Abstract
With the continuous scaling of resistive random access memory (RRAM) devices, in-depth understanding of the physical mechanism and the material issues, particularly by directly studying integrated cells, become more and more important to further improve the device performances. In this work, HfO2-based integrated 1-transistor-1-resistor (1T1R) RRAM devices were processed in a standard 0.25 μm complementary-metal-oxide-semiconductor (CMOS) process line, using a batch atomic layer deposition (ALD) tool, which is particularly designed for mass production. We demonstrate a systematic study on TiN/Ti/HfO2/TiN/Si RRAM devices to correlate key material factors (nano-crystallites and carbon impurities) with the filament type resistive switching (RS) behaviours. The augmentation of the nano-crystallites density in the film increases the forming voltage of devices and its variation. Carbon residues in HfO2 films turn out to be an even more significant factor strongly impacting the RS behaviour. A relatively higher deposition temperature of 300 °C dramatically reduces the residual carbon concentration, thus leading to enhanced RS performances of devices, including lower power consumption, better endurance and higher reliability. Such thorough understanding on physical mechanism of RS and the correlation between material and device performances will facilitate the realization of high density and reliable embedded RRAM devices with low power consumption.
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Introduction
Future embedded non-volatile memories require higher density, lower power consumption, higher speed and better scalability1. Resistive random access memories (RRAM) with 1 transistor-1 resistor (1T1R) architecture emerge recently as one of the most promising candidates to fulfil these requirements2,3. Moreover, the RRAM technology is also of great interest for different system-on-chip (SoC) applications such as wireless sensor networks (WSNs) and medical health care devices, considering that RRAM allows to largely reduce the “standby” power dissipation in the sensor node4,5. In 1T1R RRAM devices, the transistor is used to limit the pulse current in order to avoid the hard breakdown (HBD) in the resistor, which consists of a metal-insulator-metal (MIM) structure for resistive switching (RS). Among various candidates for the active insulator layer in MIM structure6, hafnia (HfO2) widely attracts attention because of its compatibility with the current semiconductor fabrication process. Since 2007, it has been selected as the “standard” gate dielectric material in modern complementary-metal-oxide-semiconductor (CMOS) transistors7. Many efforts have been made to realize fab friendly HfO2 RRAM using atomic layer deposition (ALD), which distinguishes itself from other counterparts thanks to its extraordinary good step coverage, the precise control of atomically specified film thickness and the high film quality8. Particularly, the batch ALD technique with reduced cost per wafer has been developed for future mass production of related devices9. Despite of a bunch of detailed studies focusing on unveiling the RS mechanism (normally on μm-size devices10,11) and on attempting to improve the cell-performances (with different methods like doping12,13,14,15, filament confinement16,17 and bilayers18,19,20,21 etc.), a fundamental but indispensable study correlating the material properties (e.g. the crystallinity and the carbon impurity, etc.) and device performances, particularly for integrated RRAM devices in nm scale, is still missing.
In this work, nm-size 1T1R integrated RRAM devices were fabricated in a standard 0.25 μm CMOS process line. The TiN/Ti/HfO2/TiN MIM structures, acting as the resistor, were fabricated by depositing HfO2 at two different temperatures (150 °C and 300 °C) by employing the batch ALD approach (with 100 process-wafer loading capability) with a metal organic precursor (which is more suitable for the batch ALD process thanks to its liquid form22). Both electrical and material properties of devices were systematically studied and correlated. The nm-size HfO2-based devices show typical filament-type RS. The higher deposition temperature of 300 °C does not induce significant recrystallization but dramatically reduces the residual carbon concentration in HfO2 films. Increased density of nano-crystallites in HfO2 slightly affects the forming voltage and its variability of corresponding devices. Carbon impurities inducing trap levels inside the band gap23 are believed to interact with oxygen vacancies (VO) in the filament area and thus significantly influence RS properties of the devices. The reduced C concentration in the 300 °C devices leads to enhanced RS performances such as lower Vset/reset, lower power consumption, better endurance and higher reliability etc. The theoretical simulation using the Quantum Point Contact (QPC) model confirms that the 300 °C samples have much more stable confinement of leakage current paths (i.e. filaments).
