Impact of Chamber/Annealing Temperature on the Endurance Characteristic of Zr:HfO2 Ferroelectric Capacitor
by
, , , ,
Yejoo Choi
1, 
Changwoo Han
1,
Jaemin Shin
2,
Seungjun Moon
1,
Jinhong Min
3,
Hyeonjung Park
1,
Deokjoon Eom
4,
Jehoon Lee
4 and
Changhwan Shin
5,*
1
Department of Electrical and Computer Engineering, Sungkyunkwan University, Suwon 16419, Korea
2
Department of Electrical Engineering, University of Notre Dame, Notre Dame, IN 46556, USA
3
Department of Materials Science and Engineering, University of Michigan, Ann Arbor, MI 48109, USA
4
School of Advanced Materials Sciences and Engineering, Sungkyunkwan University, Suwon 16419, Korea
5
School of Electrical Engineering, Korea University, Seoul 02841, Korea
*
Author to whom correspondence should be addressed.
Sensors 2022, 22(11), 4087; https://doi.org/10.3390/s22114087
Submission received: 13 April 2022
/
Revised: 20 May 2022
/
Accepted: 24 May 2022
/
Published: 27 May 2022
(This article belongs to the Special Issue Novel Design and Configuration of Optical/Acoustic/Ultrasonic/Pressure Sensor and Transducer)
Abstract
:The endurance characteristic of Zr-doped HfO2 (HZO)-based metal–ferroelectric–metal (MFM) capacitors fabricated under various deposition/annealing temperatures in the atomic layer deposition (ALD) process was investigated. The chamber temperature in the ALD process was set to 120 °C, 200 °C, or 250 °C, and the annealing temperature was set to 400 °C, 500 °C, 600 °C, or 700 °C. For the given annealing temperature of 700 °C, the remnant polarization (2Pr) was 17.21 µC/cm2, 26.37 µC/cm2, and 31.8 µC/cm2 at the chamber temperatures of 120 °C, 200 °C, and 250 °C, respectively. For the given/identical annealing temperature, the largest remnant polarization (Pr) was achieved when using the chamber temperature of 250 °C. At a higher annealing temperature, the grain size in the HZO layer becomes smaller, and thereby, it enables to boost up Pr. It was observed that the endurance characteristics for the capacitors fabricated under various annealing/chamber temperatures were quite different. The different endurance characteristics are due to the oxygen and oxygen vacancies in ferroelectric films, which affects the wakeup/fatigue behaviors. However, in common, all the capacitors showed no breakdown for an externally applied pulse (up to 108 cycles of the pulse).
1. Introduction
Ferroelectric materials have been widely used/adopted for various types of sensors and devices. Among various ferroelectric materials, HfO2-based ferroelectric devices have attracted great interest [1]. A HfO2-based ferroelectric film with fluorite structure solved the drawbacks in the conventional perovskite–structure ferroelectrics. They have extraordinary compatibility with complementary metal-oxide semiconductors (CMOS) and excellent ferroelectricity at ultra-thin (<10 nm) thickness [2,3]. The ferroelectric properties of HfO2-based film originated from the non-centrosymmetric orthorhombic phase (o-phase), and the stabilization of the o-phase enhances the ferroelectric behavior [4]. The ferroelectric phase can be stabilized through annealing, and it can be characterized differently by various factors, such as dopant, thickness of ferroelectric film, and deposition temperature [5,6].
Various dopants with HfO2 have been studied, and among them, zirconium (Zr) was chosen as the most promising material for memory and logic devices [6,7]. Unlike other dopants remaining stable at much lower concentration, Zr dopants can be stable with the same percentage as Hf in HZO film. Moreover, ferroelectric properties using Zr dopants can be obtained in much lower annealing temperature (TA) than other dopants.
As a memory device, the ferroelectric films require good endurance properties. The main factor affecting the endurance is the oxygen vacancy (VO) in ferroelectric films. During the electric field cycling, VO is redistributed, which results in the uniform distribution of VO in the bulk region of the ferroelectric layer [8]. This phenomenon increases the Pr value by decreasing the built-in field and then decreases the Pr value with additional cycling. This increase in Pr is called the “wake-up effect” and the decrease in Pr is called the “fatigue effect” [9,10]. The breakdown of the films is observed when VO forms a filament, which results as a leakage path. Therefore, it is very important to control the amount of VO for the reliability of memory devices.
