A Non-Volatile Memory Based on NbOx/NbSe2 Van der Waals Heterostructures
by
, ,
Ji Eun Kim
1,†
,
Van Tu Vu
1,†,
Thi Thanh Huong Vu
1,
Thanh Luan Phan
1,*
,
Young Rae Kim
1,2,
Won Tae Kang
1,2,
Kunnyun Kim
3,
Young Hee Lee
2 and
Woo Jong Yu
1,* 1
Department of Electrical and Computer Engineering, Sungkyunkwan University, Suwon, Kyunggi-do 16419, Korea
2
Center for Integrated Nanostructure Physics, Institute for Basic Science (IBS), Suwon, Kyunggi-do 16419, Korea
3
Korea Electronics Technology Institute, Seongnam 13509, Korea
*
Authors to whom correspondence should be addressed.
†
These authors contributed equally to this work.
Appl. Sci. 2020, 10(21), 7598; https://doi.org/10.3390/app10217598
Submission received: 29 September 2020
/
Revised: 19 October 2020
/
Accepted: 26 October 2020
/
Published: 28 October 2020
(This article belongs to the Section Nanotechnology and Applied Nanosciences)
Abstract
:Two-dimensional (2D) van der Waals (vdW) layered transition metal dichalcogenides (TMDs) materials have been receiving a huge interest due to atomically thin thickness, excellent optoelectronic properties, and free dangling bonds. Especially the metallic TMDs, such as MoTe2 (1T’ phase), NbS2, or NbSe2, have shown fascinating physical properties through various applications, such as superconductor and charge density wave. However, carrier transport of metallic TMDs would be degraded due to the poor stability in ambient conditions. To date, achieving both high device performance and long-term stability is still a huge challenge. Thus, an alternative way to develop both unavoidable native oxide and metallic TMDs is under consideration for new era research. In this respect, 2D metallic TMD materials have attracted high attention due to their great potential in neuromorphic-based devices with metal-insulator-metal structures, making it possible to produce scalable, flexible, and transparent memory devices. Herein, we experimentally demonstrated a synthesized metallic NbSe2 by a chemical vapor deposition method with a highly uniform, good shape distribution and layer controller ranging from 2–10 layers. Together, for the first time, we proposed the NbOx/NbSe2 heterostructure memristor device based on the native NbOx oxide on the interface of multi-layer NbSe2 flakes. The ultra-thin native NbOx oxide of 3 nm was formed after a period of oxidation time under air condition, which acts as a memristive surface in the Au-NbOx-Au lateral memristor device, in which oxygen vacancies form a conductive filament. Our NbOx/NbSe2 hetero-tructured memristor exhibits a stable memory window, a low-resistance-state/high-resistance-state ratio of 20, and stable endurance properties over 20 cycles at a low working voltage of 1 V. Furthermore, by the retention property test, non-volatile characteristics were confirmed after over 3000 s in our best data. Through a systematic study of the NbOx/NbSe2 heterostructured memristor device, this report will open new opportunities for next-generation memory devices application.
1. Introduction
As the amount of data to be processed by the development of an information technology (IT) industry increases, demands on memory chips with high performance and miniaturization have increased rapidly. Accordingly, studies on next-generation memories based on new structures and materials have been actively conducted [1,2,3,4]. In terms of scaling down the limitation of silicon-based memories, the two-dimensional (2D) van der Waals (vdW) layered transition metal dichalcogenide (TMD) materials have received great attention due to their excellent properties, such as atomically thin thickness [5], high mobility [6], various bandgaps [7], transparency [8], flexibility [9] and free dangling bonds [10]. This enables the potential development of various nano-scaled high-performance devices not only in memories, but also in field-effect transistors [11], photodetectors [12], biosensors [13], diodes [14], and so on. However, most of the studies until now have been mainly based on mechanical exfoliation methods with limitations of flake size and low yield, which restrict their application to commercialized-devices. Thus, synthesis on mass-produced 2D materials for large scale and low cost through the chemical vapor deposition (CVD) method has been proposed [15,16,17].
