a high number of defects and in-plane anisotropic absorption properties.
In each layer, covalent bonding results in a distinct hybridization between the Pd 4d and Se 4p states. The projected DOSs show that the Pd 4d and Se 4p states contribute the most to the VBM and CBM, and the more substantial contribution of Pd 4d orbitals to the total DOSs increases at an energy below –1 eV [27].
2.4 Vibrational Phonon Modes
Raman spectroscopy, which is a critical technique for 2D material characterization, was utilized to investigate the PdSe2 structure. In the Raman spectra of PdSe2, the peak position and intensity are shown to change anomalously with different numbers of PdSe2 layers, resulting from the electronic hybridization and strong interlayer coupling in the PdSe2 crystal [15].
To provide a better understanding, Fig. 4a shows the Raman spectra of PdSe2 samples from monolayer to bulk, which demonstrates the evolution of the PdSe2 vibrational modes. There are four obvious peaks in the high-frequency (HF) Raman spectra region (100–300 cm−1), including six atomic vibrational modes [15]. The six peaks are at 144.3, 146.9, 206.7, 222.7, 257.8, and 268.6 cm−1, and the corresponding Ag1, B1g1, Ag2, B1g2, Ag3, and B1g3 phonon modes of PdSe2 are marked with dotted lines in Fig. 4a. As the number of PdSe2 layers increases, the major peaks show a red shift, with the B1g1 peak changing the most and the Ag3 peak changing the least. The main reasons for this are the in-plane lattice constant variations and the strong interlayer coupling of PdSe2, which causes abnormal shifts and a broad bandgap [15].
Figure 4b shows six atomic vibrational models, where the purple arrows represent the relative movements between the Pd and Se atoms. Among all the vibrational modes of PdSe2, the vibrations of Se–Se atoms are predominant. Indeed, the Se–Se bond presents a much stronger vibration intensity than that of the Pd–Se bond [39]. Moreover, there are three peaks in the low-wavenumber region (approximately at 101, 121, and 130 cm−1) owing to variations in the symmetry. As the number of PdSe2 layers decreases, the space group transforms from Pbca to Pca21, leading to the emergence of the B1g3 mode and new peaks (268.6 cm−1) in few-layer PdSe2.
Low-frequency (LF) Raman spectroscopy (< 100 cm−1) was used to study the layer characteristics of PdSe2 further. As the two primary LF features, the breathing and shear modes pertain to the interlayer vibrational modes, and they depend on the relative motion perpendicular and parallel to the atomic layers, respectively. The breathing modes (BM1, BM2, and BM3) and shear modes (SM) are marked in Fig. 4a. For PdSe2, the intralayer covalent bonds along with the vibrational directions of adjacent atomic layers determine the intensities of the LF vibrational modes. Moreover, the interlayer vibrational modes display high intensities in few-layered PdSe2 flakes, even overtop the intralayer modes (HF features), which reflects the strong interlayer coupling of PdSe2. With the increase in the layer number of PdSe2, the LF Raman spectra exhibited a distinct red shift for the branches of the breathing modes. Such a shift was more pronounced than that of Raman peaks in the HF region. The full-width half-maximum (FWHM) of BM1 narrowed from 12 cm−1 (2 L) to 2.5 cm−1 (7 L) owing to the reduced phonon scattering rate in thicker PdSe2 flakes [18]. Thus, the number of PdSe2 layers can be precisely determined via Raman spectroscopy.
As mentioned above, PdSe2 presents relatively low symmetry owing to its puckered pentagonal structure, which exists in a few other TMDCs except PdS2. Thus, PdSe2 exhibits a unique anisotropy property, and the Raman scattering features of PdSe2 have been recently conducted to study the vibrational anisotropy [40].
2.5 Polarization Properties
Compared with 2D TMDCs, PdSe2 possesses unique optoelectronic polarization properties because of anisotropy [16, 40], which is a great advantage for detecting polarized light. The PdSe2 has an appropriate bandgap (1.1 eV) and excellent optical absorption at the near-infrared range [40].
To date, PdSe2 remains the only choice for polarization investigation among the noble metal dichalcogenides. Indeed, the pentagonal PdS2 may possess the photoelectric properties analogous to the PdSe2. But 2D PdS2 investigation remains the theoretical calculation [13] and has yet been successfully prepared in experiments. This is probably because of the thermodynamic instability of marcasite PdS2 in the air [14]. Therefore, the application of PdSe2 exhibits high promise in the applications of optoelectronics and electronics.
Polarization-resolved Raman measurements and theoretical calculations were employed to systematically investigate the anisotropic optical properties [39]. Figure 5a, b shows the Raman intensity simulations of the Ag and B1g modes versus the polarization angle in 3 L PdSe2 under parallel polarization configuration. The Ag modes reveal a period of 180°, and the B1g modes reveal a period of 90° in the parallel configuration.
Figure 5c, d presents the Raman intensity of both modes under parallel polarization configuration. Indeed, the Ag and B1g modes both reveal a period of 90° under the cross configuration. The LF Raman peaks possess Ag or B1g symmetry because the LF modes follow the group theory, similar to the HF modes, and the breathing modes and shear modes possess Ag and B1g symmetry, respectively.
2.6 Optical Absorption Properties
The anisotropic features of PdSe2 can be verified based on its optical absorption. Figure 6a shows the optical absorbance of 1–3 L PdSe2 flakes at measurement angles of 0° and 90°, where an interesting orthogonal crossover is observed at around 470 nm [39]. Owing to the decrease in the bandgap, the increase in the number of PdSe2 layers leads to a slight red shift of the intersection point after 600 nm.
Figure 6b shows the variation in PdSe2 absorption with the polarization angle for a systematic investigation of the anisotropic characteristics. Almost all the absorption spectra of PdSe2 intersect at 472 nm when the polarization angle varies from –90° to 90°.
2.7 Photoelectronic Properties
Based on the optical absorption of PdSe2, the photoresponse of 2D PdSe2 was investigated. The spatially resolved photocurrent mapping was collected for the few-layer PdSe2 devices [41]. Figure 4g shows a stable photocurrent of the device under 1060-nm illumination at two metal-PdSe2 junctions without any applied voltage.
To further study the photocurrent generation mechanisms, gate-dependent scanning photocurrent measurements were taken (Fig. 7a, b). Besides, the photocurrent could be tuned from positive to negative when regulating the drain–source voltage from 150 to -150 mV (Fig. 7c). The photocurrent mapping could be applied in the image sensing.
A strong photocurrent resonance peak emerges at 1060 nm, which may be due to an indirect optical transition. Due to the potential barriers created by the Fermi level alignment, a built-in electric field separates the photogenerated electron–hole pairs in the PdSe2 device [41].
2.8 Thermoelectric Properties
Over the past decade, thermoelectric devices have attracted much attention because they can directly convert thermal energy into electrical energy. Because the bond saturation significantly enhances the thermal energy transport in 2D pentagonal materials, a unique feature is that PdSe2 possesses good thermoelectric properties. In particular, monolayer PdSe2 can be applied as a promising high-performance thermoelectric material in the future owing to its high Seebeck coefficient (> 200 μV K−1) [27]. For few-layer PdSe2, the energies of CB and VB were found to be convergent during a systematic investigation of its lattice structure and electronic properties, which indicates the significant thermoelectric properties of PdSe2 [42].
Figure 8a shows the electron transport coefficient of PdSe2 based on the constant relaxation time approximations of the Boltzmann theory [39]. Clearly, when the doped carrier concentration increased, the conductivity (σ) increased, while the Seebeck coefficient decreased. For monolayer PdSe2, the Seebeck coefficient can reach 660 μV K−1, which is comparable to that of some reported 2D materials [43]. The S for p-type doping is more asymmetric than that for n-type doping, and this provides the possibility for the design of transverse thermoelectric devices. Figure 8a proves that the power factor (PF) S2σ possesses distinct anisotropy, and this results from the large anisotropy of σ and S.
Figure 8b shows the calculation of the lattice thermal conductivity κl through the phonon Boltzmann transport equation and DFT. The lattice thermal conductivity of PdSe2 is much lower than that of monolayer MoS2 and GX2 [44], and it exhibits a large directional anisotropy. Figure 8c displays the relationship between the dimensionless figure of merit (ZT) value of the doped monolayer PdSe2 and the carrier concentration at room temperature.
The ZT value of monolayer PdSe2 is small and almost isotropic, while that for p-type doping is large and strongly anisotropic. Therefore, the high S, low σ, and high ZT values of monolayer PdSe2 at room temperature make PdSe2 suitable for thermoelectric devices.
2.9 Phase Transformation Properties
Two-dimensional materials, especially TMDCs, can possess various properties via change in their phases, namely in terms of bonding and configurations, which can be exploited in other fields. For PdSe2, the interlayer interaction is relatively more reliable than the intralayer connection through covalent bonds, which facilitates the transition to other phases under different external parameters. The unique puckered pentagonal structure of PdSe2 possesses imperfect rotational symmetry, resulting in high defect sensitivity, particularly Se vacancies (VSe), which facilitates the occurrence of different phase transitions [45].
PdSe2 structure could transform into a Pd2Se3 structure (Fig. 9a) through VSe [46]. From the STEM images, it was found that the preferred monolayer phase form exfoliated from bulk PdSe2 is not a PdSe2 structure. Through analysis of the quantitative STEM image intensity and DFT calculations, a new stable monolayer phase was determined to be Pd2Se3, which corresponds to the result from the experimental ADF-STEM image (Fig. 9b) [47].
The reconstruction of Pd2Se3 is due to the interlayer fusion mechanism, which results from the VSe produced by electron radiation (Fig. 9c). According to the research results, the new Pd2Se3 phase exhibits physical stability and high cohesive energy, implying robust chemical bonding. Moreover, the Pd2Se3 monolayer is an excellent thermoelectric material with good electronic and optical properties [48].
Figure 9d shows the typical VSe migration process in PdSe2 in four possible configurations labeled I, II, III, and IV. The red circle indicates the position of the VSe, which diffuses in the direction of the green arrow. The theoretically calculated energy barriers were presented for the corresponding VSe diffusion (Fig. 9e). For configurations I to II and III to IV, the energy barrier of interlayer and intralayer VSe diffusion is 1.59 and 1 eV, respectively. These barriers are lower than the corresponding energy barriers in MoS2. These VSe migrations are facilitated by the stronger interlayer interaction and weaker intralayer bond strength of PdSe2. For configurations II to III, the energy barrier for intralayer VSe diffusion is 0.03 eV owing to the Se–Se bonding [45].
Environmental energy input elevates the energy of PdSe2 and provides the activation energy for the formation of other Pd–Se compounds, viz. the phase transformation occurs. For example, the thermal annealing, plasma, and laser treatment have resulted in the phase transition of PdSe2. The typical external conditions are listed in Table 2 for the phase transition of PdSe2.
First, PdSe2 can be transformed to PdSe2-x with vacuum annealing. According to the traditional bulk Pd–Se phase diagram [49], the Se loss induces the change in the Pd/Se ratio. Hence, the phase transition occurs after 30-s pulse annealing at 400 °C and the PdSe2-x (x = 0–1) forms partially. Another 30-s pulse annealing completed the phase transition into Pd2Se3. The long-time annealing at 400 °C or heating at high temperature (> 400 °C) leads to excess Se loss and thinning of 2D materials and finally form pure Pd materials [49]. Indeed, Se loss occurs in other metal selenide upon thermal annealing. Second, high laser power can lead to Se loss and the formation of Pd nanoparticles [50]. Third, the high-pressure condition may induce the change of crystal structures [40] and layer stacking orientation [33].
Except for Pd2Se3, the Pd–Se binary phases include Pd17Se15, Pd7Se4, and Pd4Se. Through experiments, their metallic or superconducting characteristics have been displayed, and theoretical predictions have highlighted their topological quantum properties [51].
For instance, the Pd17Se15 phase has excellent stability with analogous chemical bonds to those of the PdSe2 phase [52]. Figure 9f, g shows the structure of the Pd17Se15 phase and the corresponding STEM images. The phase transition results from the VSe in the PdSe2 crystal are due to Ar-plasma treatment (Fig. 9h). Moreover, the Raman spectra and STEM images indicate that the exposure time under Ar plasma irradiation affects the defects and degree of the phase transition in the PdSe2 crystal.
We now come to the introduction of synthesis strategies and posttreatment approaches.
3 Synthesis Methods for Obtaining PdSe2
High-quality PdSe2 has been obtained via several reliable methods [17], which shows promise for exploration of its remarkable properties. In this section, we review the specific PdSe2 synthesis methods in terms of 3D bulk crystals and 2D thin films.
3.1 Formation of 3D Bulk Crystals via Chemical Vapor Transport
The chemical vapor transport (CVT) method has been developed for the synthesis of most 3D bulk materials; it is an efficient method employed for laboratory synthesis and mass production. A common CVT reaction involves three processes: sublimation, transport, and deposition, and follows Le Chatelier’s principle in thermodynamics [53].
The typical chemical vapor transport method has shown success in the growth of bulk PdSe2 crystals [54]. Herein, a stoichiometric ratio of high-purity Pd and Se powder was mixed as the source and placed into an ampoule reactor with mineralizers as the transporting agent (Fig. 10). The sealed reactor was then heated under a preset temperature gradient, where Temperature 1 is the temperature for the sublimation of Pd and Se and Temperature 2 is the temperature for PdSe2 deposition [54]. Generally, Temperature 1 is greater than Temperature 2 because the process of PdSe2 crystal formation is endothermic [53].
For example, Pd and Se powders (mixed in an atomic ratio of 1:6) were filled in a sealed evacuated quartz ampule, which was slowly heated to 850 °C and maintained for 50 h. After the synthesis was completed, the quartz ampule was gradually cooled to 450 °C at a rate of 3 °C h−1 and finally naturally cooled to room temperature [53]. Eventually, shiny single PdSe2 crystals were obtained on millimeter-grade paper.
3.2 Developing 2D Thin Tilm via Exfoliation
As devices with smaller sizes and higher performance are desired in the development of electronics, the growth of high-quality ultrathin 2D materials has become increasingly crucial. Thus, mechanical exfoliation and chemical vapor deposition (CVD) techniques are widely employed to produce layered PdSe2 thin films.
After the synthesis of bulk PdSe2 crystals, atomic PdSe2 thin flakes could be easily obtained using the mechanical exfoliation method [15]. PdSe2 flakes with different layers were transformed onto the Si/SiO2 substrate (Fig. 11). The exfoliated PdSe2 samples were then applied to different electronic devices.
The exfoliated PdSe2 flakes have high crystallinity (Fig. 11) and intrinsic properties, which are beneficial for fabrication of individual devices [39]. The mechanical exfoliation method enables facile fabrication of the vdWHs [54]. However, the lack of large-area uniformity and layer-number controllability limits the applicability of the mechanical exfoliation method; moreover, the method is difficult to use for industrial production.