Results and Discussion
Resistive switching properties
Back-end-of-line (BEOL) HfO2-based integrated 1T1R RRAM cells were prepared in a standard 0.25 μm CMOS process line. Figure 1 illustrates the final structure of the device. 1T1R devices with five different MIM areas, i.e. 600 × 600 nm2, 700 × 700 nm2, 800 × 800 nm2, 900 × 900 nm2 and 1000 × 1000 nm2, were processed. The electrical characteristics of 1T1R integrated RRAM devices (using the MIM area of 1000 × 1000 nm2) with HfO2 films grown at 150 °C and 300 °C have been examined by current-voltage (I-V) measurements. After the electroforming process step, all devices demonstrate resistive switching (RS) behaviours as illustrated in Fig. 2. Figure 2(a) demonstrates the forming process of the 150 °C (blue curve) and the 300 °C (red curve) devices with a common compliance current (ICC) of 10 μA (corresponding to a gate voltage of 0.9 V). The forming process was performed by applying a dc sweep on the bit line (BL), i.e., drain line of the select MOS device, up to Vd = 4.5 V with a step of 0.05 V (i.e. top injection). To prevent HBD, the current during formation is limited by setting the gate voltage of the select transistor to 0.9 V (word line/WL voltage). It can be observed that during the forward sweep from 0 V to 4.5 V, the current of the pristine 150 °C device is always lower than that of the 300 °C device, indicating a greater initial resistance state (IRS) of the 150 °C sample. Moreover, the 150 °C device demonstrates sharper forming behaviour at 3 V. The variation of the forming voltage (VF) as a function of HfO2 growth temperature was explored by a statistic study on 20 devices and the result is shown in Fig. 2(b). It can be observed that the VF slightly increases with higher growth temperature (from ~3.2 V to ~4.0 V), which nevertheless results in a much more pronounced VF device-to-device variation (ΔVF varies from ~0.3 V to ~1.8 V).
Figure 2(c) shows the typical set characteristics of the devices. The set operation (see the inset for the equivalent circuit) switches the RRAM cell from a high-resistive state (HRS or OFF state) to a low-resistive state (LRS or ON state) by sweeping Vd up to 2.5 V whereas applying 0 V to the source line voltage (Vs) with Vg = 3 V. Figure 2(d) demonstrates the set voltage (Vset) variation versus HfO2 growth temperature. Figure 2(e) shows the typical reset characteristics of devices. The reset operation (see inset for the equivalent circuit) switches the cell from ON state to the OFF state by sweeping Vs up to 2 V, whereas Vd = 0 and Vg = 3 V. Figure 2(f) demonstrates the reset voltage (Vreset) variation versus HfO2 growth temperature. Obviously, one can observe from Fig. 2(c–f) that compared to the 150 °C devices, the 300 °C devices show enhanced RS properties because they possess 1) greater ON/OFF ratios and 2) lower set and reset voltages, reducing the power consumption.
It is well-known that during the electroforming process of oxide-based RRAM devices, the oxide layer undergoes certain nano-morphological modifications associated with the formation of oxygen vacancies (VO)24,25,26. Furthermore, the mechanism of VO (or O atoms) movement usually plays a dominant role in determining the RS properties of RRAM devices10,27. Therefore the observed difference of the 150 °C and the 300 °C devices in their forming and RS behaviour must be closely connected to the RS mechanism and their materials properties, which will be discussed in detail in the following sections.
To explore the endurance of the HfO2 based 1T1R integrated RRAM devices, dc cycling studies were performed, as shown in Fig. 3. Figure 3(a) shows the resistance (taken from the reset process at V = 0.2 V) evolution with dc cycles for the 150 °C (top panel) and the 300 °C (bottom panel) devices. The straight lines are the corresponding linear fitting results. The 300 °C device shows an ON/OFF ratio of about 10, which is larger than that of the 150 °C device. This confirms the observation by RS loops, as already shown in Fig. 2. Moreover, it is evident that the ON/OFF ratio of the 150 °C device gradually decreases with cycles and the RS “window” continuously becomes smaller. In the contrary, the 300 °C device shows stable endurance behaviour with a constant ON/OFF ratio up to 300 cycles. Interestingly, for both devices the HRS states (empty stars and circles) show higher variations compared to the LRS states (full stars and circles). More details are illustrated in Fig. 3(b), plotting the probability of resistance states. It is confirmed that the LRS with higher slopes (solid symbols) is more stable than the HRS (empty symbols). In particular the LRS of the 300 °C device remains almost unchanged, demonstrating an excellent reliability. Regarding the variation of the HRS, it is related to the RS physical mechanism.
In order to clarify the RS mechanism of such nm-size HfO2 based 1T1R integrated RRAM devices, device area dependent I-V measurements have been carried out on the 300 °C devices and the results are shown in Fig. 4. According to detailed reviews by Waser and Sawa et al.1,26,28, two main categories of physical models of RS can be classified, i.e. interface type, which is related to the modification of the metal/oxide interface barrier height (thus RS is cell area dependent)28 and filament type, the RS of which is dominated by the formation and rupture of local conductive paths inside the oxide bulk (thus RS is cell area independent)29. On one hand, it is widely accepted that HfO2 based RRAM devices demonstrate VO-related filament type mechanism and many studies show experimental observation of the conductive filaments (CFs)30,31. It is noted here that the CFs in HfO2 based devices could also consist of cations32 (but specified electrodes are required, in general Cu2+) rather than VO. Such so-called conductive bridge RAM (CBRAM) is out of the scope of the current work. On the other hand, even for the filament type devices, it is found that the interface details are of great significance33,34 and different electrodes cause different RS behaviour24,35. Particularly, TiN or Ti electrodes normally serve as oxygen reservoirs, which strongly influence the VO formation in HfO2 and thus the device performance. Our prior studies clarified that the Ti inserting layer is indispensable to achieve good RS behaviour of HfO2 based 1T1R integrated RRAM devices and its thickness plays an important role in realizing high RS performance (here an optimized thickness of 7 nm was used)36. Furthermore, in-operando hard X-ray photoemission spectroscopy (HAXPES) revealed that an oxygen atom exchange occurs between Ti and HfO2 layer during RS processes, which corresponds also to the interface barrier modification37,38. Therefore, it is necessary to clarify the RS mechanism in nm-sized TiN/Ti/HfO2/TiN 1T1R integrated devices, particularly considering that devices areas are comparable with the reported CFs size ranging from a few tens of nanometers to several hundreds of nanometers27,30,31.
