Abstract
Resistive random-access memory (ReRAM) devices based on halide perovskites have recently emerged as a new class of data storage devices, where the switching materials used in these devices have attracted extensive attention in recent years. Thus far, three-dimensional (3D) halide perovskites have been the most investigated materials for resistive switching memory devices. However, 3D-based memory devices display ON/OFF ratios comparable to those of oxide or chalcogenide ReRAM devices. In addition, perovskite materials are susceptible to exposure to air. Herein, we compare the resistive switching characteristics of ReRAM devices based on a quasi-two-dimensional (2D) halide perovskite, (PEA)2Cs3Pb4I13, to those based on 3D CsPbI3. Astonishingly, the ON/OFF ratio of the (PEA)2Cs3Pb4I13-based memory devices (109) is three orders of magnitude higher than that of the CsPbI3 device, which is attributed to a decrease in the high-resistance state (HRS) current of the former. This device also retained a high ON/OFF current ratio for 2 weeks under ambient conditions, whereas the CsPbI3 device degraded rapidly and showed unreliable memory properties after 5 days. These results strongly suggest that quasi-2D halide perovskites have potential in resistive switching memory based on their desirable ON/OFF ratio and long-term stability.
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Introduction
Photovoltaic devices are recognized as prospective energy sources1,2,3,4,5,6,7,8. As light absorbers, halide perovskites have had a significant impact on solar cell research owing to their remarkable photovoltaic properties, such as their long charge diffusion length and low exciton binding energies9,10,11,12,13,14,15,16. In particular, the current–voltage (I–V) hysteresis of halide perovskites has broadened their applications to electronic devices beyond photovoltaics, such as field-effect transistors, resistive-switching memory, and artificial synapses17,18,19. The defects that cause sweep-dependent hysteresis migrate in the halide perovskite layer, causing a switch in the current direction upon the application of a weak electric field20.
In general, halide perovskites, which are three-dimensionally (3D) structured compounds with the chemical formula ABX3, consist of monovalent cations in the A-site, divalent cations in the B-site, and halide anions in the X-site21. 3D halide perovskites, such as MAPbI3 (MA = CH3NH3) or CsPbI3, have been mostly studied for ReRAM devices; these devices have ON/OFF ratios on the order of 106 with multilevel resistive switching and low operating voltages22,23.
ReRAM devices based on halide perovskites have recently received attention as a potential research topic; however, some issues need to be resolved. Compared with conventional ReRAM devices based on metal oxides24,25,26, 3D halide perovskite memory devices display low stability in humid and ambient atmospheres, leading to the degradation of the switching characteristics of the memory devices. More importantly, the ON/OFF ratio should be higher than 1010 to be commercialized, because the resistances of the bit and selector lines are considered in terms of the high-density layer of the memory array.
To address these issues, quasi-two-dimensional (2D) halide perovskites have been considered as a means of improving the ON/OFF ratio and preventing device degradation in air27,28. Quasi-2D halide perovskites have the general formula (RNH3)2An−1BnX3n+1 (n = 1, 2, 3, …), where RNH3 is a large organic cation such as a large aliphatic or aromatic alkylammonium cation29,30,31,32. Thus, as the n-values decrease, the dimensionality of halide perovskites changes from 3D to quasi-2D and 2D structures. Quasi-2D halide perovskites, which are formed by introducing large organic cations into 3D perovskites, have wider bandgaps33,34,35, which make the Schottky barrier at the interface top electrode much higher. This behavior in turn lowers the high-resistance state (HRS) current, which results in an increase in the ON/OFF ratio. Furthermore, the large organic cation between the quasi-2D perovskite layers prevents the device from breaking down because of the hydrophobicity of the alkyl amines36,37,38,39. Recently, ReRAM devices were reported with ON/OFF ratios ranging from 105 to 107, which are still too low to show commercial promise40,41.