Among them, there has been a demand for utilizing metallic 2D materials for fabricating metal-insulator-metal (MIM) structures for next-generation memory, resistive switching random-access memory (ReRAM) [18,19], which has been spotlighted with attractive advantages, such as fast switching speed, low operation voltage, and good scalability, making it one of the most promising candidates for next nonvolatile memory devices [1,2,3,4]. Despite such favorable demands, the sensitive metallic 2D materials were easily degraded due to poor stability in ambient conditions [18]. To address such poor stability of metallic TMDs, passivation or interfacial engineering have been introduced [20,21,22]. Nonetheless, to achieve both high device performance and long-term stability is still hugely challenging. Thus, another alternative way to develop both unavoidable native oxide and metallic TMDs is under consideration for new era research. In this respect, the sensitive metallic TMD vdW material can be utilized as resistive memory by forming an ultra-thin native oxide on the surface of host materials under ambient conditions, which can act as a memristive surface memristor with an oxygen vacancy, forming a conductive filament [23,24].
In this study, we have experimentally demonstrated the synthesis of NbSe2 flake by the CVD approach with highly uniform, good shape distribution and layer controller ranging from 2 layers to 10 layers. Furthermore, for the first time, we proposed the NbOx/NbSe2 heterostructure memristor device based on the native NbOx oxide on the interface of multi-layer NbSe2 flake. The ultra-thin native NbOx oxide of 3 nm was formed after a period of oxidation time under air condition, which acts as a memristive surface in the Au-NbOx-Au lateral memristor device, in which oxygen vacancies forming a conductive filament. Our NbOx/NbSe2 heterostructured memristor exhibits a stable memory window with reversible switching processes at a low working voltage of 1 V. Furthermore, the memristor shows a low-resistance-state (LRS)/high-resistance-state (HRS) ratio of about 20 and non-volatile properties via a retention test of 3000 s. Moreover, good endurance without any degradation up to 20 endurance cycles was demonstrated. Our strategy to fabricate feasible memristor for next-generation memory devices suggests new opportunities based on the CVD-grown 2D metallic materials.
2. Materials and Memristor Fabrication
2.1. Synthesis of NbSe2 by Using Chemical Vapor Deposition (CVD) Method
Figure 1a shows a schematic of a CVD growth of NbSe2 flakes. Firstly, the ammonium niobium oxalate (ANO)-C4H4NNbO9·xH2O (Sigma-Aldrich) was used as the niobium (Nb) precursor. The stock solution of Nb was prepared by dissolving a calculated amount of ANO powders in a deionized (DI) water. (0.3 g/10 mL) The sodium hydroxide (NaOH) was used as a promoter and medium solution of iodixanol (Opti Prep density gradient medium, Sigma Aldrich) which enhances the adhesion between the solution and the growth substrate during the liquid source coating process. These compositions were mixed in a precise ratio and then uniformly shaken with a speed of 300 rpm to obtain a homogeneous solution phase. The mixed solution was then deposited on a 300-nm thick SiO2/Si substrate by a spin-coating with a speed of 3500 rpm for 1 min. Next, the coated substrate was annealed at 500 °C for 30 min in the air to convert ANO into Nb2O5 as well as burn carbon from Opti [25]. For a typical CVD growth process, the coated substrate was placed on a ceramic plate and loaded in the center of the quartz tube of a CVD chamber. Here, the solid selenium (Se) was located at an entrance region with a distance of 17 cm from the center of the quartz tube of the chamber. Note that the distance of the Se source was controlled at various positions from 17 to 18.5 cm for controlling the heating temperature of the source, which will be discussed in detail later (Figure 1b). The temperature was controlled at 380 °C at the Se source location while the growth reaction was performed at 800 °C for 20 min under the flowing of 300 sccm N2 and 20 sccm H2 gas, which was used as a carrier gas during the whole growth process (Figure S1). Finally, the chamber was rapidly cooled down by opening the furnace after completing the whole synthesis process.