Figure 4(a) shows the VF dependence on the device area. It reveals a decrease of VF value scattering and a slight VF reduction when the device area decreases from 1 to 0.36 μm2. These behaviours can be attributed to the Ti layer oxidation during the forming process, which helps the formation of VO-related filaments in HfO2 layer. Many authors pointed out that Ti serves as an excellent oxygen reservoir because the formation of TiOx is easier than HfOx39,40. Ti is oxidized by taking the oxygen atoms from HfO2 once the external electric field provides enough energy higher than the reaction activation energy. In cells with smaller Ti/HfO2 interface area, less material inhomogeneity (thus smaller VF value scattering) appears and less energy (thus smaller forming voltage) is required to reach the activation energy of Ti oxidation. Moreover, the decrease of VF variation with the reducing device area indicates probably a local area feature of the forming process. This is immediately confirmed by HRS/LRS dependence of device area, as shown in Fig. 4(b). Evidently, the LRS is almost unaffected by the variation of the cell area. The HRS does not show either a clear modification despite of relatively higher error bars. Figure 4(c) further shows that Vset and Vreset do not vary with the device area. These results evidently confirm that the filament mechanism dominants the RS behaviour of nm-sized HfO2 RRAM devices.
After understanding the filament type of our devices, a physics-based analytical quantum point contact (QPC) model was employed to examine the experimental I-V curves in order to unveil more details of the device endurance. Briefly, QPC model assumes that the current flows through a filamentary path between two electron reservoirs in both HRS and LRS states. Then, based on Landauer theory, one can obtain an expression of the conducting current represented by the quantum transmission probability, which is determined by the height and the width of a potential barrier with a parabolic shape. In the HRS, the barrier top is well above the energy window of the injected electrons while in the LRS, the barrier does not impact at all41. QPC model has been successfully applied to fit I-V curves of several RS systems including atomic vapour deposited HfO2 1T1R RRAM devices, which highlights again the filament type of such devices2,32,42. Here we focus on the endurance studies. In QPC model, the low resistance current ILRS reads:
where G0 = 2e2/h = (12.9 kΩ)−1 is the quantum conductance unit; R is the resistance to be fitted for the I-V curve of each cycle and V is the applied voltage. We define G = 1/(1 + G0R) which includes the fitted parameter R varied for each RS. Thus the normalized conductance G/G0 could indicate the stability of the confinement path (i.e. the filament) in the MIM structure.
Figure 5(a,b) show the distributions of the normalized conductance G/G0 for the 150 °C and the 300 °C devices, respectively. They were obtained from the QPC fittings for LRS currents extracted from the similar measurements shown in Fig. 3. It can be seen in Fig. 5(a) that the G/G0 of the 150 °C device averagely distributes in a large range from 0.5 to 1.6 despite of a relatively larger intensity at the interval of [1.0, 1.4]. This reveals that the 150 °C device tends to form instable confinement paths (filaments) with large fluctuations, which could be caused by oxygen vacancy transport and inelastic electron trapping and de-trapping processes. These fluctuations decrease the “window” between the LRS and HRS after tens of cycling processes (see Fig. 3(a)). In the contrary, the G/G0 distribution of the 300 °C device in Fig. 5(b) represents a very sharp feature with almost all counts locating at the value of 1.0, namely, it is related to a stable confinement path (filament) formed at G0. This higher stability of the conductive path of the 300 °C device clearly clarifies the reason for its better endurance compared to that of the 150 °C device (see Fig. 3(a)).
Material properties and discussion
In order to understand the underlying physical mechanism of the different RS properties in devices induced by the HfO2 growth temperatures, 10 nm thick HfO2 films were grown by ALD on planar TiN/Si substrates under precisely same conditions as for the 1T1R integrated devices and their properties were explored in detail.