In this study, (PEA)2Cs3Pb4I13 (PEA = phenethylammonium) and CsPbI3 are employed as the resistive switching elements in a ReRAM device to compare the dependence of the switching behavior on the 3D and quasi-2D halide perovskites. We successfully fabricate a (PEA)2Cs3Pb4I13 ReRAM device with the Ag/(PEA)2Cs3Pb4I13/Pt(platinum)/Ti/SiO2/Si structure, where the perovskite resistive switching layer is synthesized on a Pt-coated silicon substrate by solution processing at low temperature. The devices exhibit bipolar resistive switching behavior and ultralow operating voltages. Furthermore, the ON/OFF ratios (>109) of the (PEA)2Cs3Pb4I13 ReRAM devices are noticeably higher than those of the CsPbI3 device, with long-term stability under ambient conditions. This study provides an opportunity to investigate the effect of the dimensionality of halide perovskites on the resistive switching of devices for use in next-generation high-performance nonvolatile memory.
Results and discussion
Figure 1 presents a schematic illustration of the device structure and the resistive switching materials CsPbI3 and (PEA)2Cs3Pb4I13. Vertical stacks of the Ag top electrode/CsPbI3 or (PEA)2Cs3Pb4I13/Pt bottom electrode/Ti/SiO2/Si structures were fabricated. For the low-temperature all-solution process, CsPbI3 and (PEA)2Cs3Pb4I13 films were successfully synthesized by the spin-coating method and by the thermal evaporation method using a dot-patterned shadow mask. Ag top electrodes were formed on the switching layers.
Compared with CsPbI3, in a 3D halide perovskite, the two organic PEA cation layers that are stacked between the inorganic layers can increase the bandgap. Although the organic PEA cations do not influence the electronic states around the band edge, the steric hindrance and other structural effects caused by the organic PEA cations bring about structural changes in the halide perovskite frameworks, which indirectly influences the increase in the bandgap. Notably, the bandgap increase has a significant influence on the switching performance42.
Figure 2a, b present scanning electron microscopy (SEM) images of the CsPbI3 and (PEA)2Cs3Pb4I13 perovskite layers synthesized on Pt-coated silicon substrates. For both samples, the thickness was ~300−350 nm (Supplementary Fig. S1, Supporting Information), with good film quality and high film coverage. To achieve a smooth surface, the Pt-coated silicon substrates were subjected to ultraviolet ozone cleaning before coating with the perovskite films.
As shown in Fig. 2c, d, the surface of both perovskite layers was evaluated by atomic force microscopy (AFM) with a scan size of 5 μm × 5 μm. Ultralow roughness was obtained for the (PEA)2Cs3Pb4I13 film, with a root mean square roughness of 3.0 nm, which is much lower than that of the CsPbI3 film (15.0 nm). It is suspected that the addition of PEAI (Phenethylammonium iodide) to the precursor solution impedes the growth of the perovskite crystal due to the strong hydrogen bond between the hydrogen atom of PEAI and the halide atom in PbI. Thus, the PEAI addition to form (PEA)2Cs3Pb4I13, a quasi-2D halide perovskite, dramatically improved the film uniformity43,44.
X-ray diffraction (XRD) measurements were conducted to verify the accurate phase of the 3D perovskite (CsPbI3 black phase) and quasi-2D perovskite ((PEA)2Cs3Pb4I13). As shown in Fig. 2e, the XRD pattern of the CsPbI3 sample shows sharp peaks at (100) and (200), indicating that the obtained perovskite film is highly oriented. A shoulder appeared next to the (110) peak, providing evidence of strain in the crystal, which allows the crystallization of CsPbI3 in the cubic phase45. Nevertheless, peaks of the yellow phase were also observed due to the metastable nature of cubic CsPbI3. Upon incorporating PEAI into CsPbI3 to obtain the quasi-2D perovskite, a low-angle diffraction peak appeared, which can be attributed to the typical reflections from the layered structure46. No XRD peaks related to yellow-phase CsPbI3 were observed for the quasi-2D perovskite sample. This result indicates that the addition of PEAI to CsPbI3 not only improves the morphology but also considerably boosts the stability of the perovskite film by inhibiting the transformation from the black to yellow phase of CsPbI3.
To compare the switching characteristics of the CsPbI3- and (PEA)2Cs3Pb4I13-based memory devices, the I–V characteristics of both devices were measured under a direct current–voltage sweep. Figure 3 displays the typical current–voltage curves of the Ag/CsPbI3/Pt (a) and Ag/(PEA)2Cs3Pb4I13/Pt (b) devices, where the voltage was applied to the top Ag electrode and the Pt bottom electrode was grounded. Both devices displayed bipolar resistive switching, which indicates that ON/OFF switching occurred at opposite polarities.
