Introduction

Lately, a novel memory device, resistive switching memory, has been extensively studied due to its great potential of low operation voltage, low power consumption, high operation speed, nonvolatility, and simple structure [18]. Particularly, the ZrO2-based resistive switching memory has attracted more and more attention because it is compatible with the conventional CMOS process [1, 2]. In the previous reports [913], the Al/ZrO2/Pt structural devices presented a unipolar resistive switching property that might cause a switching error while the unipolar resistive switching was performed. However, the Al/ZrO2/Pt device with bipolar resistive switching is revealed in this work. It is demonstrated that the device with bipolar resistive switching is more stable and reliable for memory application. In addition, the existence of non-lattice oxygen in the ZrO2 film deposited at room temperature (RT) is firstly proposed. We infer that the non-lattice oxygen will react with the Al atoms to form an AlOy interface layer during the deposition of the Al top electrode (TE). The resistive switching within the interface layer is expected to be more stable and uniform than that within the bulk ZrO2 film, leading to a higher device yield [9]. The Al/ZrO2/Pt device proposed in this study is also possible for application in flexible electronic equipment because it can be fully fabricated at RT.

Experimental details

As shown in Figure 1, the device that consisted of five sets of samples in the form of Al/ZrO2/Pt sandwich structure was employed in this work. First of all, a 200-nm-thick SiO2 isolation layer was thermally grown on five cleaned Si substrates in an oxidation furnace. After that, a 20-nm-thick Ti adhesion layer and a 60-nm-thick Pt bottom electrode (BE) were continuously deposited on the SiO2 layer by an electron beam evaporator at RT without breaking a vacuum. Then, an about 20-nm-thick ZrO2 resistive switching layer was deposited on the Pt BE by a radio frequency magnetron sputtering at different temperatures, including RT, 150°C, 200°C, 250°C, and 300°C. Finally, 300-nm-thick Al TEs with 250-μm diameter defined by a shadow mask were deposited on the ZrO2 film at RT by the sputtering to complete the Al/ZrO2/Pt structural samples.

Figure 1
figure 1

Structure of the Al/ZrO 2 /Pt device. Throughout the electrical measurements, bias voltages were applied on the Al TE; meanwhile, the Pt BE was grounded.

The chemical bonding states and the non-lattice oxygen of the ZrO2 films were determined by an X-ray photoelectron spectroscopy (XPS). The electrical properties of the samples were recorded by Keithley 2400 source meter (Keithley Instruments, Inc., Cleveland, OH, USA). Throughout the electrical measurements, bias voltages were applied on the Al TE; meanwhile, the Pt BE was grounded. All of the measurements were performed at RT.

Results and discussion

Figure 2 depicts the resistive switching I-V curves typically for the Al/ZrO2/Pt samples where the ZrO2 films were deposited at various temperatures. The bipolar resistive switching indicates that the memory states of the device are altered by applying bias voltages with different polarities (curves 1 and 2). On the other hand, the unipolar resistive switching means that the memory states are switched by applying bias voltages with the same polarity (curves 1 and 3). As shown in Figure 2, the memory states of the device can be switched from a high resistance state (HRS) to a low resistance state (LRS) by applying a positive bias voltage, which is called set process. Besides, the memory states can be altered back to the HRS by applying a positive or negative bias, called reset process. The reset process is independent of voltage polarity. A current compliance (CC) is set at 10 mA during the set process to prevent degradation of the device, but no CC is used during the reset process. The set and reset processes, i.e., the resistive switching, can be stably repeated for a lot of times, and the memory states between the LRS and HRS are distinguishable.

Figure 2
figure 2

Typical resistive switching I - V curves of the Al/ZrO 2 /Pt device. Under the bipolar resistive switching mode (curves 1 and 2) and the unipolar resistive switching mode (curves 1 and 3).

Figure 3 shows the yield of the samples where the ZrO2 films were deposited at various temperatures. The yield is defined as a percentage of samples which possess the resistive switching behavior. As shown in Figure 3, the Al/ZrO2/Pt samples where the ZrO2 film was deposited at RT show the highest yield. In addition, the device yields are decreasing with the increased deposition temperatures of the ZrO2 films, the property which can be explained by the XPS results as shown in Figure 4.

Figure 3
figure 3

Yields of the Al/ZrO 2 /Pt samples deposited at various temperatures. Where the ZrO2 films were deposited at RT, 150°C, 200°C, 250°C, and 300°C. The samples fabricated at RT show the highest yield.

Figure 4
figure 4

XPS spectra of the ZrO 2 films deposited at various temperatures. (a) Zr 3d and (b) O 1s XPS spectra of the ZrO2 films deposited at RT, 150°C, 200°C, 250°C, and 300°C. The ZrO2 film deposited at RT possesses the highest content of the non-lattice oxygen.

Figure 4a exhibits the Zr 3d XPS spectra of the ZrO2 films deposited at various temperatures. The peaks of Zr 3d3/2 and Zr 3d5/2 are near 184 and 182 eV, respectively, the energy which indicates the ZrO2 bonding [14, 15]. In addition, no metallic Zr peak (178.9 eV) is found [16], and the result shows that the ZrO2 films deposited at various temperatures are fully oxidized. Figure 4b shows the O 1s XPS spectra of the ZrO2 films. The ZrO2 films deposited at various temperatures exhibit lattice oxygen signals at about 529.8 eV, which indicates the Zr-O bonding [14]. Besides, non-lattice oxygen signals at 531.0 eV decrease with the increased deposition temperatures of the ZrO2 films. Therefore, the ZrO2 film deposited at RT possesses the highest content of the non-lattice oxygen, where the ZrO2 film plays a role of oxygen storage room. During the sputtering of the Al TEs, we infer that the non-lattice oxygen in the ZrO2 film will react with the Al atoms to form an AlOy interface layer. The resistive switching within the interface layer is expected to be more stable and uniform than that within the bulk ZrO2 film, leading to a higher device yield. Lin et al. also demonstrated that the resistive switching near the Ti/ZrO2 interface layer with sufficient oxygen ions possesses stable resistive switching behavior [12]. Because the yield of the Al/ZrO2/Pt device fabricated at RT is higher than that of the other samples, more detailed investigations focused on this device are shown as follows.