The characteristics of ferroelectric films can vary through various methods such as adjusting the doping effect and the chamber temperature during ALD [11,12]. Adjusting the temperature of the chamber during ALD changes the deposition rate and the average grain size of the film [6,13]. These factors change the distribution of VO, which can significantly affect the ferroelectricity and the endurance properties. However, studies on the relationship of the effects of chamber temperature and the endurance performance are still lacking.
In this study, the ferroelectric properties of TiN/HZO/TiN capacitors with different chamber temperatures were investigated. The electrical characteristics of each capacitor were analyzed through polarization–voltage (P-V) curves and leakage current–voltage (I-V) curves. Moreover, the endurance performance related to the amount of VO was investigated under different chamber temperatures.
2. Fabrication
The illustrated cross-sectional view and fabrication flow of TiN/HZO/TiN capacitors are shown in Figure 1a,b, respectively. First, a p+-doped silicon wafer was cleaned by a SPM cleaning, which was followed by the conventional RCA method (i.e., SC-1 cleaning and SC-2 cleaning). Then, the 50 nm-thick TiN bottom electrode was deposited on the Si substrate by using DC sputtering. The 10 nm-thick HZO thin film was deposited by thermal atomic layer deposition (ALD). The tetrakis (ethylmethylamino) hafnium (TEMAH), tetrakis (ethylmethylamino) zirconium (TEMAZ), and H2O source precursor were used for the ALD process to deposit the HZO film. The Hf and Zr was deposited using an ALD supercycle [14]. The aforementioned fabrication was identically completed but at three different chamber temperatures (TCH) of 120 °C, 200 °C, and 250 °C. As shown in Figure 1c, the growth per (super)cycle of HZO film decreased as the chamber temperature (TCH) increased. The total number of supercycles to make 10 nm-thick HZO thin film was set to 56, 61, and 68 for TCH of 120 °C, 200 °C, and 250 °C, respectively. The 50 nm-thick TiN top electrode on the HZO layer was deposited using the DC sputtering used for bottom electrodes. Then, the HZO capacitors were patterned to have the electrode area of 6400 µm2. Finally, the post-metallization annealing (PMA) was completed by rapid thermal annealing (RTA) at 400, 500, 600, and 700 °C for 30 s in N2 atmosphere to crystallize the HZO films.
To investigate the electrical characteristics of HZO capacitors, P-V curves and I-V curves were measured using semiconductor parameter analyzer (Keithley 4200-SCS). The X-ray photoelectron spectroscopy (XPS), transmission electron microscopy (TEM), and energy-dispersive X-ray spectroscopy (EDS) were used to characterize the HZO capacitor.
3. Results and Discussion
3.1. Electrical Characteristics
Figure 2a–c show the measured P-V curves of the TiN/HZO/TiN capacitors with a few annealing temperatures (i.e., 400, 500, 600, and 700 °C) at TCH of 120 °C, 200 °C, and 250 °C, respectively. The measured Pr was increased at a higher TA for all the capacitors. This is mainly because the ratio of o-phase in the HZO layer was increased at the higher TA [2,10]. For a given TA, a higher Pr was implemented at a higher TCH. This achievement was physically originated from a few reasons, as follows: (1) The number of supercycles increases at a higher TCH because the deposition rate of HZO film is decreased at a higher TCH (see Figure 1c). This leads to increasing the number of HfO2/ZrO2 nanolaminates, resulting in the improved Pr [15]. (2) The average grain size of HZO film becomes smaller at a higher deposition temperature, if H2O is used as the oxygen source in ALD [13]. The smaller average grain size enables us to boost up the ferroelectric polarization [10,16]. This is primarily originated from the tetragonal phase (t-phase) and the orthorhombic phase (o-phase), which are easily stabilized in smaller grain regions. (3) Because defects (noted as VO) are likely to be accumulated along the grain boundaries, the smaller grain size is likely to build more grain boundaries for a given volume. This would distort the distribution of VO. Herein, it is noteworthy that the well-balanced distribution of VO in HZO films should help stabilize the ferroelectric phase, and thereby, the ferroelectric polarization would be enhanced [10,17].
In Figure 2d, the leakage current of TiN/HZO/TiN capacitors fabricated at different TA and TCH was measured. It turned out that for a given TCH (TA), the leakage current increases at a higher TA (TCH). In the MFM ferroelectric capacitor, the leakage current is mostly originated from VO (i.e., the higher VO is, the more the leakage current flows [15]). In Section 3.2, with TEM, XPS, and EDS data, it is investigated how VO is varied at different TCH.