Given that the ON/OFF resistive switching operation is explained by the SET and RESET processes for these halide perovskite memory devices, the SET process, which refers to the switching from a HRS (OFF state) to a low-resistance state (LRS; ON state) at a certain positive voltage, showed an abrupt increase. In these memory devices, the abrupt increase in the current during the SET process and the sustained LRS support the formation of conducting filaments with a compliance current (CC) of 10−3 A. Then, the LRS changed to an HRS when a negative voltage was applied to these devices, which indicates the rupture of the conducting filaments with a CC of 10−2 A. Notably, the ON/OFF ratio for the (PEA)2Cs3Pb4I13-based devices was as high as ~109, whereas that of the CsPbI3-based devices was much lower (by ~106). The high ON/OFF ratio of the (PEA)2Cs3Pb4I13-based devices can be explained by the Schottky barrier height.
By changing the dimensionality from 3D for CsPbI3 to quasi-2D for (PEA)2Cs3Pb4I13, the bandgap is widened33,34,35. As the bandgap increases, the Schottky barrier height, which corresponds to the electron flow from the top electrode to the bottom electrode, increases at the interface between the halide perovskite switching layer and Ag top electrode. This means that the increased barrier height caused a reduction of the injected carrier density from the electrode to the perovskite switching layer. As a result, the HRS current decreased, leading to a high ON/OFF ratio.
The electrical thermal activation energy (Ea) may be another factor influencing the HRS current reduction. Figure 3c, d present plots of the HRS current vs. the inverse temperature at 0.02 V. The Ea for carrier migration in the switching layer in the HRS was deduced from the Arrhenius equation. From the linear fitting slope of each curve, the activation energy was estimated using the Arrhenius equation (presented as Eq. (1)):
where Ioff is the current in the HRS, I0 is a constant, Ea is the activation energy, k is the Boltzmann constant, and T is the absolute temperature47. The distribution of the Ea for the CsPbI3 and (PEA)2Cs3Pb4I13 memory devices extracted from this Arrhenius plot was 0.18 and 0.44 eV, respectively.
When the conducting filament is broken in the HRS, a small current flows through the trap states by hopping thermally excited electrons48,49. The trap state, which is a donor level in the conduction band, is associated with the Ea. Compared with the 3D halide perovskite (CsPbI3), the quasi-2D halide perovskite ((PEA)2Cs3Pb4I13) has a larger bandgap and a higher conduction band minimum, leading to deeper trap states. The deep trap states cause the Ea to increase. Thus, the HRS current is decreased.
Therefore, the fact that the Schottky barrier height and the activation energy of quasi-2D (PEA)2Cs3Pb4I13 are higher than those of 3D perovskites may account for the high ON/OFF ratio of the (PEA)2Cs3Pb4I13-based memory device, originating from the low HRS current.
To compare the superior resistive switching properties of the (PEA)2Cs3Pb4I13-based memory device with representative research studies on halide perovskite-based ReRAMs, the values of the ON/OFF ratios with SET voltages are exhibited, as shown in Supplementary Table S1. In addition, the ON/OFF ratios vs. the SET voltages are plotted in Fig. 3e.
Figure 4 shows the detailed resistive switching performance of the (PEA)2Cs3Pb4I13-based memory device. As shown in Fig. 4a, a series of five sweeps was performed in DC sweep mode at 0 V → +0.8 V → 0 V → −0.8 V → 0 V with a semiconductor parameter analyzer to confirm the hysteresis in the I–V profile of the device. In the initial DC sweep, an electroforming process referred to as a kind of “soft breakdown” was needed to achieve stable resistive switching properties50, which is analogous to that of general resistive switching memory devices based on electrochemical metallization (ECM). In ECM, the active top electrode is dissolved by oxidation, after which the metal cations form a conducting filament passing through the switching layer51.