The typical features are compared in Table 3 for the synthesis approaches of 3D bulk, nanosheets, and 2D films of PdSe2.
Recently, the Au-assisted exfoliation method has shown success in the separation of monolayer 2D materials over a centimeter size [55]. In brief, the Au film is first deposited onto a target substrate [56]. Then, the tape with exfoliated 2D material is stuck onto the Au surface. Upon the pressing over the sample, the strong interaction forms between Au and 2D material. Eventually, monolayer or few-layer 2D materials remain over the Au surface after peeling off the tape. Here, the interlayer interaction in TMDCs can be overcome by the interaction between Au film and 2D materials [57]. The strong van der Waals interaction between Au and the uppermost two-dimensional layered transition-metal chalcogenide promotes the exfoliation of the single layer, which leaves large-area single-layer domain on the Au surface. For example, Au-assisted exfoliation has produced large MoS2 domains, i.e., 40 times greater than that produced by the tape-assisted exfoliation [57].
The Au-assisted exfoliation has become a universal approach for obtaining millimeter-sized 2D materials including PtSe2, PtTe2, and PdTe2 [58]. It may apply to the exfoliation of PdSe2 over a large size soon, which may accelerate the fabrication of electronic device arrays due to the large effective film area. The 2D materials over Au film by Au-assisted exfoliation can be applied in electrochemistry and photocatalyst [55].
Most 2D materials with large-area uniformity and high crystallinity can be synthesized via the CVD method or thermal selenization/sulfurization treatment [59]. Several approaches have been used to grow homogeneous PdSe2 thin films, with satisfactory results being obtained. We now discuss thermal deposition approaches for synthesizing PdSe2 films.
3.3 Chemical Vapor Deposition from the PdCl2 and Se Reaction
A chemical vapor deposition strategy was developed by employing Pd-containing precursors and Se powders for synthesizing the PdSe2 films. Here, PdCl2 powder was selected as precursors [60]. A schematic of the CVD process with a three-zone tube furnace is shown in Fig. 12a.
Here, Se powder was placed in Zone 1 at a temperature of 250 °C, and PdCl2 powder was placed in Zone 2 at a temperature of 500 °C. Then, Se and Pd precursors were transported by Ar/H2 to Zone 3, and the temperature was maintained at 600 °C, at which the polycrystalline PdSe2 films were synthesized continuously on the substrate. Figure 12b shows a photograph of the as-grown PdSe2 film with high uniformity. The AFM image and height profile of the PdSe2 films were characterized (Fig. 12c) with a thickness of ∼8 nm, corresponding to 20 layers of PdSe2 [15].
Because of the high melting point of the Pd metal precursor, the molten salt-assisted method can be utilized for the growth of PdSe2 flakes, which can be synthesized at a lower temperature over a large domain [61]. The ambient pressure chemical vapor deposition (APCVD) method can be used with the assistance of salt powder, such as NaCl, where the Pd metal precursor is replaced by high-purity PdCl2 powder. Au foils were placed above the mixture and heated at 850–900 °C at 85 sccm Ar and 15 sccm H2 flows for 10–15 min. Interestingly, the length/width ratio of the PdSe2 flakes increased markedly during the synthesis. PdSe2 flakes were obtained with growth times of 20 and 35 min, respectively. The PdSe2 flakes on Au foil exhibited a ribbon-like shape, which was rarely the case on the amorphous oxide substrates. Hence, the synthesis of PdSe2 may depend on its anisotropic structure and orthorhombic symmetry.
3.4 Chemical Vapor Deposition Reaction by the Sublimated Pd and Se
A CVD approach has been developed with the reaction of sublimated Pd and Se for growing few-layer PdSe2 flakes with high crystallinity [62]. In the setup for the synthesis of PdSe2 crystals, the Se powder was placed in a separate quartz tube zone wrapped with a heating belt at 350 °C, while Pd powder was located in the center of the furnace at 800 °C, with an Ar flow of 50–150 sccm for 10–20 min. Meanwhile, the substrate was placed in the downstream zone outside the heating zone at 480–600 °C. The scheme of the growth method is presented in Fig. 13.
Notably, the PdSe2 flakes had various thicknesses, sizes, and shapes when the substrates were synthesized at different temperatures. For example, square-like flakes grown at 600 °C are thicker and larger than the heart-like flakes grown at a temperature of 500 °C.
Chemical vapor deposition has been employed for synthesizing large-area PdSe2 films [16], single-crystal domains [63], nanowires [48], and ribbons [64]. Wafer-scale single-crystal PdSe2 may be necessary for integrated circuit applications.
3.5 Selenization of Pd Film
A simple selenization method leads to the synthesis of noble metal diselenide films [65]. The synthesis of PdSe2 films by direct selenization and the thickness of PdSe2 can be well controlled by varying the thickness of the deposited Pd layer [62]. The Pd layer deposited on the substrate via magnetron sputtering was placed in the center zone of the tube furnace at 480 °C, while the high-purity Se powder (99.99%) was placed in the upstream zone at 220 °C under a 60-sccm Ar flow for 90 min. The selenization strategy could enable the wafer-scale growth of PdSe2, such as in the form of a 2-inch PdSe2 film over a Si wafer [62]. The Raman mapping of the PdSe2 film proves that the PdSe2 film possesses good uniformity.
The structure–property relationship is listed in Table 4. The advantages and disadvantages are compared for different synthesis approaches for obtaining PdSe2. Future opportunities lie in the synthesis of monolayer single-crystal PdSe2 full film over a wafer scale (yet shown).
3.6 Direct van der Waals Epitaxial Growth of PdSe2 on Graphene
The PdSe2 has been deposited over the support of graphene or MoS2 in an epitaxial growth fashion [22]. The precursor of Pd containing organic molecules has been employed for the formation of PdSe2. Figure 14a illustrates a schematic of the experimental process. The van der Waals heterostructure of PgSe2/graphene can be directly grown with this method.
Graphene was suspended on top of the observation membrane by drop-casting the same volume of dispersion onto a TEM grid. The graphene was transferred onto a 0.50 × 0.50 mm2 SiNx membrane, which has 2-μm vacuum pinholes spaced 5 μm apart.
Figure 14b shows the CVD system for the selenization of PdSe2. The two-zone furnace was compiled with the temperature profile for Zone 1 at 240 °C and Zone 2 at 360 °C (Fig. 14c). This research presents a direct method for the growth of vdWHs at the nanoscale and atomic level and an innovative strategy for the synthesis of 2D materials through predetermined nucleation.
3.7 Layer-by-layer Thinning by the Oxygen Plasma
Precise layer control of PdSe2 samples plays an important role in tuning of the bandgap of PdSe2. A layer-by-layer thinning strategy has been employed for etching an n-layered PdSe2 flake to the (n − 1) layered flake (Fig. 15). Precise layer thinning [66] has been depicted by selective oxidation via oxygen plasma and sublimation through thermal annealing (Fig. 15a-d).
To investigate the etching method, the PdSe2 flakes were exposed to plasma with different O2/Ar ratios [66]. Figure 15e shows the variation in the thickness of the PdSe2 flakes after etching. The correlation between the thickness and number of layers employs an empirical value of 0.7 nm per PdSe2 layer [15]. Figure 15f shows an optical micrograph of two pristine PdSe2 flakes with seven and nine layers, respectively. Figure 15g shows the same regions after the plasma etch cycle. The color of the PdSe2 species changes subtly from blue to light purple, which indicates a decrease in the PdSe2 film thickness.
The AFM images of the corresponding PdSe2 flakes (Fig. 15h, i) provide line-scanning information (Fig. 15j). Here, 2-nm PdSe2 (ca. 3 layers) was etched after oxidation and sublimation upon O2 plasma treatment. Therefore, plasma etching and surface curing may shed light upon the bandgap regulation of 2D materials over a large area.
The posttreatment of PdSe2 could modify the structure and properties of the pristine material. First, mild plasma exposure to PdSe2 could lead to layer-by-layer plasma etching to regulate the thickness [66]. The ozone treatment [67] of PdSe2 could enhance the chemical sensitivity owing to the weak oxidation. Electron irradiation can modify conductivity performance [68]. The phase transformation of PdSe2 leads to a sub-1-nm channel by thermal treatment [49] and the Pd2Se3 phase by interlayer fusion [46].
4 Roles in Electronic Devices
As mentioned above, because of the strong interlayer interactions resulting from the almost fully occupied d-orbital and tunable properties, which depend on the number of layers, PdSe2 shows potential as a 2D material applicable for use in electronic devices.
4.1 Electrical Contacts for PdSe2 Devices
Prior to fabrication of an electric device, a metal/PdSe2 contact is essential for optimizing the electrical performance of transistors, photodetectors, and integrated circuits. At the interface of metal/semiconductor contact, the transport properties of charge carriers are determined by the Schottky height, tunneling energy barrier, orbital overlapping percentage, as well as the geometry of the interface.
Theoretical calculations using the DFT approach were employed to compare the metal/PdSe2 contact performances by tuning the metal types such as Au, Ag, Pb, Cu, and Ti, as well as semimetallic graphene. The efficiency of charge transfer at the PdSe2–metal interface was examined for energy barrier evaluation [69]. Figure 16a shows the prototype of a PdSe2–metal contact with a carrier flowing from the metal electrode to the PdSe2 channel through the pathway (I → II → III → IV → V). In a typical PdSe2 FET (Fig. 16b), carriers diffuse from the metal to the layered PdSe2 and encounter a tunneling barrier, which depends on the binding strength at the interface of the PdSe2-metal contact.
The PdSe2–metal contacts, i.e., with Au or Ag electrodes, are demonstrated with their energy band alignment based on the binding energy owing to the Schottky barriers (Fig. 16c). First, Au/PdSe2 was preferred via compression of the Schottky barrier height. Meanwhile, the Ag electrodes led to an improved orbital overlap with PdSe2. A vertical Schottky barrier appears at the interface (II) in the vertical direction, while a lateral Schottky barrier occurs at the interface (IV) between the heterojunction and the PdSe2 channel region. Second, the Pb/PdSe2 contact has a low tunneling potential with a Schottky barrier height of 0.67 eV (Fig. 16d). Third, Cu/PdSe2 does not form a tunneling interface (Fig. 16e) but has a Schottky height of 0.58 eV.
Eventually, the graphene/PdSe2 contact has emerged as a proof of concept with regard to vdWHs. A Schottky barrier height of 0.22 eV is preferred for electron transport—that is, n-type charge carrier conductance [69]. Indeed, electrons are transferred from the interface to the PdSe2 side with a band bending of − 0.94. The weak van der Waals interactions between graphene and PdSe2 render a quasi-Ohmic contact without energy transfer between the two surfaces. That is, the intrinsic transport properties of PdSe2 are maintained. Analogous to the contact behavior of other 2D materials, one can fabricate high-performance optoelectronic devices.
The stability and metallicity of the Pd17Se15 phase make it an ideal buffering material between the metal and PdSe2. The low lattice mismatch between both palladium selenides guarantees quasi-Ohmic conductance behavior, which suppresses the Schottky barrier height. In contrast, PdSe2 devices with Pd17Se15 contacts performed better than those with Ti/Au contacts [52]. Figure 17a shows the temperature-dependent mobility of PdSe2 devices with Pd17Se15 contacts and Ti/Au contacts, which are approximately 170 and 8 cm2 V−1 s−1, respectively.
Figure 17b shows the relationship between the slope and different drain voltages at zero gate voltage. The Schottky barrier height ФB of the Ti/Au contact device (96.2 meV) is greater than that of the Pd17Se15 contact device (3.26 meV). Figure 17c, d illustrates the electrode contact of the PdSe2 devices from the Schottky barrier of Ti/Au contacts to the Ohmic contact of Pd17Se15 contacts. Thus, the contact resistance of the PdSe2 device decreases and has the potential to become closer to the quantum limit.
Future opportunities may remain in developing the electrical contacts of PdSe2 with other palladium selenides. Indeed, the PdSe2-x phases with different stoichiometric ratio may arouse different contact behaviors when stacking vertically with PdSe2 or stitching together laterally. The PdSe2-x/PdSe2 contact could be either Ohmic or Schottky typed, which require the optimization of researchers. The Schottky type contact could be utilized in the rectifier device. The Ohmic contact facilitates the electronic transport performances such as charge carrier mobility. The phase-engineering method proves that new crystalline phases of anisotropic 2D materials can be induced by defects. These new PdSe2-x compounds may have different stoichiometries, which broadens the choices of materials for electrical contacts.
After understanding the metal/PdSe2 contact, we now come to the discussion of electronic transport performances in field-effect transistors.
4.2 PdSe2 Field-effect Transistors
The field-effect transistors are one of the most significant devices in semiconductor electronics, and FETs based on 2D materials have shown superior performance to those based on traditional semiconductors. Moreover, usage of 2D materials provides new opportunities and effective approaches regarding FETs, with a high on/off ratio, high carrier mobility, and excellent stability. The layer-dependent properties of TMDCs are important for the design of FETs for diverse functionalized devices [30]. In this section, PdSe2 FETs and efficient methods to improve their performance are introduced.
PdSe2 has proven to be a successful channel material for FETs. PdSe2 transistors have achieved high mobility with tunable ambipolar characteristics [70]. Figure 18a shows an experimental setup to measure the PdSe2 FET characteristics with p-type Si as a universal back-gate electrode, and Fig. 18b, c shows SEM images of the two as-fabricated PdSe2 FET samples.
The electronic performances of the PdSe2 FETs are depicted in the output and transfer characteristics (Fig. 18d, e). In the output curves, the PdSe2 FET exhibited a linear correlation between the voltage and current (insets of Fig. 18d, e). Such a linear drain current–voltage dependence indicates quasi-Ohmic contact, i.e., suppression of the Schottky barrier between PdSe2 and the electrodes. The electrons dominate the primary charge carriers of the FET at a positive gate voltage and a small negative gate voltage (Fig. 18f). In contrast, the holes become the leading charge carriers of the FET at a large negative gate voltage.
The air stability of PdSe2 guarantees the lifetime of its transistor-based sensor applications in a wet environment. For example, the 2D material-based transistors have been embedded in a microfluidic chip for microRNA detection and screening [71]. The chemical sensors of 2D materials have demonstrated superior performances.
The slight hysteresis of the transfer curve could result from the effect of slow trap states and the surface adsorbates from the lithography-based fabrication process [17]. Remarkably, the ambipolar behavior of the PdSe2 FET could be regulated through a biased sweep.
The hysteresis width can be periodically evaluated by continuously measuring several transfer curves. These two transfer curves of the PdSe2 FET were measured in succession (Fig. 18g). The first curve in black was employed as a reference curve, and the second curve in red was collected at a delay of 8 s after the first signal capture. Therefore, the hysteresis is elevated with the increased sweeping time of the gate voltage.
The transport properties of PdSe2 FETs can be regulated by employing vacuum annealing, charge doping, electrical stress, pressure, and electron irradiation [17]. Through reduction of both the pressure and electron irradiation, hysteresis in the PdSe2 FET can be effectively suppressed. These strategies offer viable methods to reduce hysteresis in devices. Moreover, the types of charge carriers can be converted from n-type to p-type, which can be used as a switch for practical circuits.