2.2. Fabrication of NbOx/NbSe2 Heterostructured Memristor Device
The as-grown NbSe2 flake sample was transferred to a target substrate by a typical wet-transfer approach [26]. Firstly, the as-grown NbSe2 sample was coated with a poly-methyl-methacrylate (PMMA) C4, which formed a support layer. Then, the substrate was etched with a diluted hydrogen fluoride (HF) acid solution to separate the grown sample/PMMA film from the growth substrate. With several rinsing with deionized (DI) water, it was transferred onto a target SiO2/Si substrate. Finally, after drying the transferred sample, the PMMA support layer was removed by acetone and rinsed again via isopropyl alcohol (IPA) solution. (Figure 1c)
The native oxide layer (NbOx) was formed by exposing the grown NbSe2 sample to the air at room temperature for several days (in our case, 21 days), resulting in NbOx/NbSe2 heterostructure, where the NbOx layer can act as a memristive surface. To fabricate the memristor device, the metal electrodes (source and drain) for a probe contact were patterned on NbOx/NbSe2 heterostructures using e-beam lithography followed by e-beam deposition of Cr/Au (5/50 nm). Electrical and memristive feature measurements for NbSe2 and NbOx/NbSe2 heterostructures were performed using a probe station and a semiconductor analyzer (Keysight B1500A) at room temperature.
3. Results
3.1. Characterization
3.1.1. NbSe2 Material Characterization
The NbSe2 flake was characterized by Raman spectroscopy at room temperature under a 0.4-mW laser power and 532-nm wavelength excitation laser (XperRam200, Nano base) (Figure 1d). The spatially resolved Raman mapping images are shown according to A1g and E2g modes, as shown in Figure 1d and Figure S2, respectively. As a result, the intensity of both peaks (A1g and E2g) was distributed uniformly. It suggests that we successfully grew high uniformity of the NbSe2 flake using the CVD method. In the middle part of the NbSe2 flake, there was a damage point, which was attributed to the laser focus during the measurement process. In Figure 1e, it is clearly shown that the Raman peak of our NbSe2 flake is located at about 225 cm−1 and about 250 cm−1 of NbSe2, which are assigned to the out-of-plane mode A1g peak and the in-plane mode E2g peak in NbSe2 flake [27].
To further optimize our CVD-grown NbSe2 flake, we conducted experiments to meticulously explore possibly contributing to the NbSe2 thickness as a function of Se source distance (dSe) from the center of the quartz. Figure 2 shows the NbSe2 flake grown with different distances between the Se solid source and center of the quartz, ranging from 17 to 18.5 cm while fixing all other parameters. It is noted that the one-zone CVD chamber was used for synthesis. The temperature set for the growth (800 °C for this experiment) can be kept well at the center of the quartz tube but gradually declines as it goes toward the edge of the quartz tube. Thus, controlling the loading position of Se (dSe) in the quartz tube can be interpreted as controlling the heating temperature of the Se source. Base on that, the NbSe2 flake thickness concerning the dSe for 17–18.5 cm was separately measured in Figure 2a–h. At a long dSe (18.5 cm), the NbSe2 flake showed a thickness of 2.4 nm as confirmed by atomic force microscopy (AFM) height profile function (Figure 2a,b). With decreasing the dSe to 18 cm, the NbSe2 flake thickness was increased to 4.8 nm (Figure 2c,d). Furthermore, with decreasing the dSe to 17.5, 17 cm, the thickness of the NbSe2 flake increased up to 7.2 and 12 nm, respectively (Figure 2e–h). These tendencies can be explained as follows. The different heating temperatures of Se induce different flow rates of the selenium vapor by affecting the vaporizing speed of Se and consequently affect the selenization amount of Nb2O5 [27]. The selenization amount during growth can heavily determine the thickness of the NbSe2, because the NbSe2 form a stacking layer over the grown flakes rather than expanding towards the SiO2 surface, which can form a larger flake. Note that the SiO2 surface is not flat and has many dangling bonds, which result in high energy barrier energy and low diffusion NbSe0,1,2 radicals [28]. Thus, NbSe2 growth at the SiO2 surface is remarkably limited and, therefore, the staking of NbSe2 is perpendicularly formed. Figure 2i summarizes the thickness of NbSe2 flake corresponding to the dSe (for 17–18.5 cm). The error bar indicates ±10 °C and ±2 nm for the x and y-axis, respectively. From the data, with increasing the dSe, the thickness of NbSe2 flake decreased due to the selenization process as described above. According to the height profiles in atomic force microscopy (AFM, SPA 400, Seiko Instruments) images along with the dSe ranging from 17–18.5 cm, the different thicknesses of 2.4 to 12 nm, corresponding to the 2 layers, 4 layers, 6 layers, and 10 layers, are defined.