In the (PEA)2Cs3Pb4I13-based memory device, electroforming occurred abruptly at a voltage of +0.40 V; the operating voltage required for the SET process was +0.18 V, and that for the RESET process was −0.10 V. The SET process could proceed at a lower voltage than that of the electroforming process because of the already-formed filament, which makes it easier to pass the SET filament. Initially, the sustained low-current state of the device (10−12 A) abruptly changed to the high-current state of the device (10−3 A) when the applied voltage exceeded the SET voltage. Subsequently, the sustained high-current state abruptly changed to the low-current state when the applied bias at negative polarity exceeded the RESET voltage. From the series of five I–V sweeps, the reliable and reproducible resistive switching of the (PEA)2Cs3Pb4I13-based ReRAM devices was confirmed.
Figure 4b, c show the statistically analyzed forming, SET, and RESET voltage distributions of 50 different Ag/(PEA)2Cs3Pb4I13/Pt cells for evaluating the uniformity of the operational function of the (PEA)2Cs3Pb4I13 memory devices. From these distributions, there was no significant deviation in the forming voltages of the different 50 cells, nor did the SET and RESET voltages show any meaningful deviation.
Figure 4d shows the HRS and LRS values of 50 different Ag/(PEA)2Cs3Pb4I13/Pt cells under applied write/erase voltage pulses. The result confirms that the average ON/OFF ratio did not differ significantly for the devices, which means that the reproducibility of the cells in resistive switching memory devices is superior.
The switching endurance, which confirms the stability and the number of switching cycles, is also one of the key factors influencing the reliability of resistive switching memory devices. Figure 4e shows the endurance characteristics of the (PEA)2Cs3Pb4I13 memory device, measured by applying alternating current (AC) voltage pulses. Continuous write/erase voltage pulses of +0.8 V for the SET process and −0.8 V for the RESET process were applied to the memory devices, with a 640 μs pulse duration and a read voltage of +0.05 V. The Ag/(PEA)2Cs3Pb4I13/Pt device was functional for 230 endurance cycles, with ON/OFF ratios above 108.
The typical data retention for the ON and OFF states was also evaluated for the Ag/(PEA)2Cs3Pb4I13/Pt cell to test the electrical reliability of the memory device, as shown in Fig. 4f. A constant ON/OFF ratio of ~109 was maintained for over 2 × 103 s at a reading voltage of +0.02 V. In the HRS region, a very small current fluctuation was observed, but the HRS and LRS remained constant overall.
To elucidate the current transport mechanisms of the resistive switching behavior, the typical I−V curves of the devices were plotted using a double-logarithmic scale for each resistance state, as shown in Fig. 5a. The electrical conduction of the Ag/(PEA)2Cs3Pb4I13/Pt memory device differed in the HRS and LRS during the SET operation under a voltage sweep of 0 V → +0.8 V → 0 V. First, it was found that the ohmic conduction plot had a slope of 0.99, with a linear relation of ln I vs. ln V in the LRS region after the abrupt current increase23,52,53,54. In the HRS region, the relation of ln I vs. ln V was nonlinear with a slope of 0.26, which verifies that Schottky emission is dominant23,53,55.
To better understand the two types of electrical conduction mechanisms, i.e., ohmic conduction in the LRS and Schottky emission in the HRS, the I–V curves of each resistance state were replotted with linear fitting lines. From Fig. 5b, it is clear that the linear fitting conforms to the ohmic conduction in the LRS, as proven by the proportional relation of the current density to the voltage (I ∝ V)53. This finding indicates that ohmic conduction governed the LRS after the abrupt formation of the conducting filament by passing through the halide perovskite switching layer.
To further clarify whether Schottky emission is dominant in the HRS region during the SET operation, the nonlinear I–V curve of the HRS was replotted as ln I vs. the square root of the applied voltage (ln I ∝ V1/2), as illustrated in Fig. 5c52,55,56. The fitting result shows a linear relationship of ln I ∝ V1/2, which can be taken as evidence that Schottky emission is dominant in the HRS region, according to the following equation:23
where I is the current, q is the electric charge, ε is the dielectric constant, d is the dielectric film thickness, and V is the applied voltage. The linearity of the replotted graph indicates that the metal cations are dissolved from the Ag top electrode by thermionic Schottky emission. In other words, in the HRS, Schottky contact is formed between the Ag top electrode and the halide perovskite layer, and the ejected carriers from the top electrode can easily pass through the potential barrier. Furthermore, the results suggest that the limited current flow from the top electrode to the switching layer controls the HRS current level.