Remarkably, vacuum annealing is an effective method for improving the mobility of FETs, and it has been widely used in electronic devices [72]. For PdSe2 FETs, annealing can remove the surface adsorbates to achieve higher mobility, on/off ratio, and lower Schottky barrier. Moreover, annealing at 450 K can eliminate hysteresis in FETs [17]. After annealing at 400 and 450 K, PdSe2 FET exhibits a higher mobility of 75 and 216 cm2 V−1 s−1 than that measured at room temperature. Such a transistor achieves the highest current ON/OFF ratio of 103 at 450 K. Meanwhile, the threshold voltage shows an increasing shift to the negative gate voltage as the annealing temperature increases. This indicates that the Fermi level moved to the conduction band in PdSe2. Thus, the PdSe2 FET exhibits an obvious n-type transfer characteristic.
Furthermore, a molecular doping method converts the electron transport behavior of PdSe2 into a hole-transport feature [17]. As a prevalent p-dopant, F4-TCNQ has high electron affinity and has been utilized in low-dimensional materials [73], which can be applied to PdSe2. One can compare the transfer curves of the FET with different doping levels from undoped to completely doped, whereby a distinct conversion of the transfer characteristics from ambipolar to p-type is shown. The contact resistance of the PdSe2 FET has a dependence on the gate voltage, resulting from the Fermi level being adjusted by electrostatic gating. Therefore, vacuum annealing and molecular doping can effectively reduce contact resistance.
The transport properties of PdSe2 FETs can be altered via annealing or charge doping. Besides, the ambipolar behavior of PdSe2 FETs can be obtained by varying the electrical stress, pressure, and electron irradiation [70].
Atmospheric pressure has a significant influence on the PdSe2 FET. The transfer curves of the PdSe2 FET were extracted under various pressures at a constant drain voltage of 100 mV. As the pressure increases, the transfer nature of the PdSe2 FET gradually transforms from the n-type to the p-type, and the PdSe2 FET exposed to air after 10 min becomes a p-type depletion mode transistor [70].
Moreover, electron irradiation changes the charge distribution in the PdSe2 FET, which further affects the transfer characteristics [74]. The transfer curves of the PdSe2 FETs were collected before and after electron irradiation via SEM imaging. With increasing time after SEM imaging, the transfer characteristics slowly revert to the initial state.
Two-dimensional PdSe2 synthesized using different approaches has been used in the fabrication of FETs. Table 5 compares the performance of these PdSe2 FETs in terms of charge carrier mobility and current ON/OFF ratio. Further developments with large-area CVD-grown PdSe2 may improve the electrical performance, such as the charge mobility and ON/OFF ratio.
In summary, several strategies have been developed to improve the FET performance of PdSe2. Future opportunities still exist in terms of surface cleaning and modification, electrode contact design, packaging conditions, and vdWH stacking. Indeed, the PdSe2-based electronic devices could be integrated with the piezoelectric materials, i.e., PVDF for tactile sensors [75]. For the comfort of human beings, stretchable and wearable electronics become emerging with device development such as strain sensors and electronic skin [76]. Besides, the introduction of triboelectric nanogenerators, supercapacitors [77], and batteries [78] may lead to self-powered sensors [79].
After knowing the electronic devices of PdSe2, we turn to the progress in its applications in optoelectronics and optics.
5 PdSe2 for Optoelectronics and Optics
The photodetector, which is a device that converts an optical signal into an electrical signal instantaneously, plays an indispensable role in current and burgeoning technology, in the fields of biotechnology, medicine, physics, and natural sciences [80].
Owing to their unique and significant properties, 2D materials have been applied in photodetectors and exhibit remarkable performance in terms of responsivity (R), detectivity (D*), and external quantum efficiency (EQE) [81]. Here, the responsivity R describes the photoelectric conversion efficiency, D* reflects the ability to measure the minimum optical signal, and EQE is the ratio of the number of photo-generated electron–hole pairs contributing to photocurrent to the number of the incident photons. The rise/fall time is a crucial parameter for evaluating the response speed of photodetectors.
Two-dimensional materials can be used as outstanding photodetector components by constructing heterojunctions [82] and gate-voltage regulated phototransistors [41]. For example, infrared photodetectors can employ the sensing materials such as BP [83], PtTe2 [10], and WS2. But h-BN, graphene/Si [84], and MoS2/GaN [85] can be used for ultraviolet light detection. Besides, PtSe2 has a large photoresponse at a wide spectral band ranging from 200 to 1550 nm [7]. Then, the anisotropic compounds such as PdSe2 can be used for polarized sensitive photoelectric detection [29]. Therefore, the coupling of PdSe2 and other 2D materials may cover the light detection of a broad spectral range.
In this section, we will discuss the detection band versus bandgap, photodetection performances, and polarized light detection based on PdSe2 and related materials.
5.1 Detection Bands versus Bandgap
The performance of the photodetectors can be determined by the bandgaps of the materials. Photodetectors function at various wavelengths based on different 2D materials. Owing to the different bandgaps of the 2D materials, the corresponding photodetectors function in different spectral bands (Table 6).
The performances of 2D material-based photodetectors can be determined as per details, such as black phosphorene or black phosphorus, MoS2, MoSe2, WS2, WSe2, graphene, SnS, SnSe, SnS2, SnSe2[86], InSe, In2Se3, ReS2, black AsP, PtSe2, PtS2, and PdSe2.
The PdSe2 layered material has remarkable optoelectronic properties, with a large bandgap tenability and extraordinary carrier mobility. The PdSe2-based devices are relatively stable and can be applied for photodetection from deep ultraviolet to mid-infrared bands [21], and the longest photodetection wavelength studied thus far is 10.6 μm [54].
5.2 PdSe2 Photodetectors for Near-infrared Light Detection
The near-infrared light (1060 nm) is important for optical data communication and biomedical imaging. The small bandgap of monolayer PdSe2 features resonant optical absorption of such a wavelength. Therefore, PdSe2 is an ideal material for near-infrared light photodetectors.
A typical PdSe2 photodetector has been measured under monochromatic illumination [19]. Because the PdSe2 photodetector is based on field-effect transistors, the gate voltage plays an important role in photodetection. The responsivity of the PdSe2 photodetector demonstrates a strong gate voltage dependence under 1.06-μm light illumination. The device showed an ultrahigh responsivity of 708 A W−1 at a gate voltage of 30 V, and the detectivity was calculated to be 1.31 × 109 Jones.
The normal positive trend of the photocurrent increases with increasing power intensity [19]. The responsivity of the PdSe2 photodetector under 4.05-μm illumination is much lower at 1.9 mA W−1. The photodetector exhibits excellent stability and repeatability in the environment at room temperature. The absorption spectra of PdSe2 flakes with different thicknesses demonstrate that the thick PdSe2 flakes have a higher MIR wavelength absorption. Therefore, this proves the feasibility of photodetection in the mid-infrared band.
However, the photoresponse time of PdSe2 photodetectors, in the order of several milliseconds, is less than desirable. The photogating effect may account for this phenomenon. That is, photogenerated electrons cannot recombine in a timely manner with photogenerated holes trapped by trap states. Therefore, the lifetime of photoelectrons is prolonged, and the device response is slow.
Both 2D materials and traditional 3D semiconductor materials can form heterostructures with PdSe2 and perform well in photodetection. A pyramid microstructure for heterojunction photodetectors have demonstrated their excellent performances via the light trapping effect and numerical modeling [62].
The PdSe2/pyramid Si photodetector can achieve greater performance than that of the PdSe2/Si photodetector in terms of the responsivity, detectivity, and ON/OFF ratio [62], and they are compared with other heterostructures (discussed later in 6.3). The PdSe2/pyramid Si photodetector can function as a self-driven device without a power supply. The tuning of the light intensity leads to a difference in the responsivity and ON/OFF ratio at zero bias. The maximum ON/OFF ratio can reach 1.6 × 105. The responsivity and detectivity depend on the illuminating light wavelength, and the maximum values are 456 mA W−1 and 9.97 × 1013 Jones, respectively. Both are determined under 980-nm illumination for obtaining the peak sensitivity of the PdSe2/pyramid Si photodetector.
Similar to the Si pyramid, Ge nanocones (GeNCs) in heterojunction photodetectors can absorb photons more efficiently [87]. They have a higher photocurrent than that of the PdSe2/planar Ge heterostructure. Under 1550-nm illumination with a power intensity of 5 µW cm−2, the PdSe2/GeNCs photodetector exhibits a much larger responsivity (530.2 mA W−1) and quantum efficiency (42.4%) than those under 1300-nm and 1650-nm illumination. The variation of the current ON/OFF ratios with light intensity was compared under three different wavelengths. This proves the best performance of the PdSe2/GeNCs photodetectors in the 1550-nm detection.
5.3 PdSe2 Photodetectors for Sensing Polarized Light
Polarized light detection can be achieved in the heterostructures of PdSe2 with other materials, such as PdSe2/Si nanowire arrays (SiNWA) [25] and PdSe2/perovskite [26] heterostructures.
Figure 19a demonstrates the schematic of the setup of the PdSe2/SiNWA heterostructure-based photodetector. The responsivity R and detectivity D* under various light intensities are shown in Fig. 19b. Both parameters increase with the decrease in light intensity and reach a maximum at 726 mA W−1 and 3.19 × 1014 Jones upon illumination with a light intensity of 27.5 cm−2. Notably, the PdSe2/SiNWA photodetector demonstrates a significant response to the weak light signals with a broad spectral detection range from the deep ultraviolet to the mid-infrared range (Fig. 19c).
However, it shows a high sensitivity to polarized light signals attributed to the asymmetric pentagonal structure of PdSe2. Here, the incident polarized light is supplied with various polarization angles through a half-wave plate using a polarizer. The normalized photocurrent was measured versus the polarization angle at zero bias (Fig. 19d). The polarization sensitivity of the PdSe2/SiNWA device is 75, which is higher than that of other 2D material-based devices.
Therefore, the PdSe2/SiNWA heterostructure exhibits great advantages as the self-driven and wide-band photodetector with highly polarization sensitivity. It has shown a remarkable broad photodetection from DUV to MIR with an excellent responsivity, specific detectivity, response time, and polarization sensitivity. Meanwhile, the device holds prominent potential in infrared imaging of high pixel resolution.
Under 650-nm illumination, the graphene/PdSe2/Ge photodetector [21] shows a record polarization sensitivity (112.2) among the reported PdSe2-based devices, including PdSe2/SiNWA photodetectors (75) and PdSe2/perovskite photodetectors (6.04) [26].
A comparison of polarized light sensing is presented for different 2D materials and their heterostructures (Table 7). The polarization sensitivity of the graphene/PdSe2/Ge photodetector is much higher than that of some devices based on other 2D materials, such as GeS2 (2.1) [88], GeSe2 (2.16) [89], BP (8.7) [90], antimonene (17) [91], and BP/MoS2 heterostructures (22) [92].
Analogous to silicene and black phosphorus, PdSe2 has a high sensitivity to polarized light owing to its anisotropic crystalline structure. Based on this, graphene/PdSe2/Ge heterojunction photodetectors have been studied for the polarization-dependent photoresponse [21].
Overall, PdSe2-based photodetectors demonstrate remarkable photodetection of broadband bands (from deep ultraviolet to mid-infrared), good responsivity, outstanding stability, and sensitive polarization.
5.4 PdSe2 Photodetector-enhanced Humidity Sensors
Besides image sensor, PdSe2-based devices can be applied to humidity sensors owing to the large surface-to-volume ratio of the PdSe2 film. For instance, a PdSe2/SiNWA device has been utilized as a highly sensitive sensor of the relative humidity (RH) of the ambient environment [25].
Figure 20a shows the response performance of the PdSe2/SiNWA devices at various relative humidity values from 11 to 95% in the dark. The response of the device exhibited good stability and repeatability at all RH values.
Moreover, the response of the PdSe2/SiNWA device under 780-nm illumination was significantly more sensitive than that in the dark (Fig. 20b). Figure 20c shows that the response speed is further improved under illumination when the RH value is 75%, and the response and recovery times are superior to those of some sensors based on other materials reported previously. The rapid response of the device under illumination may have resulted from the rapid recombination of carriers. Figure 20d plots the incident light intensity dependence of the sensitivity at 75% RH under 780-nm illumination, and the sensitivity of the device increases as the light intensity increases. Furthermore, the PdSe2/SiNWA device can retain its initial sensing performance after 6 months, indicating the good stability of the device [25].
5.5 Saturable Absorber for Pulsed Laser
Graphene has been employed as a saturable absorber in the formation of pulsed lasers in the visible to mid-infrared range. However, the zero bandgap of graphene hinders its photonic application. Moreover, TMDCs have been employed as Q switches or mode lockers in the generation of pulsed lasers such as MoS2, WS2, MoSe2, and WSe2. However, their bandgaps are tunable in a limited range, i.e., from 1 to 2 eV, which suppresses the potential for application in optical regulation. With a wide range of tunable bandgaps, phosphorene has shown remarkable performance as a saturable absorber in pulsed lasers [93]. However, its weak air stability impedes further studies.
The tunable bandgap and air stability have guaranteed that PdSe2 is a saturable absorber (SA) in passive Q-switching, which is a crucial method when fabricating pulsed laser devices [94].
A typical PdSe2-based passive Q-switched Nd:GdLaNbO4 laser is demonstrated (Fig. 21a). The laser diode (LD) as a direct pumping source is condensed into the Nd:GdLaNbO4 crystal through the fiber core and a pair of convex lenses (L1, L2), and it is then transformed into a pulsed laser through the PdSe2 nanosheet, while the plane mirrors (M1, M2) are coated with the transmission of different reflectivity to control the output laser.
The pulse repetition frequency shows a positive correlation with the absorbed pump power (Fig. 21b), whereas the pulse duration displays a negative correlation. Figure 21c shows the evolution of the pulse energy and peak power of the PdSe2/Nd:GdLaNbO4 laser with varying absorbed pump power, which may be due to the extensive modulation range of PdSe2. These results are better than those of MoS2 and WS2 [95], proving the excellent characteristics of the PdSe2 SA and the excellent potential of passive Q-switched lasers.
Due to the suitable bandgaps, 2D materials have been employed as saturable absorbers (SA) for passively Q-switched and mode-locked fiber laser. Besides, optical circuits have incorporated various saturable absorber materials, such as SnTe quantum dots, graphitic-phase C3N4, MoS2, PdS2, In2Se3, PtS2, WS2, and PdSe2 [96]. Indeed, they have emerged as cost-effective, simple, and highly integrated component for pulsed laser generation.
Future works may lie in the adoption of PdSe2-based van der Waals heterostructures as saturable absorbers for pulsed laser modulation in the fiber lasers or solid-state lasers.