Together, Raman spectroscopy also identifies the thickness of the CVD-grown NbSe2 (Figure 2j). For the measurements, a laser power of 0.4 mW and an excitation wavelength of 532 nm were used. At room temperature, the intensity of the peaks (A1g and E2g) of thin-layer NbSe2, such as 2 or 4 layers, were shown weekly. However, as the thickness increased, such as to 6 or 10 layers, the intensity of the two peaks increased noticeably, which is in good agreement with the previous reports [27].
For more optimal conditions for NbSe2 growth, the roles of H2 and the ratio of the carrier gas were examined (Figure S3). Without H2 flow, there are only NbSe2 particles grown, while the NbSe2 flake size tends to be small under high H2 concentration (N2/H2 = 300/40~60). This is because it has been reported that H2 plays a reducer agent in the growth reaction [29]. Thus, in the absence of H2, there are insufficient NbSe0,1,2 radicals for growth, while H2 also promotes the chemical etching effect rather than the formation of NbSe2 under a high flow of H2 [30]. From these perspectives and our results, 300/20 sccm for carrier gas ratio was found to be the optimal condition.
3.1.2. NbSe2 Electrical Characterization
We now describe the electrical characteristic of our NbSe2 flakes field-effect transistor (FET) device at room temperature under a high vacuum (1 × 10−6 Torr), Figure 3a. Figure 3b shows the transfer characteristics of the NbSe2 FET device at Vgs, sweeping from −50 to 50 V at various Vds ranging from −0.5 to 0.5 V. As a result, our NbSe2 flakes show an intrinsically metallic behavior with no gate dependence from −50 V to 50 V and a high on-current of 0.1 mA. Figure 3c shows the output characteristics of the NbSe2 FET device at varying Vgs of −50 V to 50 V. As the results indicate, an ohmic contact behavior with a linear relation between I and V were observed with no current difference according to different gate voltage biasing, in agreement with transfer curve results. These properties were also confirmed in our other NbSe2 devices (Figure S4).
3.2. Properties of the NbOx/NbSe2 Heterostructured Memristor Device
Considering the highly electrical conductivity of our NbSe2 flakes, we built the NbOx/NbSe2 heterostructure for a memristor device as shown in Figure 4a. Before discussing, it is noted that the thin NbSe2 flakes (below six layers) are very sensitive in ambient, which is easily damaged in a short period, suggesting unsuitability for our heterostructure memristor device (Figure S5). To perform this concept device, we are using the thick NbSe2 flakes of 10 layers (Figure 4b). By exposing the thick NbSe2 flakes under an ambient condition for 21 days, the native NbOx layer was formed on the NbSe2 interface. Our NbOx/NbSe2 heterostructure is operating in a lateral direction (Au-NbOx-Au) by resistance switching through the lateral NbOx layer on top of NbSe2. Furthermore, in the NbOx/NbSe2 lateral memristor, total resistance (Rtot) can be considered as NbSe2 resistance (RNbSe2) + NbOx resistance (RNbOx) (Figure S6) [31]. In the case of a low resistance state (LRS), Rtot is more influenced by RNbSe2 compared to RNbOx because of the formation of conductive filament interior of the oxide layer. Thus, during the LRS state, low Rtot can be realized by using a thicker metallic NbSe2 layer, resulting in high-performance LRS.