3.2. XPS, TEM, and EDS
Figure 3 shows the XPS depth profile of the TiN/HZO/TiN capacitor at TA of 700 °C under three different TCH values. The atomic percent clearly reveals the TiN/HZO/TiN device structure. Among many atoms in the profile, the O 1s in the HZO layer is deconvoluted to figure out the oxygen bonds in great detail (see Figure 4). Notice that the intensities of each net peak were normalized to the same scale. The O 1s was divided into two peaks (i.e., lattice oxygen peak and sub-oxide peak). The lattice oxygen peak describes the bonds such as Hf-O and Zr-O, of which the binding energy is located in ≈532 eV. The sub-oxide peak indicates oxygen in a lattice, which does not contain its full complement of oxygen (and therefore, indicating the presence of vacancies). The peak describes the bonds such as oxygen interstitial and oxygen vacancy (VO), of which the binding energy locates at ≈534 eV.
The amount of O 1s in Figure 3 and Figure 4a confirms that there was a difference in the ratio of O 1s in HZO film, depending on three different TCH. The intensity of peak amplitude is decreased at a higher TCH. In addition, the atomic percent of Ti and N is decreased at a lower TCH (see Figure 3). In other words, the formation of the dead layer (i.e., TiO2 and TiON) between the HZO layer and the TiN electrode was suppressed at a lower TCH, which reduces the amount of VO in the HZO layer. It was confirmed that the ratio of VO increases if the dead layer between the HZO layer and the TiN electrode is formed [18].
It was observed that the percentage of sub-oxide bonding is increased at a higher TCH (see Figure 4a). This also indicates that the ratio of VO increases. In other words, the oxygen should move from the HZO layer to the electrodes to make the interfacial layer, and thereby, the VO in HZO film is increased [17]. Hence, the increased VO means that the larger amount of oxygen has moved toward the interfacial layer. In addition, in the XPS for Hf 4f spectra, it was confirmed that the sub-oxide means the oxygen vacancy in the HZO layer [19]. As shown in Figure 4b, it was observed that the ratio of sub-oxide in Hf 4f spectra is increased when TCH is increased, which leads to a higher VO. In summary, the ratio of oxygen in the HZO layer becomes smaller at a higher TCH, which is closely associate with the amount of VO. A higher TCH would make the ratio of VO higher. This is well agreed to the increase in leakage current at a higher TCH because of the increased VO (see Figure 2d).
Figure 5a–c show the TEM image of TiN/HZO/TiN capacitors fabricated at three different chamber temperatures (TCH) with TA of 500 °C. It was observed that the thicknesses of the HZO films were all the same: 10 nm. Figure 5d shows the EDS image of the TiN/HZO/TiN capacitor fabricated with TA of 700 °C. The ratio of elements in each layer can be determined through the EDS analysis (see Table 1). For example, the largest (smallest) atomic rate of oxygen in HZO films was implemented with TCH of 120 °C (250 °C), which was consistent with the XPS analysis. The amount of oxygen vacancy (VO) was increased, as the oxygen was decreased with increasing TCH. However, the discrepancy of the ratio of elements exists between the XPS and EDS analysis. Note that the purpose of the EDS analysis in this work was to confirm/verify the change of oxygen atoms.
3.3. Endurance
The endurance (especially, affected by an electric field cycling) in TiN/HZO/TiN capacitors was investigated. Figure 6 shows the pulsing scheme for evaluating the endurance of the capacitors. The electric field cycling was completed with using a trapezoidal pulse, and the number of cycling was applied up to 108. After the cycling pulses were applied, a triangular pulse was applied to measure the P-V characteristic of the capacitor. Note that both pulses have the same peak amplitude of 3 V. The P-V characteristic of each capacitor was compared to each other (see Figure 7).
The remnant polarization (Pr) of each HZO capacitor in pristine state is as follows: In case of TCH of 120 °C, Pr of 0.28 µC/cm2, 1.17 µC/cm2, 2.68 µC/cm2, and 17.21 µC/cm2 was observed for TA of 400 °C, 500 °C, 600 °C, and 700 °C, respectively. In case of TCH of 200 °C, Pr of 5.66 µC/cm2, 6.88 µC/cm2, 13.43 µC/cm2, and 26.37 µC/cm2 was observed for TA of 400 °C, 500 °C, 600 °C, and 700 °C, respectively. Finally, in case of TCH of 250 °C, Pr of 16.38 µC/cm2, 20.46 µC/cm2, 25.3 µC/cm2, and 31.8 µC/cm2 was observed for TA of 400 °C, 500 °C, 600 °C, and 700 °C, respectively. Regardless of TCH, it turned out that Pr was increased with increasing TA. For a given/identical TA, Pr can be improved with higher TCH. This is primarily because the amount of ferroelectric phase was increased with increasing either TA or TCH [2,9].