Previously, the electronics, optoelectronics, and optics of PdSe2 have been introduced. Besides, the PdSe2 may possess great promises in the environmental, energy and biomedical applications. Indeed, the 2D materials have demonstrated the great performances in clean energy production [97,98,99], i.e., catalysis of hydrogen production or oxygen reduction, solar cells [100], thermoelectric power generation, energy storage, environmental remediation [101, 102], and photodegradation of organic-molecules-polluted water [103] as well as water purification. Besides, the metallic low dimension materials may favor the anti-bacterial performances as well as other biomedical engineering.
After knowing the devices of individual PdSe2 material, we come to the discussion of PdSe2-based van der Waals heterostructures.
6 PdSe2-based van der Waals Heterostructures
The vdWHs of 2D materials employ weak layer interactions between two stacked layered materials to form multilayer structures. Owing to the enriched choice of conductivity types, 2D materials can be stacked by choosing from semiconducting, metallic, and insulating types. Indeed, 2D material-based vdWHs have enhanced the device architectures of conventional Si technology. Here, PdSe2 as a semiconducting 2D material could broaden the applicability of 2D vdWHs. In this section, we discuss emerging applications in electronics, such as rectifiers and optoelectronics, such as image sensors.
6.1 Van der Waals Heterostructure Based on PdSe2/MoS2 Contact
Two-dimensional heterojunction-based photodetectors show superior photoresponse time and detectivity. PdSe2/MoS2 vdWH photodetectors (Fig. 22a) can effectively improve the responsivity and detectivity under 10.6-μm illumination, and the rise/fall time (τr/τf) of the photocurrent is 65.3/62.4 μs [54].
The vdWH can significantly suppress the dark current and current noise of the device, and the photocurrent can be generated under the combined action of intralayer excitons and interlayer excitons [54].
Figure 22b shows the responsivity and noise equivalent power as a function of the incident wavelength. PdSe2-based heterojunction photodetectors have better responsivity and detectivity for broadband detection. Typical photocurrent performances are presented in the dark and under illumination (Fig. 22c).
The photoresponse time can be improved by fast charge transfer in the heterostructure. Indeed, the PdSe2/perovskite heterojunction photodetector could solve the problems faced by most perovskite photodetectors, i.e., low specific detectivity and slow photoresponse [104].
The detectivity of PdSe2/MoS2 photodetectors can reach 8.21 × 109 Jones, which is much better than that of most mid-infrared photodetectors (Fig. 22d) based on AsP [105], PtSe2 [106], graphene thermopiles [107], and uncooled HgCdTe [108]. The detectivity of PdSe2 exceeded that of some traditional mid-infrared photodetectors [108]. Compared with the PdSe2/MoS2 photodetector (Table 8), the potential of PdSe2 in mid-infrared photodetection is further reflected.
6.2 PdSe2 van der Waals Heterostructure-based p–n Junction-based Rectifier
The optoelectronics has stemmed from the fundamental component of p–n junctions. Indeed, the conventional 3D thin film stacking has contributed to the photovoltaics [109, 110], photodetectors, tunneling transistors, rectifiers, and light-emitting diodes. The metal/semiconductor contact has favored the Ohmic type conductance behavior for elevating the charge carrier transport. These investigations based on thin film deposition techniques have provided useful guide for 2D materials.
Two types of 2D materials stack together with weak interaction, termed van der Waals heterostructure. With delicate selection, one can assembly a p–n junction with the atomic layer thickness [111, 112]. No dangling bonds remain at their interface; besides, low lattice mismatch between both 2D materials result in the declined defect states. Therefore, the quantity of scattering center for charge carrier is minimized for boosting the charge carrier transport, which is superior to the Si based materials.
High gate-modulated rectification in vdWHs based on PdSe2 has been introduced and examined. For example, p-type germanium selenide (GeSe) and n-type PdSe2 with a pure ohmic contact show a large rectification ratio, which is defined as the ratio between the forward and reverse currents, up to 5.5 × 105, resulting from the clean interface and low Schottky barrier [24].
One can find schematic of the p-GeSe/n-PdSe2 vdWH-based rectifier device (Fig. 23a), and the corresponding optical image (Fig. 23b).
Figure 23c displays the AFM images of the GeSe and PdSe2 flakes with thicknesses of 12 and 11.5 nm, respectively. The Raman spectra of GeSe and PdSe2 demonstrate the successful stacking of both 2D materials (Fig. 23d).
For p-GeSe/n-PdSe2 diodes, the linear scale (Fig. 23e) and the semi-log scale (Fig. 23f) of the drain current versus voltage curves were measured at different gate voltages. Indeed, the gate voltage can modulate the rectifying effect. This result is due to the carrier density and electrostatic inversion from semiconductor to semi-insulator materials [113]. Figure 23g presents the variation in the ideality factor η of the p-n diodes, which is obtained as 1.2 at a negative gate voltage. The p-n diode tends to decrease its ideality at a positive gate voltage, which can be attributed to the carrier recombination at the sharp interface resulting from the decrease in electric field [114]. Table 9 compares the rectification ratios of typical p-n diodes based on the vdWHs of PdSe2 and other 2D materials.
This proves that nTMDC-based rectifier may hold promises in logic switches as shown in other TMDC logic circuits [115]. Besides, the nTMDC-based rectifier could be employed as an energy harvester for collecting the electromagnetic wave energy as proved by other 2D materials [116].
6.3 PdSe2 van der Waals Heterostructure-based Junction Photodetectors
The PdSe2 based van der Waals heterostructures remain less investigated in terms of fabrication strategies. One can refer to the investigation of other vdWH emerging 2D materials. To date, the dry stamp transfer method has dominated the stacking nanosheets. Indeed, the epitaxy-based synthesis has great opportunities of fabricating the secondary layer of 2D materials. Besides, large quantity of 2D materials remain unexplored for the stacking of 2D materials such as metal–organic framework, graphene, MoS2, ReSe2, PtSe2, MXene, and tellurium as well as perovskites. Besides, the lateral heterostructure may arise the attention for novel charge carrier transport.
To investigate the additional features of the p-n vdWH diode, the photoresponse was investigated [117]. Figure 24a shows a schematic of the p-BP/n-PdSe2 vdWH diode under illumination.
The time-resolved photocurrent was measured under intermittent lasers with different wavelengths at a fixed power (Fig. 24b). The varying incident wavelengths from the visible to NIR region on the p-BP/n-PdSe2 diode led to current versus voltage curves (Fig. 24c). This indicates that the photocurrent decreased when the incident wavelength increased. The photocurrent of the diode depends on the back-gate voltage (Fig. 24d).
The energy band alignment of p-BP, n-PdSe2, and their heterostructures after contact (Fig. 24e), with the CBM, VBM, work function, and electron affinity. A magnified view of the band alignment is presented after contact at a gate voltage of 0 V (Fig. 24e). When the diode operates at a negative back-gate voltage, the Fermi level moves away from the conductance band. This increases the potential barrier of the p-BP/n-PdSe2 interface, resulting in a high rectifying current. The Fermi level approaches the conductance band at a negative gate voltage (Fig. 24f) and decreases the potential barrier and rectification ratio. For the p-BP/n-PdSe2 diode, the positive gate voltage (Fig. 24g) can modulate the Fermi level and control the carrier densities, which can eventually control the rectification ratio.
Therefore, the PdSe2 p–n junction-based photodiode shows a great potential in high-performance visible-infrared photodetectors, as well as solar cell for electricity production. This p-n diode concept may broaden the application of 2D nTMDC-based heterostructures in photovoltaics.
In this section, we discuss the structure and performance of different photodetectors based on PdSe2. A comparison of the performances of different PdSe2-based photodetectors is listed in Table 10.
6.4 Image Sensor System from PdSe2 van der Waals Heterostructure
Because of the excellent performance of PdSe2 in the field of photodetection, some studies subsequently explored further possibilities in the image sensor field. Infrared image sensors have emerged as an essential device unit in optoelectronic systems such as fire monitoring, night vision, and surveillance cameras [118].
The PdSe2/pyramid Si device presented superior results in terms of infrared image sensing [119]. In portable systems, cardboard masks can be imaged using such a device. The geometry of the house and tree shapes was imaged under 980-nm and 1300-nm illumination. The illuminated areas are highlighted in photocurrent mapping. In contrast, the photocurrent in the other areas remained much weaker, similar to the dark state.
Although some blemishes in the blocked regions need to be further corrected, the shapes of the patterns can be distinguished easily by contrast. Similar results were obtained for the PdSe2/GeNCs hybrid device [263], indicating the reliable infrared imaging capability of PdSe2-based devices.
The suitable bandgap of PdSe2 guarantees its application in infrared light sensing. When the devices are fabricated into arrays, the system can achieve image sensing with high pixel numbers [21]. When the polarized light is incident on the device through a specific mask, the lock-in amplifier can timely scan the voltage of the device and transform it into the voltage mapping image.
The graphene/PdSe2/Ge photodetector with a broadband range from ultraviolet to near-infrared light (Fig. 25a).
The normalized photocurrent of the graphene/PdSe2/Ge device shows a strong correlation with the polarization angle under various illuminations having different wavelengths, including 365, 650, 980, and 1550 nm (Fig. 25b).
The maximum and minimum values of the photocurrent were achieved at polarization angles of 0° (180°) and 90° (270°), respectively. Indeed, the sine-shaped photocurrent curve indicates a good polarization sensitivity of the graphene/PdSe2/Ge device [21].
A high-resolution infrared image is compiled after projecting a patterned light to the detector (Fig. 25c) after passing through the P letter mask (Fig. 25d). Here, the photocurrent intensity is stronger with a polarization angle of 0° (left panel) than that of polarized light at 90° (right panel). The high polarization contrast ratio (> 10) between the polarization angles of 0° and 90° indicates the outstanding performance of the PdSe2-based device in polarized light imaging. The heterojunction-based photodetector has excellent potential as a mid-infrared image sensor. Figure 25e presents a highly recognizable spectral image of the Z letter under 3043-nm illumination with a polarization angle of 0°.
Such an image sensor is highly promising for broadband photodetection and imaging. The PdSe2 heterojunction-based photodetector demonstrates an extraordinary polarization sensitivity, which is the highest value among 2D material-based polarized light photodetectors (thus far). On account of a strong asymmetry of PdSe2, the effective separation of photogenerated electron–hole pairs occurs by a built-in perpendicular electric field in the p–n junction. Then, the efficiency of the carrier collection is enhanced by graphene electrode. Therefore, PdSe2 is a very profound material for high-performance polarization-sensitive photodetectors.
The integration with light-absorbing materials could provide the power source owing to the photovoltaic effect. Moreover, the use of perovskite as an absorber material can transform the light into electricity for self-powering by forming a Schottky junction with PdSe2. The PdSe2/perovskite heterostructure photodetector is illustrated in Fig. 26a with a high quantum efficiency (Fig. 26b).
Such a photodetector has a broad detection band ranging from 200 to 1200 nm. Through tuning of the illuminating light with various incident wavelengths from 265 to 980 nm, the current of the photodetector has been recorded. Here, the photocurrent curve displays a maximum value under 808-nm illumination at a negative bias (Fig. 26c), which corresponds to the quantum efficiency peak around 800 nm.
In the inset panel, the current–voltage curves show the photovoltaic effect upon illumination. Similarly, PdSe2/perovskite photodetector-based arrays can be employed in image sensing with significant photoresponse capability (Fig. 26d). When the infrared light passes through the mask, the projection of the features from the mask is captured by the detector. Moreover, the processing unit converted the current signal to each pixel. Subsequently, the 2D contrast current mapping software automatically incorporates the data and exhibits the current mapping image.
Consequently, the outlines of the five letters can be recognized by 2D current mapping under 808-nm illumination. Therefore, the PdSe2/perovskite heterostructure device shows potential for the future image sensing of complicated shapes such as human beings and animals.
The currently available image sensors are listed in Table 11. The resolution and current contrast ratio may require the future efforts for improvement.
Owing to the superior capability of detecting mid-infrared light at room temperature, PdSe2-based devices highlight the high potential for application of photodetectors and image sensor systems. There remain good opportunities in the formation and application of vdWHs based on PdSe2 and other 2D materials. Indeed, low-dimensional materials have yet to be tested in vdWH assemblies with the coupling of PdSe2.
7 Conclusions and Outlook
In this work, we deliver a comprehensive review of the progress in the rising-star pentagonal 2D material, i.e., palladium diselenide. First, the fundamental of PdSe2 is introduced with the types, atomic and electronic structure, bandgap, and vibration properties. Second, the synthesis approaches are listed with top-down and bottom-up methods. Indeed, the authors are fed with mechanical exfoliation, plasma thinning, and vacuum annealing. Then, the large-area synthesis has been introduced with thermal selenization of Pd thin film, and chemical vapor deposition with different Pd precursors such as PdCl2 powers. Third, the electronic and optoelectronic devices are discussed with the metal/semiconductor contact, field-effect transistors, photodetectors, and humidity sensors. The PdSe2 has been employed in the generation of pulsed laser and the thermoelectric power. Last but not the least, the van der Waals heterostructures of PdSe2 are delivered as well as their applications in the rectifier, photodetectors, and image system.
The fundamental physics of PdSe2 may provide for the insight for the guide of device design and fabrication. Indeed, the engineering applications of conventional devices and characterization tools require refreshing novel materials to enrich the interdisciplinary research across the microelectronics, optoelectronics, spectroscopy, optics, photonics, spintronics, and valleytronics. Besides, the magnetic properties of materials are interesting for the incubation of the proof-of-concept devices. Besides, the band alignment in a heterostructure may provide a platform for photo-generated carrier transport. The 2D materials as saturable absorbers have demonstrated extraordinary performances in Q-switching and mode lock for pulsed laser generation. Indeed, the metallic 2D materials have demonstrated superior performances in electromagnetic interference shielding or microwave absorption. Besides, the incorporation of magnetic nanoparticles may lead to the change of magnetoresistance as a magnetic field sensor.
The performance of PdSe2 devices has been verified in photodetectors[62], field-effect transistors [16], and humidity sensors [25]. First, PdSe2 transistors demonstrate pressure-tunable hysteresis [70], field emission [81], and phototransistors [41]. Second, the narrow bandgap of PdSe2 guarantees its performance in an infrared range such as 10.6-µm light detection [54] and broadband sensing [19]. Third, the linear dichroism transition [39] in PdSe2 guarantees optical switching and communication. As a saturable absorber, PdSe2 shows success in Q-switching for pulsed lasers [96].