One of the most important film properties which probably influence the RS properties of the device consists in the film crystallinity. Therefore both X-ray diffraction (XRD) and high-resolution transmission electron microscopy (HRTEM) methods were employed to investigate this issue. Figure 6(a) shows grazing incidence XRD (GIXRD) measurements performed at 1° angle of incidence around the TiN (200) Bragg reflection. It is known that the large scale recrystallization of HfO2 films occurs above ~370 °C53,44, below which HfO2 remains amorphous. Specular out-of-plane XRD measurements (not shown) do not show any HfO2 related diffraction peak. Here GIXRD was utilized, which provides a much higher sensitivity for detecting the possible presence of randomly distributed nm-scale crystallites in the 10 nm-thick amorphous HfO2 films. For both films the XRD patterns are dominated by two sharp TiN peaks, i.e. (111) at 2Θ = 36.9° and (200) at 2Θ = 42.6°, which are related to the polycrystalline cubic TiN structure of the substrate. No well-defined HfO2 related diffraction peak is observed for both samples, demonstrating that no large-scale recrystallization occurs in both samples. However, a wide swell region ranges from 2Θ~28.3° to 2Θ~34.2° appears in both patterns of the 150 °C and the 300 °C samples, indicating the presence of randomly distributed nm-scale crystallites. The dashed lines denote the reflection positions of (−111) at 2Θ = 28.3°, (111) at 2Θ = 31.6° and (002) at 2Θ = 34.2° of HfO2 monoclinic lattices. The swell regions well locate between (−111) and (002) positions. Moreover, the swell region of the 300 °C sample has a slightly higher intensity indicating an increase of nm-size crystallites. HRTEM measurements were therefore performed to possibly visualize the crystallites, as shown in Fig. 6(b,c) for the 150 °C and the 300 °C samples, respectively. For the 150 °C sample, no crystallite was found in the detected region. That is the reason why Fast Fourier Transformation (FFT) pattern (Fig. 6(b) inset) extracted from an arbitrary part of the HfO2 film shows only a diffused halo feature. While for the 300 °C sample, FFT patterns extracted from most parts of the film in Fig. 6(c) show the same pattern as the inset of Fig. 6(b), indicating that the overwhelming part of the 300 °C film remains amorphous. However, one can find a single crystallite with diameter of ~2 nm in the circled region and thus the FFT pattern (Fig. 6(c) inset) extracted from this part shows both diffused halo and dots (marked by arrows).
Let us now consider the impact of the film crystallinity on the RS properties shown in the last section. Firstly, it is known that polycrystalline grain boundaries (GBs) could serve as favourable conductive paths due to their oxygen deficient feature, which lead to higher conductivity of the HfO2 films45,46,47. Recently, conductive atomic force microscopy (CAFM) studies have provided solid proofs that, under nanoscale electrical stress, the leakage currents through GBs are higher than those through the grains in HfO2 films48. Meanwhile, the electrical breakdown voltages on GBs are much lower than those on grains (nanocrystals), leading to the formation of CFs at GBs that are responsible for the repeatable RS behaviour observed in Hf based oxide films49. Compared to the 150 °C sample, the 300 °C sample remains amorphous but shows an increasing crystallite density. This explains its smaller IRS before forming, as observed in Fig. 2(a). Moreover, more inhomogeneous feature in the 300 °C sample leads to a larger VF variation, as shown in Fig. 2(b). Thirdly, according to our prior theoretical and experimental studies on the Ti/HfO2 interface, Ti can scavenge more O from amorphous HfO2 films compared to polycrystalline ones50. Therefore, the increasing number of nm-size crystallites yields higher average VF.
These considerations demonstrate that the difference in forming process of both devices can be well attributed to the film crystallinity. However, such arguments meet difficulties when one tries to clarify the difference of the Vset/Vreset and the endurance behaviour of the devices fabricated at different temperatures, because there is no clear proof, demonstrating that the filaments formed in HfO2 films with slightly different crystallinity possess different behaviour. Meanwhile, solid evidences have been reported for the inevitable presence of residual impurities like carbon or chlorine (depending on the precursors) in ALD grown HfO2 films and their significant impact on the electrical properties of HfO2 such as carrier mobility and reliability in metal-oxide-semiconductor (MOS) devices51,52. Particularly, the HBD of MOS and/or MIM devices has been correlated with the high C concentration in the HfO2 layer51,52,53. In this study, carbon related TEMAH precursor has been utilized due to its liquid form being suitable for the batch ALD process, therefore, the residual carbon atomic concentration in both films grown at 150 °C and 300 °C were explored. Time-of-flight secondary ion mass spectrometry (Tof-SIMS) method was employed to determine the carbon content because it provides a very sensitive detection range up to 1018 atoms/cm3 (~10 ppm). Figure 7 displays the Tof-SIMS depth profile for carbon residues in ALD HfO2 films as a function of the film depth, in which the atomic concentration values were determined by the estimation from sputtering X-ray photoelectron spectroscopy (XPS) measurements (see Fig. S1 in Supporting Information). It can be seen that the HfO2 film grown at the lower temperature of 150 °C (blue curve) reveals an average residual carbon concentration of ~8.9% (marked by a blue dashed line) whereas the higher temperature of 300 °C (red curve) results in a lower one of ~5.9% (marked by a red dashed line) in the HfO2 film. The reduction of C residues at higher temperatures in ALD HfO2 films originate either from the almost complete decomposition of the Hf[N(CH3)(C2H5)]4 precursor or the more complete reaction between the precursor and oxidants during the deposition.
C defects can exist as substitutional and interstitial ones. Cho et al.51,52 clarified using density functional theory approach that, the interstitial defect is favoured under the oxygen-rich ambience whereas the substitutional form is more stable within the oxygen-deficient environment. More importantly, Choi et al.23 further pointed out that carbon atoms which induce trap levels inside the band gap can form a permanently conducting path once they percolate. This indicates that, similarly as VO which forms filaments contributing to a “soft” breakdown in RRAM devices, C residues can also form filaments which results in, however, “hard” breakdown. It is worth noting that during the forming process in RRAM devices, the initial formed filament should still be based on VO instead of C atoms due to the higher mobility of oxygen ions and the easier formation of VO thanks to the reservoir effect of the Ti metal36,39.