As shown in Figure 8, all the capacitors did not show any breakdown up to 108 cycles. However, depending on TCH, the number of cycles at which the fatigue begins (i.e., Pr is about to decrease) is varied. Regardless of TCH, higher Pr was observed with higher TA. This is primarily originated from a well-distributed VO in bulk region of HZO film at a higher TA [10].
It is known that the ferroelectric characteristics (notably, represented by Pr) can be improved as the number of cycles increases (a.k.a., wake-up effect). However, the ferroelectric characteristics should not be ever enhanced because of fatigue. The maximum value of 2Pr and the number of cycles at which fatigue begins (a.k.a. critical number of cycles) are summarized in Figure 9. It turned out that the value of 2Pr increases with increasing TA. (However, only for TCH of 120 °C, TA of 400 °C shows insufficient ferroelectricity, which results in a low 2Pr.) Compared to the other TCH of 200 °C and 250 °C, the measured Pr was significantly degraded for TCH of 120 °C. When H2O reactant is used as an oxygen source in ALD, the lowest TCH (i.e., 120 °C) forms the largest average grain size. This causes more formation of monoclinic phase (m-phase), which is non-ferroelectric phase, and it makes the depolarization field stronger [20,21]. Therefore, for TCH of 120 °C, the sudden decrease in Pr in the HZO capacitor was understood with less m-phase.
In Figure 9, it was also observed that the critical number of cycles (i.e., the number of cycles at which fatigue begins) decreases at a higher TCH for the same TA. As shown in Figure 2d and Figure 4, more VO in the ferroelectric layer was observed at a higher TCH, and thereby, so is the leakage current in HZO capacitor (this is because the excessive amount of VO makes undesirable conducting paths in the HZO film [10,22]). The more VO in the ferroelectric film should cause the ferroelectricity of the film to be fatigued at a rapid pace.
4. Conclusions
In this work, the impact of chamber/annealing temperatures in the atomic layer deposition (ALD) process on the ferroelectric property of the HZO layer in a TiN/HZO/TiN capacitor was investigated. Regardless of the chamber temperature (TCH), a higher remnant polarization (Pr) was achieved with a higher annealing temperature (TA). For a given TA, Pr was increased with increasing TCH. This ferroelectricity was well retained up to the cycles of 108. However, the capacitors fabricated under the three different TCH showed different endurance performances in terms of the critical number of cycles. This is due primarily to the oxygen and oxygen vacancies in the HZO layer (which was quantitatively analyzed and confirmed by XPS and EDS analysis). The more oxygen vacancies (VO) at a higher TCH enabled for Pr to be improved, but they made an undesirable conducting path in the HZO film, resulting in decreasing the critical number of cycles.
Author Contributions
Conceptualization, Y.C., J.S., S.M. and C.S.; Data curation, Y.C., C.H., J.S., S.M., J.M. and C.S.; Formal analysis, Y.C., C.H., S.M., H.P. and C.S.; Funding acquisition, C.S.; Investigation, Y.C., J.S., S.M. and J.M.; Methodology, Y.C., C.H., J.S., S.M., J.M., D.E. and J.L.; Project administration, C.S.; Resources, Y.C.; Supervision, C.S.; Validation, Y.C., J.S., S.M., J.M. and C.S.; Visualization, Y.C., C.H., J.S. and C.S.; Writing—Original draft, Y.C. and C.S.; Writing—Review and editing, C.S., Y.C., C.H., J.S., S.M. and J.M. equally contributed to this work. All authors have read and agreed to the published version of the manuscript.
Funding
This work was funded by a National Research Foundation of Korea (NRF) grant funded by the Korean government (MSIP) (No. 2020R1A2C1009063, 2020M3F3A2A01082326, 2020M3F3A2A01081672 and 2020M3F3A2A02082436).
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
The data presented in this study are available on request from the corresponding author.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
(a) Illustrated cross-sectional view of the fabricated TiN/HZO/TiN capacitor, and (b) its fabrication process flow. The HZO layer were deposited under three different temperatures in chamber, i.e., 120 °C, 200 °C, and 250 °C. (c) Growth per cycle of HZO film for three different chamber temperatures. Note that the growth per cycle is decreased with increasing the chamber temperature, which is due primarily to the decreasing contribution of surface exchange reaction [13].