There are still plenty of room in the development of sophisticated techniques for mass production of PdSe2. First, the chemical vapor deposition [120] has the features of upscale production, large-area homogeneity, and compatibility with Si-based technology. Indeed, the chemical vapor deposition of 2D materials [121,122,123] become necessary to achieve the synthesis over a large area and even a wafer size [124]. Owing to the layer-dependent properties, the preparation methods of high-quality 2D PdSe2 should be modified to accurately control the thickness, which is essential for the manufacture of high-performance devices. According to the trend of sophisticated 2D materials such as graphene, the quality of synthetic PdSe2 may go through the path, i.e., from mechanically exfoliated nanosheets, ball-milled nano-powders [125], polycrystalline thick films, monolayer or bilayer polycrystalline thin film [126, 127], and monolayer single-crystal domains [128]. More effective synthesis of atomically thin, large-scale, and uniform 2D PdSe2 should be explored to satisfy the needs of industrialization. Eventually, the domain size of PdSe2 single crystal may expand to centimeter scale and even to the wafer scale.
The posttreatment of PdSe2 may broaden its material properties, and consequently, its device performances may vary. First, the thermal annealing or plasma treatment [129] has shown modification of 2D materials. Second, the in situ characterization tools such as transmission electron microscopy [130] and XRD may provide the direct evidence for phase transition, i.e., the lattice distortion in the atomic scale. Third, the machine learning acts an efficient tool for defects determination and device performances enhancement. The properties of 2D materials could be regulated with defect engineering by the theoretical calculation, as well as big data for materials science. Besides, the patterning of 2D materials becomes a prerequisite for the fabrication of device arrays.
Future opportunities of PdSe2-based devices and systems remain great at integrated circuits as well as the internet of things. Indeed, the 2D materials have been incorporated in the logic gate-based digital circuits, programmable memories, and RF integrated circuits. One can refer to the graphene [124] and transition-metal dichalcogenides [131] for borrowing the concept of heterostructures. There remains a vortex of materials science research for artificial intelligence such as actuator devices, and human/machine interface. Therefore, great prospects of PdSe2-based van der Waals heterostructures are calling for the input of physicists, chemists, and materials scientists as well as industrial engineers.
References
Y. Saito, J. Ge, K. Watanabe, T. Taniguchi, A.F. Young, Independent superconductors and correlated insulators in twisted bilayer graphene. Nat. Phys. 16(9), 926–930 (2020). https://doi.org/10.1038/s41567-020-0928-3
C. Jin, J. Kim, M.I.B. Utama, E.C. Regan, H. Kleemann et al., Imaging of pure spin-valley diffusion current in WS2-WSe2 heterostructures. Science 360(6391), 893–896 (2018). https://doi.org/10.1126/science.aao3503
Y. Pang, Z. Yang, Y. Yang, T.L. Ren, Wearable electronics based on 2D materials for human physiological information detection. Small 16(15), 1901124 (2020). https://doi.org/10.1002/smll.201901124
A.V. Agrawal, N. Kumar, M. Kumar, Strategy and future prospects to develop room-temperature-recoverable NO2 gas sensor based on two-dimensional molybdenum disulfide. Nano-Micro Lett. 13(1), 38 (2021). https://doi.org/10.1007/s40820-020-00558-3
N.E. Holden, T.B. Coplen, J.K. Böhlke, L.V. Tarbox, J. Benefield et al., IUPAC periodic table of the elements and isotopes (IPTEI) for the education community (IUPAC Technical Report). Pure Appl. Chem. 90(12), 1833–2092 (2018). https://doi.org/10.1515/pac-2015-0703
K.F. Mak, J. Shan, Photonics and optoelectronics of 2D semiconductor transition metal dichalcogenides. Nat. Photon. 10(4), 216–226 (2016). https://doi.org/10.1038/nphoton.2015.282
L. Zeng, S. Lin, Z. Lou, H. Yuan, H. Long et al., Ultrafast and sensitive photodetector based on a PtSe2/silicon nanowire array heterojunction with a multiband spectral response from 200 to 1550 nm. NPG Asia Mater. 10(4), 352–362 (2018). https://doi.org/10.1038/s41427-018-0035-4
R. Kempt, A. Kuc, T. Heine, Two-dimensional noble-metal chalcogenides and phosphochalcogenides. Angew. Chem. Int. Ed. 59(24), 9242–9254 (2020). https://doi.org/10.1002/anie.201914886
S. Ahmad, Strain dependent tuning electronic properties of noble metal di chalcogenides PdX2 (X = S, Se) mono-layer. Mater. Chem. Phys. 198(1), 162–166 (2017). https://doi.org/10.1016/j.matchemphys.2017.05.060
L. Zeng, D. Wu, J. Jie, X. Ren, X. Hu et al., Van der Waals epitaxial growth of mosaic-like 2D platinum ditelluride layers for room-temperature mid-infrared photodetection up to 10.6 microm. Adv. Mater. 32(52), 2004412 (2020). https://doi.org/10.1002/adma.202004412
Y. Zhao, J. Qiao, Z. Yu, P. Yu, K. Xu et al., High-electron-mobility and air-stable 2D layered PtSe2 FETs. Adv. Mater. 29(5), 1604230 (2017). https://doi.org/10.1002/adma.201604230
H. Yang, Y. Li, Z. Yang, X. Shi, Z. Lin et al., First-principles calculations of the electronic properties of two-dimensional pentagonal structure XS2 (X=Ni, Pd, Pt). Vacuum 174(1), 109176 (2020). https://doi.org/10.1016/j.vacuum.2020.109176
D. Saraf, S. Chakraborty, A. Kshirsagar, R. Ahuja, In pursuit of bifunctional catalytic activity in PdS2 pseudo-monolayer through reaction coordinate mapping. Nano Energy 49(4), 283–289 (2018). https://doi.org/10.1016/j.nanoen.2018.04.019
M. Ghorbani-Asl, A. Kuc, P. Miro, T. Heine, A single-material logical junction based on 2D Crystal PdS2. Adv. Mater. 28(5), 853–856 (2016). https://doi.org/10.1002/adma.201504274
A.D. Oyedele, S. Yang, L. Liang, A.A. Puretzky, K. Wang et al., PdSe2: pentagonal two-dimensional layers with high air stability for electronics. J. Am. Chem. Soc. 139(40), 14090–14097 (2017). https://doi.org/10.1021/jacs.7b04865
Y. Gu, H. Cai, J. Dong, Y. Yu, A.N. Hoffman et al., Two-dimensional palladium diselenide with strong in-plane optical anisotropy and high mobility grown by chemical vapor deposition. Adv. Mater. 32(19), 1906238 (2020). https://doi.org/10.1002/adma.201906238
W.L. Chow, P. Yu, F. Liu, J. Hong, X. Wang et al., High mobility 2D palladium diselenide field-effect transistors with tunable ambipolar characteristics. Adv. Mater. 29(21), 1602969 (2017). https://doi.org/10.1002/adma.201602969
A.A. Puretzky, A.D. Oyedele, K. Xiao, A.V. Haglund, B.G. Sumpter et al., Anomalous interlayer vibrations in strongly coupled layered PdSe2. 2D Mater. 5(3), 35016 (2018). https://doi.org/10.1088/2053-1583/aabe4d
Q. Liang, Q. Wang, Q. Zhang, J. Wei, S.X. Lim et al., High-performance, room temperature, ultra-broadband photodetectors based on air-stable PdSe2. Adv. Mater. 31(24), 1807609 (2019). https://doi.org/10.1002/adma.201807609
H. Yang, S.W. Kim, M. Chhowalla, Y.H. Lee, Structural and quantum-state phase transitions in van der Waals layered materials. Nat. Phys. 13(10), 931–937 (2017). https://doi.org/10.1038/nphys4188
D. Wu, J. Guo, J. Du, C. Xia, L. Zeng et al., Highly polarization-sensitive, broadband, self-powered photodetector based on graphene/PdSe2/germanium heterojunction. ACS Nano 13(9), 9907–9917 (2019). https://doi.org/10.1021/acsnano.9b03994
K.L. Tai, J. Chen, Y. Wen, H. Park, Q. Zhang et al., Phase variations and layer epitaxy of 2D PdSe2 GRown on 2D monolayers by direct selenization of molecular Pd precursors. ACS Nano 14(9), 11677–11690 (2020). https://doi.org/10.1021/acsnano.0c04230
M. Jakhar, J. Singh, A. Kumar, K. Tankeshwar, Pressure and electric field tuning of Schottky contacts in PdSe2/ZT-MoSe2 van der Waals heterostructure. Nanotechnology 31(14), 145710 (2020). https://doi.org/10.1088/1361-6528/ab5de1
A.M. Afzal, M.Z. Iqbal, S. Mumtaz, I. Akhtar, Multifunctional and high-performance GeSe/PdSe2 heterostructure device with a fast photoresponse. J. Mater. Chem. C 8(14), 4743–4753 (2020). https://doi.org/10.1039/d0tc00004c
D. Wu, C. Jia, F. Shi, L. Zeng, P. Lin et al., Mixed-dimensional PdSe2/SiNWA heterostructure based photovoltaic detectors for self-driven, broadband photodetection, infrared imaging and humidity sensing. J. Mater. Chem. A 8(7), 3632–3642 (2020). https://doi.org/10.1039/c9ta13611h
L.H. Zeng, Q.M. Chen, Z.X. Zhang, D. Wu, H. Yuan et al., Multilayered PdSe2/perovskite schottky junction for fast, self-powered, polarization-sensitive, broadband photodetectors, and image sensor application. Adv. Sci. 6(19), 1901134 (2019). https://doi.org/10.1002/advs.201901134
J. Sun, H. Shi, T. Siegrist, D.J. Singh, Electronic, transport, and optical properties of bulk and mono-layer PdSe2. Appl. Phys. Lett. 107(15), 153902 (2015). https://doi.org/10.1063/1.4933302
F. Grønvold, E. Røst, The crystal structure of PdSe2 and PdS2. Acta Crystallogr. 10(4), 329–331 (1957). https://doi.org/10.1107/s0365110x57000948
J. Zhong, J. Yu, L. Cao, C. Zeng, J. Ding et al., High-performance polarization-sensitive photodetector based on a few-layered PdSe2 nanosheet. Nano Res. 13(6), 1780–1786 (2020). https://doi.org/10.1007/s12274-020-2804-y
Y. Zhao, J. Qiao, P. Yu, Z. Hu, Z. Lin et al., Extraordinarily strong interlayer interaction in 2D layered PtS2. Adv. Mater. 28(12), 2399–2407 (2016). https://doi.org/10.1002/adma.201504572
A.V. Kuklin, H. Ågren, Quasiparticle electronic structure and optical spectra of single-layer and bilayer PdSe2: Proximity and defect-induced band gap renormalization. Phys. Rev. B 99(24), 2469–9950 (2019). https://doi.org/10.1103/PhysRevB.99.245114
X. Zhao, Q. Zhao, B. Zhao, X. Dai, S. Wei et al., Electronic and optical properties of PdSe2 from monolayer to trilayer. Superlattices Microstr. 142(4), 106514 (2020). https://doi.org/10.1016/j.spmi.2020.106514
W. Lei, B. Cai, H. Zhou, G. Heymann, X. Tang et al., Ferroelastic lattice rotation and band-gap engineering in quasi 2D layered-structure PdSe2 under uniaxial stress. Nanoscale 11(25), 12317–12325 (2019). https://doi.org/10.1039/c9nr03101d
X. Zhao, B. Qiu, G. Hu, W. Yue, J. Ren et al., Spin polarization properties of pentagonal PdSe(2) induced by 3D transition-metal doping: first-principles calculations. Materials 11(11), 2339 (2018). https://doi.org/10.3390/ma11112339
S.-H. Zhang, B.-G. Liu, Hole-doping-induced half-metallic ferromagnetism in a highly-air-stable PdSe2 monolayer under uniaxial stress. J. Mater. Chem. C 6(25), 6792–6798 (2018). https://doi.org/10.1039/c8tc01450g
S. Deng, L. Li, Y. Zhang, Strain modulated electronic, mechanical, and optical properties of the monolayer PdS2, PdSe2, and PtSe2 for tunable devices. ACS Appl. Nano Mater. 1(4), 1932–1939 (2018). https://doi.org/10.1021/acsanm.8b00363
G. Liu, Q.M. Zeng, P.F. Zhu, R.G. Quhe, P.F. Lu, Negative Poisson’s ratio in monolayer PdSe2. Comput. Mater. Sci. 160(1), 309–314 (2019). https://doi.org/10.1016/j.commatsci.2019.01.024
M.A. ElGhazali, P.G. Naumov, H. Mirhosseini, V. Suss, L. Muchler et al., Pressure-induced superconductivity up to 13.1 K in the pyrite phase of palladium diselenide PdSe2. Phys. Rev. B 96(6), 060509 (2017). https://doi.org/10.1103/PhysRevB.96.060509
J. Yu, X. Kuang, Y. Gao, Y. Wang, K. Chen et al., Direct observation of the linear dichroism transition in two-dimensional palladium diselenide. Nano Lett. 20(2), 1172–1182 (2020). https://doi.org/10.1021/acs.nanolett.9b04598
W. Lei, S. Zhang, G. Heymann, X. Tang, J. Wen et al., A new 2D high-pressure phase of PdSe2 with high-mobility transport anisotropy for photovoltaic applications. J. Mater. Chem. C 7(7), 2096–2105 (2019). https://doi.org/10.1039/c8tc06050a
T.S. Walmsley, K. Andrews, T. Wang, A. Haglund, U. Rijal et al., Near-infrared optical transitions in PdSe2 phototransistors. Nanoscale 11(30), 14410–14416 (2019). https://doi.org/10.1039/c9nr03505b
M. Sun, J.P. Chou, L. Shi, J. Gao, A. Hu et al., Few-Layer PdSe2 sheets: promising thermoelectric materials driven by high valley convergence. ACS Omega 3(6), 5971–5979 (2018). https://doi.org/10.1021/acsomega.8b00485