Figure 4b shows the optical microscope images and AFM mapping images of intrinsic multi-layer NbSe2 flake (top-panel) and the NbOx/NbSe2 flake (bottom panel) are depicted. The intrinsic multi-layer NbSe2 was observed to have a 12-nm thickness (black solid line in Figure 4c). After a period of 21 days in the air condition, the native NbOx oxide was formed. The height of the flake was increased up to 15 nm (blue solid line in Figure 4c) which can be interpreted as forming a 3-nm NbOx native oxide layer on top of the intrinsic NbSe2 flake.
Figure 4d shows the current–voltage (I–V) characteristic of our NbOx/NbSe2 heterostructure memristor device. The inserted image is an optical microscope image of our device. Voltage was swept as 0 V → +1 V → −1 V → 0 V between the drain and the source electrode with the duration time of 0.1s, which showed reproducible and nonvolatile hysteretic resistive switching behavior in synaptic memory. During the positive voltage sweep, the current increased via migration of positively charged oxygen vacancies (conductive filament (CF) formation), with which the device showed the HRS to LRS transition. The resistance state kept LRS with the reverse voltage sweep. Then, again, the reset transition process started at −1V, and the LRS to HRS transition was exhibited during the negative voltage sweep. Here, the noise had occurred during the I–V switching measurement, which is probably due to the non-uniform and ultra-thin native oxide layer (~ 3 nm NbOx). It is suggested that the conductive filament pathway can be randomly formed and induce the current noise in the set/reset process during the extraction/recovery process of oxygen vacancies. The retention time and cyclic endurance were also examined to elucidate memory functionalities. In Figure 4e, a single writing pulse of VW = +1 V and −1 V was applied to switch memory into LRS and HRS, respectively, with a typical switching time of 0.1 s. The reading current was read out with a small reading bias of VR = 0.1 V and was defined as the current of HRS (black dotted line) and LRS (red dotted line). Moreover, no degradation was shown up to over 20 endurance cycles, maintaining a stable on/off ratio of 20. The retention property of the NbOx/NbSe2 heterostructure memristor was also conducted under a 10-mV reading voltage, resulting in over 250 s as shown in Figure 4f. The short retention time is because of our measurement set up as following, by (i) I–V switching, (ii) retention time test, and (iii) endurance test. To get all good electrical characteristics at once, the retention time was measured until ~250 s. To further prove the retention ability of our device, we measured other devices by focusing on the retention test on the same substrate. As a result, our best data were obtained at ~3000 s in retention time under a 10-mV reading voltage (Figure S7), where both LRS and HRS were stably remained, confirming the non-volatile properties of our NbOx/NbSe2 heterostructure memristor device.
For understanding the resistance switching behavior in the memristor, the formation process of conductive filaments (CFs) should be preceded. The mechanism of conductive filaments in our NbSe2/NbOx heterostructure memristor is depicted in Figure 4g. In particular, if the voltage is biased to the drain electrode, the electric field is applied to the NbOx layer and the movement of oxygen ions inside the oxide layer is generated. This movement causes positively charged oxygen vacancies in the oxide layer which acts as the CF. Accordingly, the source and drain electrodes are connected, and a switch-on state is maintained by exhibiting a low-resistance-state (LRS) at the oxide layer (high-resistance-state (HRS) to LRS transition, Set). In contrast, under reverse bias, the conductive filaments disappear via filling the oxygen vacancies by moving oxygen ions, which results in HRS on the oxide layer (LRS to HRS transition, Reset). To confirm the conduction mechanisms in our NbOx/NbSe2 memory device, the I–V curve of Figure 4d was replotted with a double-logarithmic scale as shown in Figure S8. According to the graphs, our device followed the Space Charge Limited Conduction (SCLS) mechanism with the most accepted factor as oxygen vacancies in our device [32,33]. The details are discussed in the Supplementary Note 1.