Figure 1.
(a) Illustrated cross-sectional view of the fabricated TiN/HZO/TiN capacitor, and (b) its fabrication process flow. The HZO layer were deposited under three different temperatures in chamber, i.e., 120 °C, 200 °C, and 250 °C. (c) Growth per cycle of HZO film for three different chamber temperatures. Note that the growth per cycle is decreased with increasing the chamber temperature, which is due primarily to the decreasing contribution of surface exchange reaction [13].
Figure 2.
Measured polarization vs. electric field of TiN/HZO/TiN capacitor in which the HZO layer was deposited at the chamber temperature of (a) 120 °C, (b) 200 °C, and (c) 250 °C. Note that four different annealing temperatures (TA = 400~700 °C) were used for better implementing the ferroelectric characteristics of the HZO layer. (d) Measured leakage current-vs.-annealing temperature for three different chamber temperatures. Note that the leakage current was measured with the voltage of −3 V across the ferroelectric capacitor.
Figure 2.
Measured polarization vs. electric field of TiN/HZO/TiN capacitor in which the HZO layer was deposited at the chamber temperature of (a) 120 °C, (b) 200 °C, and (c) 250 °C. Note that four different annealing temperatures (TA = 400~700 °C) were used for better implementing the ferroelectric characteristics of the HZO layer. (d) Measured leakage current-vs.-annealing temperature for three different chamber temperatures. Note that the leakage current was measured with the voltage of −3 V across the ferroelectric capacitor.
Figure 3.
Measured XPS depth profiles of TiN (50 nm)/HZO (10 nm)/TiN (50nm) capacitor, which was fabricated at three different chamber temperatures: (a) 120 °C, (b) 200 °C, and (c) 250 °C.
Figure 3.
Measured XPS depth profiles of TiN (50 nm)/HZO (10 nm)/TiN (50nm) capacitor, which was fabricated at three different chamber temperatures: (a) 120 °C, (b) 200 °C, and (c) 250 °C.
Figure 4.
Measured (a) XPS O 1s spectra and (b) XPS Hf 4f spectra of the HZO film in TiN/HZO/TiN capacitor, which was fabricated at three different chamber temperatures (i.e., 120 °C, 200 °C and 250 °C). The O 1s levels were deconvoluted into two peaks, i.e., lattice oxygen peak and sub-oxide peak. The Hf 4f levels were deconvoluted into five peaks, i.e., HfO2 peaks, sub-oxide peaks, and O 2s peak. Each intensity level was normalized to the same scale.
Figure 4.
Measured (a) XPS O 1s spectra and (b) XPS Hf 4f spectra of the HZO film in TiN/HZO/TiN capacitor, which was fabricated at three different chamber temperatures (i.e., 120 °C, 200 °C and 250 °C). The O 1s levels were deconvoluted into two peaks, i.e., lattice oxygen peak and sub-oxide peak. The Hf 4f levels were deconvoluted into five peaks, i.e., HfO2 peaks, sub-oxide peaks, and O 2s peak. Each intensity level was normalized to the same scale.
Figure 5.
The transmission electron microscopy (TEM) image of the TiN/HZO/TiN capacitor, which was fabricated at three different chamber temperatures: (a) 120 °C, (b) 200 °C, and (c) 250 °C. (d) The energy-dispersive spectroscopy (EDS) images for titanium, hafnium, zirconium, and oxygen in the HZO capacitor at the chamber temperature of 250 °C.
Figure 5.
The transmission electron microscopy (TEM) image of the TiN/HZO/TiN capacitor, which was fabricated at three different chamber temperatures: (a) 120 °C, (b) 200 °C, and (c) 250 °C. (d) The energy-dispersive spectroscopy (EDS) images for titanium, hafnium, zirconium, and oxygen in the HZO capacitor at the chamber temperature of 250 °C.
Figure 6.
Illustrated pulsing scheme for analyzing the wake−up and fatigue behaviors of TiN/HZO/TiN capacitor. The cycling was first completed using the trapezoidal pulse with the ramp time (Tramp) of 1 µs and the hold time (Thold) of 1 µs. Afterwards, the P-V measurement was made using the triangular pulse. Note that the amplitude for both pulses is set to 3 V.
Figure 6.