Y. Cai, G. Zhang, Y.W. Zhang, Polarity-reversed robust carrier mobility in monolayer MoS(2) nanoribbons. J. Am. Chem. Soc. 136(17), 6269–6275 (2014). https://doi.org/10.1021/ja4109787
X.-J. Ge, D. Qin, K.-L. Yao, J.-T. Lü, First-principles study of thermoelectric transport properties of monolayer gallium chalcogenides. J. Phys. D-Appl. Phys. 50(40), 405301 (2017). https://doi.org/10.1088/1361-6463/aa85b4
G.D. Nguyen, L. Liang, Q. Zou, M. Fu, A.D. Oyedele et al., 3D imaging and manipulation of subsurface selenium vacancies in PdSe2. Phys. Rev. Lett. 121(8), 086101 (2018). https://doi.org/10.1103/PhysRevLett.121.086101
J. Lin, S. Zuluaga, P. Yu, Z. Liu, S.T. Pantelides et al., Novel Pd2Se3 two-dimensional phase driven by interlayer fusion in layered PdSe2. Phys. Rev. Lett. 119(1), 016101 (2017). https://doi.org/10.1103/PhysRevLett.119.016101
J. Chen, G.H. Ryu, S. Sinha, J.H. Warner, Atomic structure and dynamics of defects and grain boundaries in 2D Pd2Se3 Monolayers. ACS Nano 13(7), 8256–8264 (2019). https://doi.org/10.1021/acsnano.9b03645
S. Zuluaga, J. Lin, K. Suenaga, S.T. Pantelides, Two-dimensional PdSe2-Pd2Se3 junctions can serve as nanowires. 2D Mater. 5(3), 035025 (2018). https://doi.org/10.1088/2053-1583/aac34c
G.H. Ryu, T. Zhu, J. Chen, S. Sinha, V. Shautsova, Striated 2D lattice with sub-nm 1D etch channels by controlled thermally induced phase transformations of PdSe2. Adv. Mater. 31(46), 1904251 (2019). https://doi.org/10.1002/adma.201904251
V. Shautsova, S. Sinha, L. Hou, Q. Zhang, M. Tweedie et al., Direct laser patterning and phase transformation of 2D PdSe2 films for on-demand device fabrication. ACS Nano 13(12), 14162–14171 (2019). https://doi.org/10.1021/acsnano.9b06892
T. Takabatake, M. Ishikawa, J.L. Jorda, Superconductivity and phase relations in the Pd-Se system. J. Less Common Met. 134(1), 79–89 (1987). https://doi.org/10.1016/0022-5088(87)90444-9
A.D. Oyedele, S. Yang, T. Feng, A.V. Haglund, Y. Gu et al., Defect-mediated phase transformation in anisotropic two-dimensional PdSe2 crystals for seamless electrical contacts. J. Am. Chem. Soc. 141(22), 8928–8936 (2019). https://doi.org/10.1021/jacs.9b02593
D. Wang, F. Luo, M. Lu, X. Xie, L. Huang et al., Chemical vapor transport reactions for synthesizing layered materials and their 2D counterparts. Small 15(40), 1804404 (2019). https://doi.org/10.1002/smll.201804404
M. Long, Y. Wang, P. Wang, X. Zhou, H. Xia et al., Palladium diselenide long-wavelength infrared photodetector with high sensitivity and stability. ACS Nano 13(2), 2511–2519 (2019). https://doi.org/10.1021/acsnano.8b09476
M. Velicky, G.E. Donnelly, W.R. Hendren, S. McFarland, D. Scullion et al., Mechanism of gold-assisted exfoliation of centimeter-sized transition-metal dichalcogenide monolayers. ACS Nano 12(10), 10463–10472 (2018). https://doi.org/10.1021/acsnano.8b06101
M. Heyl, D. Burmeister, T. Schultz, S. Pallasch, G. Ligorio et al., Thermally activated gold-mediated transition metal dichalcogenide exfoliation and a unique gold-mediated transfer. Phys. Status Solidi (RRL) 14(11), 2000408 (2020). https://doi.org/10.1002/pssr.202000408
S.B. Desai, S.R. Madhvapathy, M. Amani, D. Kiriya, M. Hettick et al., Gold-mediated exfoliation of ultralarge optoelectronically-perfect monolayers. Adv. Mater. 28(21), 4053–4058 (2016). https://doi.org/10.1002/adma.201506171
Y. Huang, Y.H. Pan, R. Yang, L.H. Bao, L. Meng et al., Universal mechanical exfoliation of large-area 2D crystals. Nat. Commun. 11(1), 2453 (2020). https://doi.org/10.1038/s41467-020-16266-w
D. Zhao, S. Xie, Y. Wang, H. Zhu, L. Chen et al., Synthesis of large-scale few-layer PtS2 films by chemical vapor deposition. AIP Adv. 9(2), 025225 (2019). https://doi.org/10.1063/1.5086447
L. Jia, J. Wu, T. Yang, B. Jia, D.J. Moss, Large third-order optical kerr nonlinearity in nanometer-thick PdSe2 2D dichalcogenide films: implications for nonlinear photonic devices. ACS Appl. Nano Mater. 3(7), 6876–6883 (2020). https://doi.org/10.1021/acsanm.0c01239
J. Zhou, J. Lin, X. Huang, Y. Zhou, Y. Chen et al., A library of atomically thin metal chalcogenides. Nature 556(7701), 355–359 (2018). https://doi.org/10.1038/s41586-018-0008-3
L.H. Zeng, D. Wu, S.H. Lin, C. Xie, H.Y. Yuan et al., Controlled synthesis of 2D palladium diselenide for sensitive photodetector applications. Adv. Funct. Mater. 29(1), 1806878 (2019). https://doi.org/10.1002/adfm.201806878
L.S. Lu, G.H. Chen, H.Y. Cheng, C.P. Chuu, K.C. Lu et al., Layer-dependent and in-plane anisotropic properties of low-temperature synthesized few-layer PdSe2 single crystals. ACS Nano 14(4), 4963–4972 (2020). https://doi.org/10.1021/acsnano.0c01139
G.D. Nguyen, A.D. Oyedele, A. Haglund, W. Ko, L. Liang et al., Atomically precise PdSe2 pentagonal nanoribbons. ACS Nano 14(2), 1951–1957 (2020). https://doi.org/10.1021/acsnano.9b08390
L.H. Zeng, S.H. Lin, Z.J. Li, Z.X. Zhang, T.F. Zhang et al., Fast, self-driven, air-stable, and broadband photodetector based on vertically aligned PtSe2/GaAs heterojunction. Adv. Funct. Mater. 28(16), 1705970 (2018). https://doi.org/10.1002/adfm.201705970
A.N. Hoffman, Y. Gu, J. Tokash, J. Woodward, K. Xiao et al., Layer-by-layer thinning of pdse2 flakes via plasma induced oxidation and sublimation. ACS Appl. Mater. Interfaces 12(6), 7345–7350 (2020). https://doi.org/10.1021/acsami.9b21287
Q. Liang, Q. Zhang, J. Gou, T. Song, Arramel et al., Performance improvement by ozone treatment of 2D PdSe2. ACS Nano 14(5), 5668–5677 (2020). https://doi.org/10.1021/acsnano.0c00180
A. Di. Bartolomeo, F. Urban, A. Pelella, A. Grillo, M. Passacantando et al., Electron irradiation of multilayer PdSe2 field effect transistors. Nanotechnology 31(37), 375204 (2020). https://doi.org/10.1088/1361-6528/ab9472
A. Hassan, Y. Guo, Q. Wang, Performance of the pentagonal PdSe2 sheet as a channel material in contact with metal surfaces and graphene. ACS Appl. Electron. Mater. 2(8), 2535–2542 (2020). https://doi.org/10.1021/acsaelm.0c00438
A. Di. Bartolomeo, A. Pelella, X. Liu, F. Miao, M. Passacantando et al., Pressure-tunable ambipolar conduction and hysteresis in thin palladium diselenide field effect transistors. Adv. Funct. Mater. 29(29), 1902483 (2019). https://doi.org/10.1002/adfm.201902483
J. Gao, Y. Gao, Y. Han, J. Pang, C. Wang et al., Ultrasensitive label-free MiRNA sensing based on a flexible graphene field-effect transistor without functionalization. ACS Appl. Electron. Mater. 2(4), 1090–1098 (2020). https://doi.org/10.1021/acsaelm.0c00095
A. Tankut, M. Karaman, I. Yildiz, S. Canli, R. Turan, Effect of Al vacuum annealing prior to a-Si deposition on aluminum-induced crystallization. Phys. Status Solidi A Appl. Mater. Sci. 212(12), 2702–2707 (2015). https://doi.org/10.1002/pssa.201532857
T. Takenobu, T. Kanbara, N. Akima, T. Takahashi, M. Shiraishi et al., Control of carrier density by a solution method in carbon-nanotube devices. Adv. Mater. 17(20), 2430–2434 (2005). https://doi.org/10.1002/adma.200500759
F. Giubileo, A. Grillo, L. Iemmo, G. Luongo, F. Urban et al., Environmental effects on transport properties of PdSe2 field effect transistors. Mater. Today Proc. 20(1), 50–53 (2020). https://doi.org/10.1016/j.matpr.2019.08.226
G.T. Xia, Y.N. Huang, F.J. Li, L.C. Wang, J.B. Pang et al., A thermally flexible and multi-site tactile sensor for remote 3D dynamic sensing imaging. Front. Chem. Sci. Eng. 14(6), 1039–1051 (2020). https://doi.org/10.1007/s11705-019-1901-5
D. Chen, Z. Liu, Y. Li, D. Sun, X. Liu et al., Unsymmetrical alveolate PMMA/MWCNT film as a piezoresistive E-skin with four-dimensional resolution and application for detecting motion direction and airflow rate. ACS Appl. Mater. Interfaces 12(27), 30896–30904 (2020). https://doi.org/10.1021/acsami.0c02640
Y. Zhou, Y. Wang, K. Wang, L. Kang, F. Peng et al., Hybrid genetic algorithm method for efficient and robust evaluation of remaining useful life of supercapacitors. Appl. Energy 260(1), 114169 (2020). https://doi.org/10.1016/j.apenergy.2019.114169
X. Shang, S. Li, K. Wang, X. Teng, X. Wang et al., MnSe2/Se composite nanobelts as an improved performance anode for lithium storage. Int. J. Electrochem. Sci. 14(1), 6000–6008 (2019). https://doi.org/10.20964/2019.07.37
C. Bu, F. Li, K. Yin, J. Pang, L. Wang et al., Research progress and prospect of triboelectric nanogenerators as self-powered human body sensors. ACS Appl. Electron. Mater. 2(4), 863–878 (2020). https://doi.org/10.1021/acsaelm.0c00022
S.C. Dhanabalan, J.S. Ponraj, H. Zhang, Q. Bao, Present perspectives of broadband photodetectors based on nanobelts, nanoribbons, nanosheets and the emerging 2D materials. Nanoscale 8(12), 6410–6434 (2016). https://doi.org/10.1039/c5nr09111j
A. Di. Bartolomeo, A. Pelella, F. Urban, A. Grillo, L. Iemmo et al., Field emission in ultrathin PdSe2 back-gated transistors. Adv. Electron. Mater. 6(7), 2000094 (2020). https://doi.org/10.1002/aelm.202000094
R. Zhuo, L. Zeng, H. Yuan, D. Wu, Y. Wang et al., In-situ fabrication of PtSe2/GaN heterojunction for self-powered deep ultraviolet photodetector with ultrahigh current on/off ratio and detectivity. Nano Res. 12(1), 183–189 (2018). https://doi.org/10.1007/s12274-018-2200-z
M. Buscema, D.J. Groenendijk, S.I. Blanter, G.A. Steele, H.S. van der Zant et al., Fast and broadband photoresponse of few-layer black phosphorus field-effect transistors. Nano Lett. 14(6), 3347–3352 (2014). https://doi.org/10.1021/nl5008085
X. Wan, Y. Xu, H. Guo, K. Shehzad, A. Ali et al., A self-powered high-performance graphene/silicon ultraviolet photodetector with ultra-shallow junction: breaking the limit of silicon? NPJ 2D Mater. Appl. 1(1), 2397–7132 (2017). https://doi.org/10.1038/s41699-017-0008-4
R. Zhuo, Y. Wang, D. Wu, Z. Lou, Z. Shi et al., High-performance self-powered deep ultraviolet photodetector based on MoS2/GaN p–n heterojunction. J. Mater. Chem. C 6(2), 299–303 (2018). https://doi.org/10.1039/c7tc04754a
E.P. Mukhokosi, S.B. Krupanidhi, K.K. Nanda, Band gap engineering of hexagonal SnSe2 nanostructured thin films for infra-red photodetection. Sci. Rep. 7(1), 15215 (2017). https://doi.org/10.1038/s41598-017-15519-x
L.B. Luo, D. Wang, C. Xie, J.G. Hu, X.Y. Zhao et al., PdSe2 multilayer on germanium nanocones array with light trapping effect for sensitive infrared photodetector and image sensing application. Adv. Funct. Mater. 29(22), 1900849 (2019). https://doi.org/10.1002/adfm.201900849
Y. Yang, S.C. Liu, X. Wang, Z. Li, Y. Zhang et al., Polarization-sensitive ultraviolet photodetection of anisotropic 2D GeS2. Adv. Funct. Mater. 29(16), 1900411 (2019). https://doi.org/10.1002/adfm.201900411
F. Chu, M. Chen, Y. Wang, Y. Xie, B. Liu et al., A highly polarization sensitive antimonene photodetector with a broadband photoresponse and strong anisotropy. J. Mater. Chem. C 6(10), 2509–2514 (2018). https://doi.org/10.1039/c7tc05488b
P.K. Venuthurumilli, P.D. Ye, X. Xu, Plasmonic Resonance enhanced polarization-sensitive photodetection by black phosphorus in near infrared. ACS Nano 12(5), 4861–4867 (2018). https://doi.org/10.1021/acsnano.8b01660
Y. Yang, S.C. Liu, W. Yang, Z. Li, Y. Wang et al., Air-stable in-plane anisotropic GeSe2 for highly polarization-sensitive photodetection in short wave region. J. Am. Chem. Soc. 140(11), 4150–4156 (2018). https://doi.org/10.1021/jacs.8b01234
J. Bullock, M. Amani, J. Cho, Y.-Z. Chen, G.H. Ahn et al., Polarization-resolved black phosphorus/molybdenum disulfide mid-wave infrared photodiodes with high detectivity at room temperature. Nat. Photon. 12(10), 601–607 (2018). https://doi.org/10.1038/s41566-018-0239-8
J. Du, M. Zhang, Z. Guo, J. Chen, X. Zhu et al., Phosphorene quantum dot saturable absorbers for ultrafast fiber lasers. Sci. Rep. 7(1), 42357 (2017). https://doi.org/10.1038/srep42357
Y.F. Ma, S.C. Zhang, S.J. Din, X.X. Liu, X. Yu et al., Passively Q-switched Nd:GdLaNbO4 laser based on 2D PdSe2 nanosheet. Opt. Laser Technol. 124(1), 105959 (2020). https://doi.org/10.1016/j.optlastec.2019.105959
Y.F. Ma, Z.F. Peng, S.J. Ding, H.Y. Sun, F. Peng et al., Two-dimensional WS2 nanosheet based passively Q-switched Nd:GdLaNbO4 laser. Opt. Laser Technnol. 115(1), 104–108 (2019). https://doi.org/10.1016/j.optlastec.2019.02.015