It is known that the current in the HRS is related to the Schottky barrier height; thus, we compared the linear replotted I–V curves for the HRS of the 3D CsPbI3 and quasi-2D (PEA)2Cs3Pb4I13 memory devices. As shown in Fig. 6a, the quasi-2D (PEA)2Cs3Pb4I13 memory device displayed a lower current in the HRS, where the current density could be estimated according to the Richardson–Schottky law:
where A is the Richardson constant, E is the electric field, and ΦB is the Schottky barrier height57,58.
As expressed in Eq. (3), the Schottky barrier height, ΦB, corresponds to the current density in the HRS. The increased barrier height of quasi-2D (PEA)2Cs3Pb4I13 limits the carrier flow from the Ag top electrode to the perovskite switching layer. Figure 6b shows a schematic representation of the Schottky barrier heights of these two perovskite materials, suggesting that the band bending induced by modifying the bandgap of the switching material controls the barrier height. Therefore, we can increase the HRS current to improve the ON/OFF ratio of the memory devices.
In the ECM mechanism, the formation and rupture of the metal cation filament are caused by electrochemical reactions as well as thermal effects; therefore, the temperature dependence of the memory devices should be investigated. To confirm the impact of temperature on the electrical characteristics of the device, I−V measurements were conducted over the temperature range of 293−393 K. Figure 7a shows that the HRS current increased with increasing temperature. The increasing tendency of the current can be attributed to the easy migration of the ejected metal cations into the switching layer after the dissolution of the metal electrode23,59.
Figure 7b–d display the decreasing and increasing trends for the forming, SET, and RESET voltages under a DC voltage sweep when the temperature was elevated. In the forming and SET processes, the operating voltage is related to the rate of migration of the metal cations and the supersaturation of the metal. As the temperature increases, Ag metal cations easily move through a switching layer and then quickly reach supersaturation at the counter-electrode, even at a low voltage, thereby reducing the forming and SET voltages59,60. In the RESET processes, the rupture of the conducting filament at the counter-electrode occurs due to Joule heating-assisted dissolution59,60,61. The narrow conducting filaments, which are thermally unstable, are easily broken at high temperature. For this reason, the rupture of the Ag filament can easily take place at the counter-electrode as the temperature increases, even under a low-intensity electric field.
One of the issues for halide perovskite-based ReRAM devices is stability. It has been reported that the CsPbI3 3D halide perovskite is susceptible to humidity, resulting in rapid degradation when related devices are exposed to ambient conditions. Recently, to enhance the moisture resistance, some techniques have been introduced to maintain the stability, such as encapsulation or applying passivating polymer films to the devices. In our work, we found that the (PEA)2Cs3Pb4I13 quasi-2D halide perovskite was more robust at room temperature under ambient conditions than the CsPbI3 3D halide perovskites.
To confirm the superior stability of (PEA)2Cs3Pb4I13, the memory devices were kept under ambient atmosphere and the I–V characteristics were monitored. As illustrated in Fig. 8a, the 3D perovskite memory device degraded after 5 days. However, from the I–V measurements for the quasi-2D perovskite memory devices in Fig. 8b, it is clear that the stability was enhanced without appreciable decay after storage in air for 2 weeks. The stable resistive switching behavior of this (PEA)2Cs3Pb4I13 memory device is influenced by multiple interaction forces in the quasi-2D structure, such as strong ionic bonds in the perovskite (inorganic) layer, weak van der Waals forces between the PEA layers (mono-ammonium cation layers), and connections between the organic and inorganic layers (the coordination bonds between the ammonium group and Pb, and the hydrogen bond between the ammonium group and halogen)62,63. Furthermore, the hydrophobic PEA cation brings about steric hindrance, which affects the surface Pb–I to prevent the adsorption of water64. In addition, the stacks of hydrophobic cation layers protect the inner perovskites from water molecules, thus minimizing the water intake by the memory devices.