Besides, an exposing time in the air is an important factor for realizing our heterostructure memristor device. We compared the I–V characteristic to the influence of the oxidation period, expected to provide the large on/off current ratio of LRS/HRS (Figure 4h and Figure S9). As result, with increasing the oxidation time, the HRS keeps decreasing while the LRS remains stable. More details about the relationship between the oxidation time and the device performance are explained in Supplementary Note 2. Our NbSe2/NbOx heterostructure memristor device was mostly stable at 21 days of oxidation time in ambient conditions. To prove that, we measured our device under ambient and vacuum conditions, as shown in Figure S10. From the data, the device shows well repeatable memory behavior in both conditions, indicating that the elimination of oxygen in the air was un-affected by our device performance. Thus, we can conclude that the non-volatile memory behavior of our NbSe2/NbOx heterostructure originates from the NbOx oxide layer on the NbSe2 interface, which is similar to the NbS2 material in the previously reported study [31].
4. Conclusions
In conclusion, we have demonstrated the synthesis of NbSe2 flakes by the CVD approach via specifically controlled Se source distance from the center of the quartz (dSe) and the carrier gas ratio (H2:N2). Concerning these efforts, we had successfully grown the NbSe2 flakes with highly uniform, good shape distribution, controlling layers from 2 to 10 layers. Together, we proposed the NbOx/NbSe2 heterostructure memristor device based on the native NbOx oxide on the interface of NbSe2 flakes. Here, the NbOx oxide layer acts as a memristive surface in the Au-NbOx-Au lateral memristor device, in which oxygen vacancies form a conductive filament. Our memristor shows an LRS/HRS ratio of 20 and stable cyclic endurance properties at a low working voltage of 1 V. Furthermore, by retention test, non-volatile characteristics were confirmed at 3000 s. This systematic study of the NbOx/NbSe2 heterostructured memristor device is expected to open the possibilities of a viable next-generation memory device.
Supplementary Materials
The following are available online at https://www.mdpi.com/2076-3417/10/21/7598/s1, Figure S1: The CVD growth condition for NbSe2 flakes; Figure S2: Raman mapping image according to E2g mode at 250 cm−1 of the CVD-grown NbSe2; Figure S3: CVD NbSe2 growth tendency according to the optimization of carrier gas ratio (N2:H2); Figure S4: Electrical characteristics of various other CVD-grown NbSe2 flakes; Figure S5: The oxidization effect of the thin CVD-grown NbSe2 flake; Figure S6: Formation of channels in a memristor device structured with NbOx/NbSe2 heterostructure; Figure S7: Retention properties of the NbOx/NbSe2 memristor under 0.01-V read voltage; Figure S8: I–V curves of NbOx/NbSe2 memory devices, displayed on a double-logarithmic scale; Figure S9: I–V characteristic of NbOx/NbSe2 heterostructure memristor along with the influence of oxidation time (0–24 days); Figure S10: Electrical comparison of memristor under vacuum and ambient condition. Supplementary Note 1: Explanation of the conduction mechanism of our NbOx/NbSe2 memory device based on the SCLC mechanism; Supplementary Note 2: Explanation of the relationship between the exposure time and device performance.
Author Contributions
Conceptualization, J.E.K., V.T.V., T.T.H.V., T.L.P. and W.J.Y.; Data curation, J.E.K., V.T.V., T.T.H.V., T.L.P. and W.J.Y.; Formal analysis, J.E.K., V.T.V., T.T.H.V., T.L.P., Y.R.K., W.T.K. and W.J.Y.; Funding acquisition, K.K., Y.H.L. and W.J.Y.; Project administration, W.J.Y.; Resources, K.K., Y.H.L. and W.J.Y.; Supervision, T.L.P. and W.J.Y.; Validation, J.E.K., T.L.P. and W.J.Y.; Visualization, J.E.K. and T.L.P.; Writing—original draft, J.E.K., V.T.V. and T.T.H.V.; Writing—review and editing, J.E.K., T.L.P., Y.R.K. and W.J.Y. All authors have read and agreed to the published version of the manuscript.