P.K. Cheng, C.Y. Tang, S. Ahmed, J. Qiao, L.H. Zeng et al., Utilization of group 10 2D TMDs-PdSe2 as a nonlinear optical material for obtaining switchable laser pulse generation modes. Nanotechnology 32(5), 055201 (2021). https://doi.org/10.1088/1361-6528/abc1a2
J. Pang, A. Bachmatiuk, Y. Yin, B. Trzebicka, L. Zhao et al., Applications of phosphorene and black phosphorus in energy conversion and storage devices. Adv. Energy Mater. 8(8), 1702093 (2018). https://doi.org/10.1002/aenm.201702093
J. Pang, R.G. Mendes, A. Bachmatiuk, L. Zhao, H.Q. Ta et al., Applications of 2D MXenes in energy conversion and storage systems. Chem. Soc. Rev. 48(1), 72–133 (2019). https://doi.org/10.1039/c8cs00324f
K. Olszowska, J. Pang, P.S. Wrobel, L. Zhao, H.Q. Ta et al., Three-dimensional nanostructured graphene: synthesis and energy, environmental and biomedical applications. Synth. Met. 234(1), 53–85 (2017). https://doi.org/10.1016/j.synthmet.2017.10.014
J. Zhou, H. Chen, X. Zhang, K. Chi, Y. Cai et al., Substrate dependence on (Sb4Se6)n ribbon orientations of antimony selenide thin films: morphology, carrier transport and photovoltaic performance. J. Alloys Compd. 862(1), 158703 (2021). https://doi.org/10.1016/j.jallcom.2021.158703
F. Shu, M. Wang, J. Pang, P. Yu, A free-standing superhydrophobic film for highly efficient removal of water from turbine oil. Front. Chem. Sci. Eng. 13(2), 393–399 (2019). https://doi.org/10.1007/s11705-018-1754-3
K. Wang, J. Pang, L. Li, S. Zhou, Y. Li et al., Synthesis of hydrophobic carbon nanotubes/reduced graphene oxide composite films by flash light irradiation. Front. Chem. Sci. Eng. 12(3), 376–382 (2018). https://doi.org/10.1007/s11705-018-1705-z
Y. Yin, J. Pang, J. Wang, X. Lu, Q. Hao et al., Graphene-activated optoplasmonic nanomembrane cavities for photodegradation detection. ACS Appl. Mater. Interfaces 11(17), 15891–15897 (2019). https://doi.org/10.1021/acsami.9b00733
F.-X. Liang, J.-Z. Wang, Z.-X. Zhang, Y.-Y. Wang, Y. Gao et al., Broadband, ultrafast, self-driven photodetector based on Cs-doped FAPbI3 perovskite thin film. Adv. Opt. Mater. 5(22), 1700654 (2017). https://doi.org/10.1002/adom.201700654
M. Long, A. Gao, P. Wang, H. Xia, C. Ott et al., Room temperature high-detectivity mid-infrared photodetectors based on black arsenic phosphorus. Sci. Adv. 3(6), e1700589 (2017). https://doi.org/10.1126/sciadv.1700589
X. Yu, P. Yu, D. Wu, B. Singh, Q. Zeng et al., Atomically thin noble metal dichalcogenide: a broadband mid-infrared semiconductor. Nat. Commun. 9(1), 1545 (2018). https://doi.org/10.1038/s41467-018-03935-0
A.L. Hsu, P.K. Herring, N.M. Gabor, S. Ha, Y.C. Shin et al., Graphene-based thermopile for thermal imaging applications. Nano Lett. 15(11), 7211–7216 (2015). https://doi.org/10.1021/acs.nanolett.5b01755
J. Piotrowski, A. Rogalski, Uncooled long wavelength infrared photon detectors. Infrared Phys. Technol. 46(1–2), 115–131 (2004). https://doi.org/10.1016/j.infrared.2004.03.016
Y. Cao, X. Zhu, H. Chen, X. Zhang, J. Zhouc et al., Towards high efficiency inverted Sb2Se3 thin film solar cells. Sol. Energy Mater. Sol. Cells 200(1), 109945 (2019). https://doi.org/10.1016/j.solmat.2019.109945
Y. Cao, X. Zhu, J. Jiang, C. Liu, J. Zhou et al., Rotational design of charge carrier transport layers for optimal antimony trisulfide solar cells and its integration in tandem devices. Sol. Energy Mater. Sol. Cells 206(1), 110279 (2020). https://doi.org/10.1016/j.solmat.2019.110279
J. Jiang, F. Meng, Q. Cheng, A. Wang, Y. Chen et al., Low lattice mismatch InSe–Se vertical van der Waals heterostructure for high-performance transistors via strong fermi-level depinning. Small Methods 4(8), 2000238 (2020). https://doi.org/10.1002/smtd.202000238
J. Jiang, F. Meng, Q. Cheng, A. Wang, Y. Chen et al., Low lattice mismatch InSe–Se vertical van der Waals heterostructure for high-performance transistors via strong fermi-level depinning (Small Methods 8/2020). Small Methods 4(8), 2070032 (2020). https://doi.org/10.1002/smtd.202070032
C.-C. Wu, D. Jariwala, V.K. Sangwan, T.J. Marks, M.C. Hersam et al., Elucidating the photoresponse of ultrathin MoS2 field-effect transistors by scanning photocurrent microscopy. J. Phys. Chem. Lett. 4(15), 2508–2513 (2013). https://doi.org/10.1021/jz401199x
F. Xue, L. Chen, J. Chen, J. Liu, L. Wang et al., p-Type MoS2 and n-type ZnO diode and its performance enhancement by the piezophototronic effect. Adv. Mater. 28(17), 3391–3398 (2016). https://doi.org/10.1002/adma.201506472
D. Li, M. Chen, Z. Sun, P. Yu, Z. Liu et al., Two-dimensional non-volatile programmable p–n junctions. Nat. Nanotechnol. 12(9), 901–906 (2017). https://doi.org/10.1038/nnano.2017.104
X. Zhang, J. Grajal, J.L. Vazquez-Roy, U. Radhakrishna, X. Wang et al., Two-dimensional MoS2-enabled flexible rectenna for Wi-Fi-band wireless energy harvesting. Nature 566(7744), 368–372 (2019). https://doi.org/10.1038/s41586-019-0892-1
A.M. Afzal, G. Dastgeer, M.Z. Iqbal, P. Gautam, M.M. Faisal, High-performance p-BP/n-PdSe2 near-infrared photodiodes with a fast and gate-tunable photoresponse. ACS Appl. Mater. Interfaces 12(17), 19625–19634 (2020). https://doi.org/10.1021/acsami.9b22898
J.A. Leñero-Bardallo, R. Carmona-Galán, A. Rodríguez-Vázquez, Applications of event-based image sensors—review and analysis. Int. J. Circ. Theor. Appl. 46(9), 1620–1630 (2018). https://doi.org/10.1002/cta.2546
F.X. Liang, X.Y. Zhao, J.J. Jiang, J.G. Hu, W.Q. Xie et al., Light confinement effect induced highly sensitive, self-driven near-infrared photodetector and image sensor based on multilayer PdSe2 /pyramid Si heterojunction. Small 15(44), 1903831 (2019). https://doi.org/10.1002/smll.201903831
I. Ibrahim, J. Kalbacova, V. Engemaier, J.B. Pang, R.D. Rodriguez et al., Confirming the dual role of etchants during the enrichment of semiconducting single wall carbon nanotubes by chemical vapor deposition. Chem. Mater. 27(17), 5964–5973 (2015). https://doi.org/10.1021/acs.chemmater.5b02037
J. Pang, R.G. Mendes, P.S. Wrobel, M.D. Wlodarski, H.Q. Ta et al., Self-terminating confinement approach for large-area uniform monolayer graphene directly over Si/SiOx by chemical vapor deposition. ACS Nano 11(2), 1946–1956 (2017). https://doi.org/10.1021/acsnano.6b08069
J. Pang, A. Bachmatiuk, I. Ibrahim, L. Fu, D. Placha et al., CVD growth of 1D and 2D sp2 carbon nanomaterials. J. Mater. Sci. 51(2), 640–667 (2015). https://doi.org/10.1007/s10853-015-9440-z
A. Soni, L. Zhao, H.Q. Ta, Q. Shi, J. Pang et al., Facile graphitization of silicon nano-particles with ethanol based chemical vapor deposition. Nano-Struct. Nano-Objects 16(1), 38–44 (2018). https://doi.org/10.1016/j.nanoso.2018.04.001
B. Sun, J. Pang, Q. Cheng, S. Zhang, C. Zhang et al., Synthesis of wafer-scale graphene with chemical vapor deposition for electronic device applications. Adv. Mater. Technol. 1, 2000744 (2021). https://doi.org/10.1002/admt.202000744
G.S. Martynkova, F. Becerik, D. Placha, J. Pang, H. Akbulut et al., Effect of milling and annealing on carbon-silver system. J. Nanosci. Nanotechnol. 19(5), 2770–2774 (2019). https://doi.org/10.1166/jnn.2019.15869
M.H. Rummeli, S. Gorantla, A. Bachmatiuk, J. Phieler, N. Geissler et al., On the role of vapor trapping for chemical vapor deposition (CVD) grown graphene over copper. Chem. Mater. 25(24), 4861–4866 (2013). https://doi.org/10.1021/cm401669k
J.B. Pang, A. Bachmatiuk, L. Fu, C.L. Yan, M.Q. Zeng et al., Oxidation as a means to remove surface contaminants on Cu foil prior to graphene growth by chemical vapor deposition. J. Phys. Chem. C 119(23), 13363–13368 (2015). https://doi.org/10.1021/acs.jpcc.5b03911
J.B. Pang, A. Bachmatiuk, L. Fu, R.G. Mendes, M. Libera et al., Direct synthesis of graphene from adsorbed organic solvent molecules over copper. RSC Adv. 5(75), 60884–60891 (2015). https://doi.org/10.1039/c5ra09405d
N.M. Santhosh, G. Filipič, E. Kovacevic, A. Jagodar, J. Berndt et al., N-graphene nanowalls via plasma nitrogen incorporation and substitution: the experimental evidence. Nano-Micro Lett. 12(1), 53 (2020). https://doi.org/10.1007/s40820-020-0395-5
R.G. Mendes, J. Pang, A. Bachmatiuk, H.Q. Ta, L. Zhao et al., Electron-driven in situ transmission electron microscopy of 2D transition metal dichalcogenides and their 2D heterostructures. ACS Nano 13(2), 978–995 (2019). https://doi.org/10.1021/acsnano.8b08079
D. Zhang, T. Liu, J. Cheng, Q. Cao, G. Zheng et al., Lightweight and high-performance microwave absorber based on 2D WS2–RGO heterostructures. Nano-Micro Lett. 11(1), 38 (2019). https://doi.org/10.1007/s40820-019-0270-4
K. Persson, Materials Data on PdSe2 (SG:61) by Materials Project. https://doi.org/10.17188/1199960
L.-Y. Feng, R.A.B. Villaos, Z.-Q. Huang, C.-H. Hsu, F.-C. Chuang, Layer-dependent band engineering of Pd dichalcogenides: a first-principles study. New J. Phys. 22(5), 053010 (2020). https://doi.org/10.1088/1367-2630/ab7d7a
K. Persson, Materials Data on PdS2 (SG:61) by Materials Project. https://doi.org/10.17188/1189716
K. Persson. Materials Data on Te2Pd (SG:164) by Materials Project. https://doi.org/10.17188/1307608
G. Anemone, P. Casado Aguilar, M. Garnica, F. Calleja, A. Al Taleb et al., Electron–phonon coupling in superconducting 1T-PdTe2. NPJ 2D Mater. Appl. 5(1), 25 (2021). https://doi.org/10.1038/s41699-021-00204-5
R.N. Madhu, Singh, Palladium selenides as active methanol tolerant cathode materials for direct methanol fuel cell. Int. J. Hydrogen Energy 36(16), 10006–10012 (2011). https://doi.org/10.1016/j.ijhydene.2011.05.069
D. Qin, P. Yan, G. Ding, X. Ge, H. Song et al., Monolayer PdSe2: a promising two-dimensional thermoelectric material. Sci. Rep. 8(1), 2764 (2018). https://doi.org/10.1038/s41598-018-20918-9
G. Zhang, M. Amani, A. Chaturvedi, C. Tan, J. Bullock et al., Optical and electrical properties of two-dimensional palladium diselenide. Appl. Phys. Lett. 114(25), 253102 (2019). https://doi.org/10.1063/1.5097825
A.N. Hoffman, Y. Gu, L. Liang, J.D. Fowlkes, K. Xiao et al., Exploring the air stability of PdSe2 via electrical transport measurements and defect calculations. NPJ 2D Mater. Appl. 3(1), 50 (2019). https://doi.org/10.1038/s41699-019-0132-4
H. Fang, W. Hu, Photogating in low dimensional photodetectors. Adv. Sci. 4(12), 1700323 (2017). https://doi.org/10.1002/advs.201700323
P. Miro, M. Ghorbani-Asl, T. Heine, Two dimensional materials beyond MoS2: noble-transition-metal dichalcogenides. Angew. Chem. Int. Ed. 53(11), 3015–3018 (2014). https://doi.org/10.1002/anie.201309280
L. Li, W. Wang, Y. Chai, H. Li, M. Tian et al., Few-layered PtS2 phototransistor on h-BN with high gain. Adv. Funct. Mater. 27(27), 1701011 (2017). https://doi.org/10.1002/adfm.201701011
H. Xu, H.P. Huang, H. Fei, J. Feng, H.R. Fuh et al., Strategy for fabricating wafer-scale platinum disulfide. ACS Appl. Mater. Interfaces 11(8), 8202–8209 (2019). https://doi.org/10.1021/acsami.8b19218
E. Zhang, Y. Jin, X. Yuan, W. Wang, C. Zhang et al., ReS2-based field-effect transistors and photodetectors. Adv. Funct. Mater. 25(26), 4076–4082 (2015). https://doi.org/10.1002/adfm.201500969
J. Shim, A. Oh, D.H. Kang, S. Oh, S.K. Jang et al., High-performance 2D rhenium disulfide (ReS2) transistors and photodetectors by oxygen plasma treatment. Adv. Mater. 28(32), 6985–6992 (2016). https://doi.org/10.1002/adma.201601002
E. Zhang, P. Wang, Z. Li, H. Wang, C. Song et al., Tunable ambipolar polarization-sensitive photodetectors based on high-anisotropy ReSe2 nanosheets. ACS Nano 10(8), 8067–8077 (2016). https://doi.org/10.1021/acsnano.6b04165
M. Hafeez, L. Gan, H. Li, Y. Ma, T. Zhai, Chemical vapor deposition synthesis of ultrathin hexagonal ReSe2 flakes for anisotropic raman property and optoelectronic application. Adv. Mater. 28(37), 8296–8301 (2016). https://doi.org/10.1002/adma.201601977
W. Feng, J.-B. Wu, X. Li, W. Zheng, X. Zhou et al., Ultrahigh photo-responsivity and detectivity in multilayer InSe nanosheets phototransistors with broadband response. J. Mater. Chem. C 3(27), 7022–7028 (2015). https://doi.org/10.1039/c5tc01208b
M. Dai, H. Chen, R. Feng, W. Feng, Y. Hu et al., A dual-band multilayer InSe self-powered photodetector with high performance induced by surface plasmon resonance and asymmetric Schottky junction. ACS Nano 12(8), 8739–8747 (2018). https://doi.org/10.1021/acsnano.8b04931