Following this scenario, it is probable that once the VO-based filament is formed in the HfO2 film, C residues that are initially homogeneously distributed in the film tend to shift into the VO sites in the filament due to its oxygen-deficient feature. Considering that the reset process in RRAM devices is based on the migration of O cations and its refilling into VO sites54, the C filling in VO sites (C can form complexes with VO55) and the formation of the more stable the Hf-C (with dissociation energy of 379 kcal/mole56 compared to a much smaller value of 184 kcal/mole of Hf-O bond57) will impede the reset process, i.e. it requires higher energy to dissociate the filament. This is precisely what we observed in Fig. 1(c–f). The 150 °C sample with higher C concentration requires higher Vset (~1.1 V) and Vreset (~1.5 V) to switch the device while Vset and Vreset of the 300 °C sample are only ~0.8 V and ~1.0 V respectively. In addition, more C atoms in VO-filament of the 150 °C device influence the leakage behaviour of its HRS state, i.e. they yield higher currents in HRS thus a smaller ON/OFF ratio (~7) compared to that of the 300 °C device (~10).
The inferior endurance of the 150 °C device (Fig. 3(a)) can also be ascribed to its higher C residual concentration. It is likely that the 150 °C device (~8.9% C residue), with the cycles (continuous electrical stress), more and more C atoms are “filled” into VO sites thus the filament transforms from a VO-dominant to a C-dominant feature with enhanced leakage current55 and finally a pure C filament forms leading to a hard breakdown. While for the 300 °C device (~5.9% C residue), the C concentration does not exceed the critical value for the formation of a “percolation path” therefore much better endurance and reliability (Figs 3 and 5) were realized. Our prior in-operando HAXPES study of the Ti/HfO2/TiN system also revealed a clear carbon segregation towards the Ti/HfO2 interface, which is a reservoir layer of VO, with RS cycles37,38,58, confirming the interaction between C and VO thus the formation of C-VO complexes with RS cycles.
Figure 8 illustrates this C residue related hard breakdown mechanism in the 150 °C device. In the pristine state, carbon impurities (black squares) are randomly distributed in the oxide film. It is noted here that due to a sintering process for 1T1R devices, consisting of a thermal annealing at 400 °C2,36, the Ti layer was already partly oxidized and VO appear in the HfO2 film which is thus denoted as HfO2−δ. After the forming process, Ti (as an oxygen reservoir) absorbs even more O ions from HfO2−δ film under the externally applied electric field and thus an oxygen deficient HfOx layer as well as a VO-filament (white circles) forms. At the same time, a few C atoms shift, due to their high concentration, to HfOx layer as well as VO sites in the filament. With cycles, more and more C-VO complexes form and a filament consisting of mainly C eventually forms which leads to the hard breakdown of the device.
Conclusion
In conclusion, nm-size HfO2-based 1T1R integrated RRAM devices were fabricated in a standard 0.25 μm CMOS process line by employing the batch ALD tool designed for mass production. We demonstrated material insights for the RS properties of devices and correlated the key material properties, including the crystallinity and the residual C concentration, with the device performances. Cell-area dependent studies were performed, indicating their filament-type RS feature even in nm-size, despite a strong impact of the interface on the forming process. A relatively higher deposition temperature of 300 °C results in a lower IRS and a slightly higher VF due to the increasing density of nm-size crystallites in the mainly amorphous bulk structure of the film. Moreover, the residual C impurity, which induces traps in the bandgap of HfO2 (similarly as VO) and could interact with VO23,51,52, imposes significant impact on the RS properties of the devices. Thanks to the reduction of the C impurity concentration, the 300 °C device displays lower power consumption with smaller Vset and Vreset, improved endurance and a better filament control thus higher reliability. The device performance-material property correlation improves the understanding of the underlying physics of the resistive switching in MIM structure and will certainly help to optimize the fabrication process of the 1T1R embedded RRAM cells thus enhancing their performances for the future high density SoC applications such as wireless sensor networks and medical health care devices.
Methods
Fabrication of HfO2 based 1T1R RRAM cells
A standard 0.25 μm CMOS process line was employed. Figure 1 illustrates the final structure of the device. Firstly, the NMOS transistors were processed with width (W) of 1.14 μm and length (L) of 0.24 μm. The resistive switching cell was then placed between the metallization levels 2 and 3. In order to reduce the surface roughness of the bottom electrode, a 20 nm-thick TiN layer was additionally deposited by atomic vapour deposition (AVD). 10 nm HfO2 films were grown at 150 °C and 300 °C in an ASM A412™ batch ALD system (with 100-wafer load capability, specially designed for mass production) using a metal organic TEMAH (tetrakis (ethylmethylamino)hafnium, Hf[N(CH3)(C2H5)]4) precursor22. Finally, HfO2 was capped by a 7 nm ionized metal plasma (IMP) Ti layer then a 150 nm PVD TiN59 layer.