Illustrated pulsing scheme for analyzing the wake−up and fatigue behaviors of TiN/HZO/TiN capacitor. The cycling was first completed using the trapezoidal pulse with the ramp time (Tramp) of 1 µs and the hold time (Thold) of 1 µs. Afterwards, the P-V measurement was made using the triangular pulse. Note that the amplitude for both pulses is set to 3 V.
Figure 7.
Measured polarization vs. electric field (PE) characteristics of TiN/HZO/TiN capacitors fabricated at various chamber temperatures (i.e., 120 °C, 200 °C, and 250 °C) as well as at various annealing temperatures (TA): (a) 400 °C, (b) 500 °C, (c) 600 °C, and (d) 700 °C. Note that the different numbers of cycles were used to explore the endurance characteristics of the ferroelectric capacitor.
Figure 7.
Measured polarization vs. electric field (PE) characteristics of TiN/HZO/TiN capacitors fabricated at various chamber temperatures (i.e., 120 °C, 200 °C, and 250 °C) as well as at various annealing temperatures (TA): (a) 400 °C, (b) 500 °C, (c) 600 °C, and (d) 700 °C. Note that the different numbers of cycles were used to explore the endurance characteristics of the ferroelectric capacitor.
Figure 8.
Measured representative ferroelectric characteristics (i.e., remnant polarization (2Pr) and/or coercive electric field (2Ec)) versus cycles, for given three different chamber temperatures, (a,d) 120 °C, (b,e) 200 °C, and (c,f) 250 °C with four different annealing temperatures (TA from 400 °C to 700 °C). The yellow−colored circle indicates the max point of 2Pr.
Figure 8.
Measured representative ferroelectric characteristics (i.e., remnant polarization (2Pr) and/or coercive electric field (2Ec)) versus cycles, for given three different chamber temperatures, (a,d) 120 °C, (b,e) 200 °C, and (c,f) 250 °C with four different annealing temperatures (TA from 400 °C to 700 °C). The yellow−colored circle indicates the max point of 2Pr.
Figure 9.
(a) Maximum remnant polarization (2Pr) and (b) critical number of cycles at which fatigue begins for given three different chamber temperatures, 120 °C, 200 °C, and 250 °C, with four different annealing temperatures (TA from 400 °C to 700 °C).
Figure 9.
(a) Maximum remnant polarization (2Pr) and (b) critical number of cycles at which fatigue begins for given three different chamber temperatures, 120 °C, 200 °C, and 250 °C, with four different annealing temperatures (TA from 400 °C to 700 °C).
Table 1.
Energy-dispersive spectrometer (EDS) quantification of elements in HZO layer.
| Chamber Temperature (TCH) (°C) | Atomic Percent (%) | |||||
|---|---|---|---|---|---|---|
| Ti | N | Hf | Zr | O | Si | |
| 120 | 4.50 | 9.76 | 20.90 | 18.16 | 30.44 | 16.24 |
| 200 | 9.20 | 4.49 | 24.95 | 21.00 | 23.32 | 17.03 |
| 250 | 10.74 | 10.80 | 24.75 | 21.18 | 19.38 | 13.15 |
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Choi, Y.; Han, C.; Shin, J.; Moon, S.; Min, J.; Park, H.; Eom, D.; Lee, J.; Shin, C. Impact of Chamber/Annealing Temperature on the Endurance Characteristic of Zr:HfO2 Ferroelectric Capacitor. Sensors 2022, 22, 4087. https://doi.org/10.3390/s22114087
AMA Style
Choi Y, Han C, Shin J, Moon S, Min J, Park H, Eom D, Lee J, Shin C. Impact of Chamber/Annealing Temperature on the Endurance Characteristic of Zr:HfO2 Ferroelectric Capacitor. Sensors. 2022; 22(11):4087. https://doi.org/10.3390/s22114087
Chicago/Turabian StyleChoi, Yejoo, Changwoo Han, Jaemin Shin, Seungjun Moon, Jinhong Min, Hyeonjung Park, Deokjoon Eom, Jehoon Lee, and Changhwan Shin. 2022. "Impact of Chamber/Annealing Temperature on the Endurance Characteristic of Zr:HfO2 Ferroelectric Capacitor" Sensors 22, no. 11: 4087. https://doi.org/10.3390/s22114087
APA StyleChoi, Y., Han, C., Shin, J., Moon, S., Min, J., Park, H., Eom, D., Lee, J., & Shin, C. (2022). Impact of Chamber/Annealing Temperature on the Endurance Characteristic of Zr:HfO2 Ferroelectric Capacitor. Sensors, 22(11), 4087. https://doi.org/10.3390/s22114087
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