Funding
This research was supported by the Bio and Medical Technology Development Program of the National Research Foundation (NRF) funded by the Ministry of Science and ICT (NRF-2020M3A9E4039241) and the Multi-Ministry Collaborative R&D Program through the National Research Foundation of Korea, funded by KNPA, MSIT, MOTIE, ME, and NFA (2017M3D9A1073539). This research was supported by the MSIT (Ministry of Science and ICT), Korea, under the ICT Creative Consilience program (IITP-2020-0-01821) supervised by the IITP (Institute for Information and communications Technology Planning and Evaluation). This work was supported by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MSIT) (NRF-2018R1A2B2008069). This work was also supported by the Institute for Basic Science (IBS-R011-D1).
Conflicts of Interest
Authors declare no conflict of interest.
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Figure 1.
Synthesis settings and characteristics of chemical vapor deposition (CVD)-grown NbSe2: (a,b) The schematic image and photo image of synthesis settings for NbSe2 Growth. The ammonium niobium oxalate-C4H4NNbO9·xH2O (ANO) source-coated substrate was loaded in the center of the CVD chamber and the solid Se was located at the upstream region where the distance is 17 cm from the center of the quartz; (c) optical microscope image of as-grown NbSe2; (d) Raman mapping image according to A1g mode; (e) the out-of-plane A1g mode at 225 cm−1 and the in-plane E2g mode at 250 cm−1 were observed.
Figure 1.
Synthesis settings and characteristics of chemical vapor deposition (CVD)-grown NbSe2: (a,b) The schematic image and photo image of synthesis settings for NbSe2 Growth. The ammonium niobium oxalate-C4H4NNbO9·xH2O (ANO) source-coated substrate was loaded in the center of the CVD chamber and the solid Se was located at the upstream region where the distance is 17 cm from the center of the quartz; (c) optical microscope image of as-grown NbSe2; (d) Raman mapping image according to A1g mode; (e) the out-of-plane A1g mode at 225 cm−1 and the in-plane E2g mode at 250 cm−1 were observed.
Figure 2.
Different thickness of CVD-grown NbSe2 via controlled growth parameter. (a–h) The microscope images, height profiles of 2 layer, 4 layer, 6 layer, and 10 layer NbSe2. The thickness of the flakes was controlled by the different distances to the Se from the center of the quartz; (i) the thickness tends to increase as the distance decreases, meaning that it increases the heating temperature of the Se source; (j) Raman spectrum according to the different thickness of the flakes under a 532-nm excitation wavelength laser.
Figure 2.
Different thickness of CVD-grown NbSe2 via controlled growth parameter. (a–h) The microscope images, height profiles of 2 layer, 4 layer, 6 layer, and 10 layer NbSe2. The thickness of the flakes was controlled by the different distances to the Se from the center of the quartz; (i) the thickness tends to increase as the distance decreases, meaning that it increases the heating temperature of the Se source; (j) Raman spectrum according to the different thickness of the flakes under a 532-nm excitation wavelength laser.
Figure 3.
Electrical properties of the CVD-grown NbSe2 field-effect transistor (FET) device. (a) Optical image of the NbSe2 device with drain and source electrodes; (b) transfer characteristic with gate voltage sweep from −50 V to 50 V under constant drain bias ranges from −0.5 V to 0.5 V. No switching property was observed according to the gate voltage. (c) Output characteristic with drain voltage sweep from −0.5 V to 0.5 V under constant gate bias ranges from −50 V to 50 V. Under different gate biases, a similar current level of drain bias was observed, which also shows the metallic properties, no gate dependency.
Figure 3.