Electrical characterization and analysis of the RRAM cells
The electrical properties of the memory cells were measured in a Cascade PA200 Semi-automatic Probe System, and the current-voltage (I-V) curves were collected by using a Keithley 4200 semiconductor parameter analyser. I-V characteristics were theoretically simulated by a physics-based analytical QPC model41,60.
Film crystallinity and thickness measurements
the crystalline properties of the HfO2 films were examined by X-ray diffraction (XRD) under grazing incidence conditions using a Rigaku Smartlab diffractometer with a 9 kW rotating anode (Cu Kα1, λ = 1.5406 Å) and microscopically by high resolution transmission electron microscopy (HRTEM) using a FEI Tecnai Osiris equipment operated at 200 kV. The film thicknesses were also determined by TEM measurements.
Residual carbon concentration measurements
The atomic concentration of residual carbon in the HfO2 films was characterized by both sputtering X-ray photoelectron spectroscopy (XPS) with Al Kα excitation energy (1486.6 eV) using a PHI Versa Probe II Scanning XPS Microprobe system and time-of-flight secondary ion mass spectrometry (Tof-SIMS) using an IONTOF TOF-SIMS 5 equipment with an Cs sputtering beam (500 eV) and a Bi1 analysis beam (25 keV).
Additional Information
How to cite this article: Niu, G. et al. Material insights of HfO2-based integrated 1-transistor-1-resistor resistive random access memory devices processed by batch atomic layer deposition. Sci. Rep. 6, 28155; doi: 10.1038/srep28155 (2016).
References
Waser, R. & Aono, M. Nanoionics-based Resistive Switching Memories. Nat. Mater. 6, 833–840 (2007).
Walczyk, C. et al. Impact of Temperature on the Resistive Switching Behavior of Embedded HfO2-Based RRAM Devices. IEEE Trans. Electron. Devices 58, 3124–3131 (2011).
Zangeneh, M. & Joshi, A. Design and Optimization of Nonvolatile Multibit 1T1R Resistive RAM. IEEE Trans. VLSI Syst. 22, 1815–1828 (2014).
Zhang, K. Embedded Memories for Nano-Scale VLSIs. (Springer-Verlag 2009).
Bez, R., Cappelletti, P., Casagrande, G. & Pirovano, A. In Memories in Wireless Systems (eds Rino Micheloni, Giovanni Campardo, & Piero Olivo ) (Springer-Verlag 2009).
Wong, H. S. P. et al. Metal-Oxide RRAM. Proc. IEEE 100, 1951–1970 (2012).
Mistry, K. et al. In Electron Devices Meeting (IEDM), IEEE International. 247–250 (2010).
Johnson, R. W., Hultqvist, A. & Bent, S. F. A Brief Review of Atomic Layer Deposition: from Fundamentals to Applications. Mater. Today 17, 236–246 (2014).
Granneman, E., Fischer, P., Pierreux, D., Terhorst, H. & Zagwijn, P. Batch ALD: Characteristics, Comparison with Single Wafer ALD, and Examples. Surf. Coat. Technol. 201, 8899–8907 (2007).
Kwon, D.-H. et al. Atomic Structure of Conducting Nanofilaments in TiO2 Resistive Switching Memory. Nat. Nano. 5, 148–153 (2010).
Calka, P. et al. Chemical and Structural Properties of Conducting Nanofilaments in TiN/HfO2-Based Resistive Switching Structures. Nanotechnology 24, 085706 (2013).
Gao, B. et al. Oxide-based RRAM: Uniformity Improvement Using A New Material-Oriented Methodology. VLSI Technology, 2009 Symposium on, 30–31 (2009).
Chen, Y. Y. et al. Tailoring Switching and Endurance / Retention Reliability Characteristics of HfO2 / Hf RRAM with Ti, Al, Si Dopants. VLSI Technology, 2009 Symposium on, 1–2 (2014).
Sharath, S. U. et al. Towards Forming-Free Resistive Switching in Oxygen Engineered HfO2−x . Appl. Phys. Lett. 104, 063502 (2014).
Zheng, L. et al. Controlled Direct Growth of Al2O3-Doped HfO2 Films on Graphene by H2O-Based Atomic Layer Deposition. Phys. Chem. Chem. Phys. 17, 3179–3185 (2015).
Niu, G. et al. Geometric Conductive Filament Confinement by Nanotips for Resistive Switching of HfO2-RRAM Devices with High Performance. Sci. Rep. 6, 25757 (2016).
Zhang, Z., Yi, W., Wong, H. S. P. & Wong, S. S. Nanometer-Scale HfOx RRAM. IEEE Electron Device Lett. 34, 1005–1007 (2013).
Fang, R.-C. et al. High-Performance Bilayer Flexible Resistive Random Access Memory Based on Low-Temperature Thermal Atomic Layer Deposition. Nanoscale Res. Lett. 8, 92 (2013).