Thus, we confirmed that the PEA cations prevent the destruction of the quasi-2D structure and provide moisture resistance, which counters the degradation of the switching performance of the (PEA)2Cs3Pb4I13 memory device.
Conclusion
In summary, a large ionic radius cation (PEA) was introduced into CsPbI3 to form a quasi-2D halide perovskite, (PEA)2Cs3Pb4I13, to achieve a high ON/OFF ratio in ReRAM devices. A uniform surface morphology was achieved by incorporating the PEA cation and PEA)2Cs3Pb4I13 effectively improved the resistive switching of the device. The ReRAM device with the Ag/(PEA)2Cs3Pb4I13/Pt structure showed a high ON/OFF ratio of 109, which is three orders higher than that of the CsPbI3-based memory device. Owing to the wide bandgap of (PEA)2Cs3Pb4I13, a high Schottky barrier was formed and the activation energy increased, thereby leading to a reduction in the HRS current. A stability test verified the superior resistance of the device under ambient atmosphere at room temperature, which is another favorable property of quasi-2D perovskites. Although the CsPbI3 memory device was degraded after 5 days, the (PEA)2Cs3Pb4I13 devices were stable for 2 weeks, which is meaningful in terms of the practical application of halide perovskite memory devices.
Experimental section
Materials
Lead(II) iodide (99.9985%) and hydroiodic acid (57% in aqueous solution, stabilized with 1.5% hydrophosphorous acid) were provided by Alfa Aesar (Thermo Fisher Scientific, USA). Phenylethylamine (>99%), cesium iodide (99.99%), poly(methyl methacrylate), chlorobenzene (anhydrous, 99.8%), and N,N-dimethylformamide (anhydrous, 99.8%) were purchased from Sigma-Aldrich (USA). All the materials were used without any further purification.
Synthesis of PEAI
Phenylethylamine (80 mmol) was dissolved in 10 mL of ethanol and placed in an ice bath. HI (20 mL) was then slowly added to the flask and was kept for 20 min under vigorous stirring. The white powder (PEAI) was collected using a rotary evaporator and washed thrice with diethyl ether. Finally, the product was dried under vacuum at 50 °C for 1 day before use (Table 1).
Fabrication of the memory devices
Different dimensional perovskite (PEA2Csn−1PbnI3n+1) precursors were prepared by mixing stoichiometric quantities of PEAI, CsI, and PbI2 in N,N-dimethylformamide (DMF, anhydrous, 99.8%) at a concentration of 40 wt%, followed by heating for 12 h. A small amount of HI was added to the solution to increase the solubility of PEAI. A uniform film was obtained by spin-coating the precursor on Pt/Ti/SiO2/Si substrates at a speed of 4000 r.p.m. and heating at 150 °C for 5 min. The PMMA (polymethylmethacrylate) solution (5 mg mL−1) was spin-coated to protect the perovskite film from moisture. After deposition of PMMA, the films were further heated at 100 °C for 5 min. To complete the devices, Ag electrodes (50 µm × 50 µm) were deposited by e-beam evaporation under 1 × 10−6 Torr at room temperature through a shadow mask.
Characterization
The surfaces and cross-sections of the perovskite films were imaged using a field-emission SEM (ZEISS MERLIN COMPACT). The morphology of the perovskite films was analyzed using AFM (Park System XE100). The XRD patterns were recorded using an X-ray diffractometer (Bruker Miller Co., D8-Advance) with Cu-Kα radiation. The electrical properties of the memory units were characterized by using an Agilent 4156C semiconductor analyzer in the direct current–voltage sweeping mode and alternating voltage pulse mode in a vacuum chamber (6 × 10−2 Torr).
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Acknowledgements
This work was financially supported by the Future Material Discovery (2016M3D1A1027666) Program, the Basic Research Laboratory (2018R1A4A1022647), and the National Research Foundation of Korea (NRF) grant funded by the Korean government MSIT (2019M3E6A1103818).
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Kim, H., Choi, MJ., Suh, J.M. et al. Quasi-2D halide perovskites for resistive switching devices with ON/OFF ratios above 109. NPG Asia Mater 12, 21 (2020). https://doi.org/10.1038/s41427-020-0202-2
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DOI: https://doi.org/10.1038/s41427-020-0202-2
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