J. Ye, S. Soeda, Y. Nakamura, O. Nittono, Crystal structures and phase transformation in In2Se3 compound semiconductor. Jpn. J. Appl. Phys. 37, 4264–4271 (1998). https://doi.org/10.1143/jjap.37.4264
W. Feng, F. Gao, Y. Hu, M. Dai, H. Liu et al., Phase-engineering-driven enhanced electronic and optoelectronic performance of multilayer In2Se3 nanosheets. ACS Appl. Mater. Interfaces 10(33), 27584–27588 (2018). https://doi.org/10.1021/acsami.8b10194
R.B. Jacobs-Gedrim, M. Shanmugam, N. Jain, C.A. Durcan, M.T. Murphy et al., Extraordinary photoresponse in two-dimensional In(2)Se(3) nanosheets. ACS Nano 8(1), 514–521 (2014). https://doi.org/10.1021/nn405037s
M. Amani, E. Regan, J. Bullock, G.H. Ahn, A. Javey, Mid-wave infrared photoconductors based on black phosphorus-arsenic alloys. ACS Nano 11(11), 11724–11731 (2017). https://doi.org/10.1021/acsnano.7b07028
D. Zheng, H. Fang, M. Long, F. Wu, P. Wang et al., High-performance near-infrared photodetectors based on p-type SnX (X = S, Se) nanowires grown via chemical vapor deposition. ACS Nano 12(7), 7239–7245 (2018). https://doi.org/10.1021/acsnano.8b03291
G. Su, V.G. Hadjiev, P.E. Loya, J. Zhang, S. Lei et al., Chemical vapor deposition of thin crystals of layered semiconductor SnS2 for fast photodetection application. Nano Lett. 15(1), 506–513 (2015). https://doi.org/10.1021/nl503857r
F. Xia, T. Mueller, Y.M. Lin, A. Valdes-Garcia, P. Avouris, Ultrafast graphene photodetector. Nat. Nanotechnol. 4(12), 839–843 (2009). https://doi.org/10.1038/nnano.2009.292
B.J. Kim, H. Jang, S.K. Lee, B.H. Hong, J.H. Ahn et al., High-performance flexible graphene field effect transistors with ion gel gate dielectrics. Nano Lett. 10(9), 3464–3466 (2010). https://doi.org/10.1021/nl101559n
E.O. Polat, G. Mercier, I. Nikitskiy, E. Puma, T. Galan et al., Flexible graphene photodetectors for wearable fitness monitoring. Sci. Adv. 5(9), eaaw7846 (2019). https://doi.org/10.1126/sciadv.aaw7846
X. Yu, Z. Dong, Y. Liu, T. Liu, J. Tao et al., A high performance, visible to mid-infrared photodetector based on graphene nanoribbons passivated with HfO2. Nanoscale 8(1), 327–332 (2016). https://doi.org/10.1039/c5nr06869j
L. Zeng, L. Tao, C. Tang, B. Zhou, H. Long et al., High-responsivity UV-Vis photodetector based on transferable WS2 film deposited by magnetron sputtering. Sci. Rep. 6(1), 20343 (2016). https://doi.org/10.1038/srep20343
J. Jiang, Q. Zhang, A. Wang, Y. Zhang, F. Meng, C. Zhang, X. Feng, Y. Feng, L. Gu, H. Liu, L. Han, A facile and effective method for patching sulfur vacancies of WS2 via nitrogen plasma treatment. Small 15(36), 1901791 (2019). https://doi.org/10.1002/smll.201901791
Q. Wang, Q. Zhang, X. Zhao, Y.J. Zheng, J. Wang et al., High-energy gain upconversion in monolayer tungsten disulfide photodetectors. Nano Lett. 19(8), 5595–5603 (2019). https://doi.org/10.1021/acs.nanolett.9b02136
W. Zhang, M.H. Chiu, C.H. Chen, W. Chen, L.J. Li et al., Role of metal contacts in high-performance phototransistors based on WSe2 monolayers. ACS Nano 8(8), 8653–8661 (2014). https://doi.org/10.1021/nn503521c
H. Zhou, C. Wang, J.C. Shaw, R. Cheng, Y. Chen et al., Large area growth and electrical properties of p-type WSe2 atomic layers. Nano Lett. 15(1), 709–713 (2015). https://doi.org/10.1021/nl504256y
J. Chen, Q. Wang, Y. Sheng, G. Cao, P. Yang et al., High-performance WSe2 photodetector based on a laser-induced p–n junction. ACS Appl. Mater. Interfaces 11(46), 43330–43336 (2019). https://doi.org/10.1021/acsami.9b13948
H.S. Lee, S.W. Min, Y.G. Chang, M.K. Park, T. Nam et al., MoS(2) nanosheet phototransistors with thickness-modulated optical energy gap. Nano Lett. 12(7), 3695–3700 (2012). https://doi.org/10.1021/nl301485q
Y.H. Zhou, H.N. An, C. Gao, Z.Q. Zheng, B. Wang, UV–Vis-NIR photodetector based on monolayer MoS2. Mater. Lett. 237(1), 298–302 (2019). https://doi.org/10.1016/j.matlet.2018.11.112
W. Wang, A. Klots, D. Prasai, Y. Yang, K.I. Bolotin et al., Hot electron-based near-infrared photodetection using bilayer MoS2. Nano Lett. 15(11), 7440–7444 (2015). https://doi.org/10.1021/acs.nanolett.5b02866
C. Jung, S.M. Kim, H. Moon, G. Han, J. Kwon et al., Highly crystalline CVD-grown multilayer MoSe2 thin film transistor for fast photodetector. Sci. Rep. 5(1), 15313 (2015). https://doi.org/10.1038/srep15313
R. Coehoorn, C. Haas, R.A. de Groot, Electronic structure of MoSe2, MoS2, and WSe2. II. The nature of the optical band gaps. Phys. Rev. B 35(12), 6203–6206 (1987). https://doi.org/10.1103/physrevb.35.6203
P.J. Ko, A. Abderrahmane, N.H. Kim, A. Sandhu, High-performance near-infrared photodetector based on nano-layered MoSe2. Semicond. Sci. Technol. 32(6), 065015 (2017). https://doi.org/10.1088/1361-6641/aa6819
V. Tran, R. Soklaski, Y. Liang, L. Yang, Layer-controlled band gap and anisotropic excitons in few-layer black phosphorus. Phys. Rev. B 89(23), 235319 (2014). https://doi.org/10.1103/PhysRevB.89.235319
Q. Guo, A. Pospischil, M. Bhuiyan, H. Jiang, H. Tian et al., Black phosphorus mid-infrared photodetectors with high gain. Nano Lett. 16(7), 4648–4655 (2016). https://doi.org/10.1021/acs.nanolett.6b01977
J. Qiao, X. Kong, Z.X. Hu, F. Yang, W. Ji, High-mobility transport anisotropy and linear dichroism in few-layer black phosphorus. Nat. Commun. 5(1), 4475 (2014). https://doi.org/10.1038/ncomms5475
J. Wang, A. Rousseau, E. Eizner, A.-L. Phaneuf-L’Heureux, L. Schue et al., Spectral responsivity and photoconductive gain in thin film black phosphorus photodetectors. ACS Photon. 6(12), 3092–3099 (2019). https://doi.org/10.1021/acsphotonics.9b00951
X. Zhou, X. Hu, B. Jin, J. Yu, K. Liu et al., Highly anisotropic GeSe nanosheets for phototransistors with ultrahigh photoresponsivity. Adv. Sci. 5(8), 1800478 (2018). https://doi.org/10.1002/advs.201800478
C. Jia, D. Wu, E.P. Wu, J.W. Guo, Z.H. Zhao et al., A self-powered high-performance photodetector based on a MoS2/GaAs heterojunction with high polarization sensitivity. J. Mater. Chem. C. 7(13), 3817–3821 (2019). https://doi.org/10.1039/c8tc06398b
R. Chai, Y. Chen, M. Zhong, H. Yang, F. Yan et al., Non-layered ZnSb nanoplates for room temperature infrared polarized photodetectors. J. Mater. Chem. C 8(19), 6388–6395 (2020). https://doi.org/10.1039/d0tc00755b
S. Deng, M.L. Tao, J. Mei, M. Li, Y. Zhang et al., Optical and piezoelectric properties of strained orthorhombic PdS2. IEEE Trans. Nanotechnol. 18(1), 358–364 (2019). https://doi.org/10.1109/Tnano.2019.2908221
Y. Deng, Z. Luo, N.J. Conrad, H. Liu, Y. Gong et al., Black phosphorus-monolayer MoS2 van der Waals heterojunction p–n diode. ACS Nano 8(8), 8292–8299 (2014). https://doi.org/10.1021/nn5027388
F. Yan, L. Zhao, A. Patane, P. Hu, X. Wei et al., Fast, multicolor photodetection with graphene-contacted p-GaSe/n-InSe van der Waals heterostructures. Nanotechnology 28(27), 27LT01 (2017). https://doi.org/10.1088/1361-6528/aa749e
X. Chen, H. Chen, Z. Wang, Y. Shan, D.W. Zhang et al., Analysis of the relationship between the contact barrier and rectification ratio in a two-dimensional P–N heterojunction. Semicond. Sci. Technol. 33(11), 114012 (2018). https://doi.org/10.1088/1361-6641/aae3aa
K. Murali, M. Dandu, S. Das, K. Majumdar, Gate-tunable WSe2/SnSe2 backward diode with ultrahigh-reverse rectification ratio. ACS Appl. Mater. Interfaces 10(6), 5657–5664 (2018). https://doi.org/10.1021/acsami.7b18242
M.A. Khan, S. Rathi, D. Lim, S.J. Yun, D.-H. Youn et al., Gate tunable self-biased diode based on few layered MoS2 and WSe2. Chem. Mater. 30(3), 1011–1016 (2018). https://doi.org/10.1021/acs.chemmater.7b04865
Z. Yang, L. Liao, F. Gong, F. Wang, Z. Wang et al., WSe2/GeSe heterojunction photodiode with giant gate tunability. Nano Energy 49(1), 103–108 (2018). https://doi.org/10.1016/j.nanoen.2018.04.034
C. Lan, C. Li, S. Wang, T. He, T. Jiao et al., Zener tunneling and photoresponse of a WS2/Si van der Waals heterojunction. ACS Appl. Mater. Interfaces 8(28), 18375–18382 (2016). https://doi.org/10.1021/acsami.6b05109
J. Chu, F. Wang, L. Yin, L. Lei, C. Yan et al., High-performance ultraviolet photodetector based on a few-layered 2D NiPS3 nanosheet. Adv. Funct. Mater. 27(32), 1701342 (2017). https://doi.org/10.1002/adfm.201701342
L. Ye, H. Li, Z. Chen, J. Xu, Near-infrared photodetector based on MoS2/black phosphorus heterojunction. ACS Photon. 3(4), 692–699 (2016). https://doi.org/10.1021/acsphotonics.6b00079
Y. Zhang, Y. Yu, L. Mi, H. Wang, Z. Zhu et al., In situ fabrication of vertical multilayered MoS2/Si homotype heterojunction for high-speed visible-near-infrared photodetectors. Small 12(8), 1062–1071 (2016). https://doi.org/10.1002/smll.201502923
Q. Liu, B. Cook, M. Gong, Y. Gong, D. Ewing et al., Printable transfer-free and wafer-size MoS2/graphene van der Waals heterostructures for high-performance photodetection. ACS Appl. Mater. Interfaces 9(14), 12728–12733 (2017). https://doi.org/10.1021/acsami.7b00912
A. Gundimeda, S. Krishna, N. Aggarwal, A. Sharma, N.D. Sharma et al., Fabrication of non-polar GaN based highly responsive and fast UV photodetector. Appl. Phys. Lett. 110(10), 103507 (2017). https://doi.org/10.1063/1.4978427
P. Wang, S. Liu, W. Luo, H. Fang, F. Gong et al., Arrayed van der Waals broadband detectors for dual-band detection. Adv. Mater. 29(16), 1521–4095 (2017). https://doi.org/10.1002/adma.201604439
D.S. Um, Y. Lee, S. Lim, J. Park, W.C. Yen et al., InGaAs nanomembrane/si van der waals heterojunction photodiodes with broadband and high photoresponsivity. ACS Appl. Mater. Interfaces 8(39), 26105–26111 (2016). https://doi.org/10.1021/acsami.6b06580
W. Zheng, R. Lin, Y. Zhu, Z. Zhang, X. Ji et al., Vacuum ultraviolet photodetection in two-dimensional oxides. ACS Appl. Mater. Interfaces 10(24), 20696–20702 (2018). https://doi.org/10.1021/acsami.8b04866
L.H. Zeng, M.Z. Wang, H. Hu, B. Nie, Y.Q. Yu et al., Monolayer graphene/germanium Schottky junction as high-performance self-driven infrared light photodetector. ACS Appl. Mater. Interfaces 5(19), 9362–9366 (2013). https://doi.org/10.1021/am4026505
X. Li, M. Zhu, M. Du, Z. Lv, L. Zhang et al., High detectivity graphene-silicon heterojunction photodetector. Small 12(5), 595–601 (2016). https://doi.org/10.1002/smll.201502336
K. Zhang, X. Fang, Y. Wang, Y. Wan, Q. Song et al., Ultrasensitive near-infrared photodetectors based on a graphene-MoTe2-graphene vertical van der Waals heterostructure. ACS Appl. Mater. Interfaces 9(6), 5392–5398 (2017). https://doi.org/10.1021/acsami.6b14483
Y.-S. Lan, X.-R. Chen, C.-E. Hu, Y. Cheng, Q.-F. Chen, Penta-PdX2 (X = S, Se, Te) monolayers: promising anisotropic thermoelectric materials. J. Mater. Chem. A 7(18), 11134–11142 (2019). https://doi.org/10.1039/c9ta02138h
Acknowledgements
H.L. acknowledges the National Key Research and Development Program of China (2017YFB0405400) from the Ministry of Science and Technology (MOST) of China, and the Natural Science Foundation for Distinguished Young Scientist of Shandong Province (Grant No. JQ201814). We thank the Project of “20 items of University” of Jinan (2018GXRC031). W.Z thanks Taishan Scholars Project Special Funds (tsqn201812083) and NSFC (No. 52022037). The authors show their gratitude to the National Natural Science Foundation of China (NSFC grant No. 51802113, 51802116) and the Natural Science Foundation of Shandong Province, China (grant No. ZR2019BEM040, ZR2018BEM015). M.H.R. thanks the National Science Foundation China (NSFC, Project 52071225), the National Science Center and the Czech Republic under the ERDF program “Institute of Environmental Technology—Excellent Research” (No. CZ.02.1.01/0.0/0.0/16_019/0000853) and the Sino-German Research Institute for support (Project No. GZ 1400).
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Wang, Y., Pang, J., Cheng, Q. et al. Applications of 2D-Layered Palladium Diselenide and Its van der Waals Heterostructures in Electronics and Optoelectronics. Nano-Micro Lett. 13, 143 (2021). https://doi.org/10.1007/s40820-021-00660-0
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DOI: https://doi.org/10.1007/s40820-021-00660-0