Sharath, S. U. et al. Thickness Independent Reduced Forming Voltage in Oxygen Engineered HfO2 Based Resistive Switching Memories. Appl. Phys. Lett. 105, 073505 (2014).
Huang, C.-Y., Huang, C.-Y., Tsai, T.-L., Lin, C.-A. & Tseng, T.-Y. Switching Mechanism of Double Forming Process Phenomenon in ZrOx/HfOy Bilayer Resistive Switching Memory Structure with Large Endurance. Appl. Phys. Lett. 104, 062901 (2014).
Lee, M.-J. et al. A Fast, High-Endurance and Scalable Non-Volatile Memory Device Made from Asymmetric Ta2O5−x/TaO2−x Bilayer Structures. Nat. Mater. 10, 625–630 (2011).
Dingemans, G. et al. Merits of Batch ALD. ECS Trans. 64, 35–49 (2014).
Choi, M., Lyons, J. L., Janotti, A. & Van de Walle, C. G. Impact of Carbon and Nitrogen Impurities in High-κ Dielectrics on Metal-Oxide-Semiconductor Devices. Appl. Phys. Lett. 102, 142902 (2013).
Lorenzi, P., Rao, R. & Irrera, F. Forming Kinetics in HfO2-Based RRAM Cells. IEEE Trans. Electron. Devices 60, 438–443 (2013).
Prakash, A., Jana, D. & Maikap, S. TaOx-Based Resistive Switching Memories: Prospective and Challenges. Nanoscale Res. Lett. 8, 418 (2013).
Waser, R., Dittmann, R., Staikov, G. & Szot, K. Redox-Based Resistive Switching Memories – Nanoionic Mechanisms, Prospects, and Challenges. Adv. Mater. 21, 2632–2663 (2009).
Yang, Y. et al. Observation of Conducting Filament Growth in Nanoscale Resistive Memories. Nat. Commun. 3, 732 (2012).
Sawa, A. Resistive Switching in Transition Metal Oxides. Mater. Today 11, 28–36 (2008).
Nardi, F., Larentis, S., Balatti, S., Gilmer, D. C. & Ielmini, D. Resistive Switching by Voltage-Driven Ion Migration in Bipolar RRAM–Part I: Experimental Study. IEEE Trans. Electron. Devices 59, 2461–2467 (2012).
Lee, M. H. & Hwang, C. S. Resistive Switching Memory: Observations with Scanning Probe Microscopy. Nanoscale 3, 490–502 (2011).
Celano, U. et al. Filament Observation in Metal-Oxide Resistive Switching Devices. Appl. Phys. Lett. 102, 121602 (2013).
Zhang, M. et al. Set Statistics in Conductive Bridge Random Access Memory Device With Cu/HfO2/Pt Structure. Appl. Phys. Lett. 105, 193501 (2014).
Yoon, J.-W., Yoon, J. H., Lee, J.-H. & Hwang, C. S. Impedance Spectroscopic Analysis on Effects of Partial Oxidation of TiN Bottom Electrode and Microstructure of Amorphous and Crystalline HfO2 Thin Films on Their Bipolar Resistive Switching. Nanoscale 6, 6668–6678 (2014).
Chen, H.-Y. et al. In Electron Devices Meeting (IEDM), IEEE International. 20.27.21–20.27.24 (2012).
Lin, K.-L. et al. Electrode Dependence of Filament formation in HfO2 Resistive-Switching Memory. J. Appl. Phys. 109, 084104 (2011).
Walczyk, C. et al. On the Role of Ti Adlayers for Resistive Switching in HfO2-Based Metal-Insulator-Metal Structures: Top Versus Bottom Electrode Integration. J. Vac. Sci. Technol. B 29, 01AD02 (2011).
Bertaud, T. et al. In-Operando and Non-Destructive Analysis of the Resistive Switching in the Ti/HfO2/TiN-Based System by Hard X-Ray Photoelectron Spectroscopy. Appl. Phys. Lett. 101, 143501 (2012).
Sowinska, M. et al. Hard X-Ray Photoelectron Spectroscopy Study of the Electroforming in Ti/HfO2-Based Resistive Switching Structures. Appl. Phys. Lett. 100, 233509 (2012).
Kim, H., McIntyre, P. C., On Chui, C., Saraswat, K. C. & Stemmer, S. Engineering Chemically Abrupt High-k Metal Oxide/Silicon Interfaces Using An Oxygen-Gettering Metal Overlayer. J. Appl. Phys. 96, 3467–3472 (2004).
Goncharova, L. V. et al. Metal-Gate-Induced Reduction of the Interfacial Layer in Hf Oxide Gate Stacks. J. Vac. Sci. Technol. A 25, 261–268 (2007).
Miranda, E. A., Walczyk, C., Wenger, C. & Schroeder, T. Model for the Resistive Switching Effect in HfO2 MIM Structures Based on the Transmission Properties of Narrow Constrictions. IEEE Electron. Device Letters 31, 609–611 (2010).
Long, S. et al. Voltage and Power-Controlled Regimes in the Progressive Unipolar RESET Transition of HfO2-Based RRAM. Sci. Rep. 3, 2929 (2013).