Electrical properties of the CVD-grown NbSe2 field-effect transistor (FET) device. (a) Optical image of the NbSe2 device with drain and source electrodes; (b) transfer characteristic with gate voltage sweep from −50 V to 50 V under constant drain bias ranges from −0.5 V to 0.5 V. No switching property was observed according to the gate voltage. (c) Output characteristic with drain voltage sweep from −0.5 V to 0.5 V under constant gate bias ranges from −50 V to 50 V. Under different gate biases, a similar current level of drain bias was observed, which also shows the metallic properties, no gate dependency.
Figure 4.
NbOx/NbSe2 van der Waals memristive memory properties. (a) The schematic image of the NbOx/NbSe2 heterostructure memristor. On top of the multi-layer NbSe2, NbOx was formed. (b) Optical microscope image and corresponding atomic force microscopy (AFM) mapping images of the intrinsic NbSe2 flake (top panel) and NbOx-formed NbSe2 flake (bottom panel). (c) The height profile of NbOx/NbSe2 and NbSe2 heterostructures. It is increased by about 2 nm compared to intrinsic flakes (12 nm), which can prove the formation of the NbOx. (d) Typical current−voltage curves of the memristor. The inset figure is the corresponding memristor device. (e) Endurance characteristics against repeated resistance switching cycles under 0.1 V read voltage. (f) Retention properties of the memristor under 0.01 V read voltage. Non-volatile properties were observed over 3 min without any resistance switching. (g) Schematics of memristive switching mechanism by conductive filament formation and rupture processes via migration of oxygen vacancies. (h) Hysteresis variation of the NbOx/NbSe2 hetero memory device according to the oxidation period of the NbSe2 flake in the air.
Figure 4.
NbOx/NbSe2 van der Waals memristive memory properties. (a) The schematic image of the NbOx/NbSe2 heterostructure memristor. On top of the multi-layer NbSe2, NbOx was formed. (b) Optical microscope image and corresponding atomic force microscopy (AFM) mapping images of the intrinsic NbSe2 flake (top panel) and NbOx-formed NbSe2 flake (bottom panel). (c) The height profile of NbOx/NbSe2 and NbSe2 heterostructures. It is increased by about 2 nm compared to intrinsic flakes (12 nm), which can prove the formation of the NbOx. (d) Typical current−voltage curves of the memristor. The inset figure is the corresponding memristor device. (e) Endurance characteristics against repeated resistance switching cycles under 0.1 V read voltage. (f) Retention properties of the memristor under 0.01 V read voltage. Non-volatile properties were observed over 3 min without any resistance switching. (g) Schematics of memristive switching mechanism by conductive filament formation and rupture processes via migration of oxygen vacancies. (h) Hysteresis variation of the NbOx/NbSe2 hetero memory device according to the oxidation period of the NbSe2 flake in the air.
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Kim, J.E.; Vu, V.T.; Vu, T.T.H.; Phan, T.L.; Kim, Y.R.; Kang, W.T.; Kim, K.; Lee, Y.H.; Yu, W.J. A Non-Volatile Memory Based on NbOx/NbSe2 Van der Waals Heterostructures. Appl. Sci. 2020, 10, 7598. https://doi.org/10.3390/app10217598
AMA Style
Kim JE, Vu VT, Vu TTH, Phan TL, Kim YR, Kang WT, Kim K, Lee YH, Yu WJ. A Non-Volatile Memory Based on NbOx/NbSe2 Van der Waals Heterostructures. Applied Sciences. 2020; 10(21):7598. https://doi.org/10.3390/app10217598
Chicago/Turabian StyleKim, Ji Eun, Van Tu Vu, Thi Thanh Huong Vu, Thanh Luan Phan, Young Rae Kim, Won Tae Kang, Kunnyun Kim, Young Hee Lee, and Woo Jong Yu. 2020. "A Non-Volatile Memory Based on NbOx/NbSe2 Van der Waals Heterostructures" Applied Sciences 10, no. 21: 7598. https://doi.org/10.3390/app10217598
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