Figure 5a, b depicts the resistive switching cycles of the samples fabricated at RT under the bipolar and unipolar resistive switching modes, respectively. The resistive switching can be stably repeated for over 100 times under both resistive switching modes. Figure 6a, b is the cumulative probabilities of the set and reset voltages under the bipolar and unipolar modes depicted in Figures 5a, b, respectively. The set and reset voltages under the bipolar mode are distinguishable; however, the voltages under the unipolar mode show a little overlap as shown in the shaded region of Figure 6b. Figure 6c shows the cumulative probabilities of the HRS currents measured at 0.1 V and the LRS currents measured at -0.1 V under the bipolar mode depicted in Figure 5a. During 150 resistive switching cycles, the LRS currents firmly hold on about several milliampere, and the HRS currents keep very low. Two memory states are distinguishable under the bipolar resistive switching.

Figure 5
figure 5

Resistive switching cycles of the samples fabricated at RT. Under the (a) bipolar and (b) unipolar modes. The resistive switching can be stably repeated for over 100 times under both resistive switching modes.

Figure 6
figure 6

Cumulative probabilities of the set and reset voltages and the LRS and HRS currents. Cumulative probabilities of the set and reset voltages of the sample fabricated at RT under the (a) bipolar and (b) unipolar modes. The set and reset voltages under the bipolar mode are distinguishable. (c) Cumulative probabilities of the HRS currents measured at 0.1 V and the LRS currents measured at -0.1 V under the bipolar mode. Two memory states are distinguishable.

Figure 7 shows the retention time of the sample fabricated at RT under the bipolar resistive switching mode. The LRS and HRS currents measured at ± 0.1 V firmly hold on about 6 mA and 2 × 10-8 A, respectively, for over 106 s without applying any power supply. The current ratio between the two memory states is over 105 times. Consequently, the good nonvolatility of the sample is demonstrated.

Figure 7
figure 7

Retention time of the sample fabricated at RT. LRS and HRS currents measured at ± 0.1 V firmly hold on about 6 mA and 2 × 10-8 A, respectively, for over 106 s without applying any power supply, so the good nonvolatility of the sample is demonstrated.

Figure 8 shows device-to-device uniformities of ten samples fabricated at RT under the bipolar resistive switching mode. The set and reset voltages under the bipolar mode are distinguishable. The LRS currents measured at -0.1 V and the HRS currents measured at 0.1 V are also distinguishable.

Figure 8
figure 8

Device-to-device uniformities of ten samples fabricated at RT under the bipolar resistive switching mode. Including the set and reset voltages and the LRS and HRS currents measured at ± 0.1 V.

Based on the resistive switching I-V curves shown in Figure 2 and the XPS spectra depicted in Figure 4, a possible resistive switching mechanism of the ZrO2-based resistive switching memory fabricated at RT is proposed. As shown in Figure 9, we infer that the AlOy interface layer with some oxygen vacancies will be formed during the sputtering of the Al TE. While a positive bias voltage is applied on the Al TE, the oxygen vacancies with positive charges will migrate through the ZrO2 film to connect the Pt BE, the connection which causes the formation of conductive filament (CF) [17]. On the other hand, the reset process can be achieved by applying a positive or negative bias voltage, i.e., regardless of voltage polarity, so we suppose that the reset process happens due to thermal oxidation of the oxygen vacancies in the CF near the AlOy/ZrO2 interface by accumulated local Joule heating, causing the rupture of the CF [18, 19]. However, migration of charged ions leading to the rupture of the CF can be excluded in this study because the reset process is independent of voltage polarity. In addition, the LRS current of the Al/ZrO2/Pt device is dominated by Ohmic conduction, which corresponds to the CF conduction model as shown in Figure 9. Furthermore, the HRS current of the device follows Frenkel-Poole emission at high electric fields, the result which corresponds to the bulk leakage current in the ZrO2 film.

Figure 9
figure 9

Possible resistive switching mechanism of the Al/ZrO 2 /Pt device. The set and reset are due to the formation and rupture of the CF in the ZrO2 film.

Conclusions

The Al/ZrO2/Pt resistive switching memory was successfully fabricated at RT. The thickness of the ZrO2 film proposed in this work is only 20 nm. The device yield improved by the non-lattice oxygen in the ZrO2 film is demonstrated. The memory states of the device can be set from the HRS to the LRS by applying a positive bias voltage, leading to the migration of oxygen vacancies in the ZrO2 film to connect the Pt BE, the connection which causes the formation of the CF. In addition, the memory state can be reset back to the HRS by applying a bias voltage regardless of its polarity, so we suppose that the reset process happens due to thermal oxidation of the oxygen vacancies in the CF by accumulated local Joule heating, causing the rupture of the CF. The nonvolatility of the device is also demonstrated. The Al/ZrO2/Pt resistive switching memory is also possible for application in flexible electronic equipment because it can be fully fabricated at RT.