Huang, C.-Y., Jieng, J.-H., Jang, W.-Y., Lin, C.-H. & Tseng, T.-Y. Improved Resistive Switching Characteristics by Al2O3 Layers Inclusion in HfO2-Based RRAM Devices. ECS Solid State Lett. 2, P63–P65 (2013).
Triyoso, D. H. et al. Physical and Electrical Characteristics of HfO2 Gate Dielectrics Deposited by ALD and MOCVD. J. Electrochem. Soc. 152, G203–G209 (2005).
Lanza, M. et al. Grain Boundaries as Preferential Sites for Resistive Switching in the HfO2 Resistive Random Access Memory Structures. Appl. Phys. Lett. 100, 123508 (2012).
Xue, K.-H. et al. Grain Boundary Composition and Conduction in HfO2: An ab Initio Study. Appl. Phys. Lett. 102, 201908 (2013).
Lanza, M. A Review on Resistive Switching in High-k Dielectrics: A Nanoscale Point of View Using Conductive Atomic Force Microscope. Materials 7, 2155 (2014).
Iglesias, V. et al. Degradation of Polycrystalline HfO2-based Gate Dielectrics under Nanoscale Electrical Stress. Appl. Phys. Lett. 99, 103510 (2011).
Shi, Y. et al. Elucidating the Origin of Resistive Switching in Ultrathin Hafnium Oxides through High Spatial Resolution Tools. ECS Trans. 64, 19–28 (2014).
Calka, P. et al. Engineering of the Chemical Reactivity of the Ti/HfO2 Interface for RRAM: Experiment and Theory. ACS Appl. Mater. & Interfaces 6, 5056–5060 (2014).
Cho, M. et al. Comparison Between Atomic-Layer-Deposited HfO2 Films Using O3 or H2O Oxidant and Hf[N(CH3)2]4 Precursor. Appl. Phys. Lett. 85, 5953–5955 (2004).
Cho, M. et al. Effects of Carbon Residue in Atomic Layer Deposited HfO2 Films on Their Time-Dependent Dielectric Breakdown Reliability. Appl. Phys. Lett. 90, 182907 (2007).
Miao, B., Mahapatra, R., Wright, N. & Horsfall, A. The role of Carbon Contamination in Voltage Linearity and Leakage Current in High-k Metal-Insulator-Metal Capacitors. J. Appl. Phys. 104, 054510 (2008).
Lin, Y. S. et al. Resistive Switching Mechanisms Relating to Oxygen Vacancies Migration in Both Interfaces in Ti/HfOx/Pt Memory Devices. J. Appl. Phys. 113, 064510 (2013).
Lau, W. S., Leong, L. L., Han, T. & Sandler, N. P. Detection of Oxygen Vacancy Defect States in Capacitors with Ultrathin Ta2O5 films by Zero-Bias Thermally Stimulated Current Spectroscopy. Appl. Phys. Lett. 83, 2835–2837 (2003).
Coffman, J. A., Kibler, G. M., Lyon, T. F. & Acchione, B. D. Carbonization of Plastics and Refractories Materials Research. Vol. Part II (WADD TR 60-646, 1963).
Panish, M. B. & Reif, L. Thermodynamics of the Vaporization of Hf and HfO2: Dissociation Energy of HfO. J. Chem. Phys. 38, 253–256 (1963).
Sowinska, M. et al. In-operando Hard X-ray Photoelectron Spectroscopy Study on the Impact of Current Compliance and Switching Cycles on Oxygen and Carbon Defects in Resistive Switching Ti/HfO2/TiN Cells. J. Appl. Phys. 115, 204509 (2014).
Lukosius, M. et al. Atomic Vapor Deposition of Titanium Nitride as Metal Electrodes for Gate-last CMOS and MIM Devices. Chem. Vap. Deposition 14, 123–128 (2008).
Degraeve, R. et al. Generic Learning of TDDB Applied to RRAM for Improved Understanding of Conduction and Switching Mechanism Through Multiple Filaments. Electron Devices Meeting (IEDM), 2010 IEEE International 632, 28.24.21–28.24.24 (2010).
Acknowledgements
G. Niu and H.-D. Kim contributed equally to this work. This work was supported by the ENIAC “PANACHE” project and partly by Deutsche Forschungsgemeinschaft (DFG) RRAM project SCHR 1123/7-1. The publication of this article was funded by the Open Access fund of the Leibniz Association.
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G.N. and H.-D.K. contributed equally to this work. G.N., H.-D.K., R.R. and C.W. designed this work. G.N., H.-D.K. and C.W. prepared the manuscript. The experimental measurements were carried out by G.N., H.-D.K., E.P., M.A.S., P.Z. and I.C. The simulation work was done by C.W., R.R., E.P. and C.W. were involved in device processing. All authors have given approval to the final version of the manuscript.
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Niu, G., Kim, HD., Roelofs, R. et al. Material insights of HfO2-based integrated 1-transistor-1-resistor resistive random access memory devices processed by batch atomic layer deposition. Sci Rep 6, 28155 (2016). https://doi.org/10.1038/srep28155
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DOI: https://doi.org/10.1038/srep28155
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