HfO<sub>2</sub>基铁电薄膜的结构、性能调控及典型器件应用

袁国亮; 王琛皓; 唐文彬; 张睿; 陆旭兵

doi:10.7498/aps.72.20222221

摘要

大数据、物联网和人工智能的快速发展对存储芯片、逻辑芯片和其他电子元器件的性能提出了越来越高的要求. 本文介绍了HfO₂基铁电薄膜的铁电性起源, 通过掺杂元素改变晶体结构的对称性或引入适量的氧空位来降低相转变的能垒可以增强HfO₂基薄膜的铁电性, 在衬底和电极之间引入应力、减小薄膜厚度、构建纳米层结构和降低退火温度等方法也可以稳定铁电相. 与钙钛矿氧化物铁电薄膜相比, HfO₂基铁电薄膜具有与现有半导体工艺兼容性更强和在纳米级厚度下铁电性强等优点. 铁电存储器件理论上可以达到闪存的存储密度, 读写次数超过10¹⁰次, 同时具有读写速度快、低操作电压和低功耗等优点. 此外, 还总结了HfO₂基薄膜在负电容晶体管、铁电隧道结、神经形态计算和反铁电储能等方面的主要研究成果. 最后, 讨论了HfO₂基铁电薄膜器件当前面临的挑战和未来的机遇.

关键词:

Abstract

The rapid developments of big data, the internet of things, and artificial intelligence have put forward more and more requirements for memory chips, logic chips and other electronic components. This study introduces the ferroelectric origin of HfO₂-based ferroelectric film and explains how element doping, defects, stresses, surfaces and interfaces, regulate and enhance the ferroelectric polarization of the film. It is widely accepted that the ferroelectricity of HfO₂-based ferroelectric film originates from the metastable tetragonal phase. The ferroelectricity of the HfO₂-based film can be enhanced by doping some elements such as Zr, Si, Al, Gd, La, and Ta, thereby affecting the crystal structure symmetry. The introduction of an appropriate number of oxygen vacancy defects can reduce the potential barrier of phase transition between the tetragonal phase and the monoclinic phase, making the monoclinic phase easy to transition to tetragonal ferroelectric phase. The stability of the ferroelectric phase can be improved by some methods, including forming the stress between the substrate and electrode, reducing the film thickness, constructing a nanolayered structure, and reducing the annealing temperature. Compared with perovskite oxide ferroelectric thin films, HfO₂-based films have the advantages of good complementary-metal-oxide-semiconductor compatibility and strong ferroelectricity at nanometer thickness, so they are expected to be used in ferroelectric memory. The HfO₂-based 1T1C memory has the advantages of fast reading and writing speed, more than reading and writing 10¹² times, and high storage density, and it is the fast reading and writing speed that the only commercial ferroelectric memory possesses at present. The 1T ferroelectric field effect transistor memory has the advantages of non-destructive reading and high storage density. Theoretically, these memories can achieve the same storage density as flash memory, more than reading 10¹⁰ times, the fast reading/writing speed, low operating voltage, and low power consumption, simultaneously. Besides, ferroelectric negative capacitance transistor can obtain a subthreshold swing lower than 60 mV/dec, which greatly reduces the power consumption of integrated circuits and provides an excellent solution for further reducing the size of transistors. Ferroelectric tunnel junction has the advantages of small size and easy integration since the tunneling current can be largely adjusted through ferroelectric polarization switching. In addition, the HfO₂-based field effect transistors can be used to simulate biological synapses for applications in neural morphology calculations. Moreover, the HfO₂-based films also have broad application prospects in antiferroelectric energy storage, capacitor dielectric energy storage, memristor, piezoelectric, and pyroelectric devices, etc. Finally, the current challenges and future opportunities of the HfO₂-based thin films and devices are analyzed.

Keywords:

作者及机构信息

1.
南京理工大学材料科学与工程学院, 南京　210094

2.
华南师范大学华南先进光电子研究院, 广州　510006

通信作者: 袁国亮, yuanguoliang@njust.edu.cn ; 陆旭兵, luxubing@m.scnu.edu.cn

基金项目: 国家自然科学基金(批准号: 92263105, 62174059)和中央高校基本科研业务费专项资金(批准号: 30921013108)资助的课题.

Authors and contacts

1.
School of Material Science and Engineering, Nanjing University of Science and Technology, Nanjing 210094, China

2.
South China Academy of Advanced Optoelectronics, South China Normal University, Guangzhou 510006, China

Corresponding author: Yuan Guo-Liang, yuanguoliang@njust.edu.cn ; Lu Xu-Bing, luxubing@m.scnu.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 92263105, 62174059) and the Fundamental Research Funds for the Central Universities, China (Grant No. 30921013108).

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参考文献

[1]	McAdams H P, Acklin K, Blake T, Du X H, Eliason J, Fong J, Kraus W F, Liu D, Madan S, Moise T, Natarajan S, Qian N, Qiu Y C, Remack K A, Rodriguez J, Roscher J, Seshadri A, Summerfelt S R 2004 IEEE J. Solid-St. Circ. 39 667 Google Scholar
[2]	Krupanidhi S B, Maffei N, Sayer M, ElAssal K 1983 J. Appl. Phys. 54 6601 Google Scholar
[3]	Eaton S, Butler D, Parris M, Wilson D, McNeille H 1988 ISSCC Dig. Techn. Papers p130
[4]	Setter N, Damjanovic D, L Eng, Fox G, Gevorgian S, Hong S, Kingon A, Kohlstedt H, Park N Y, Stephenson G B, Stolitchnov I, Taganstev A K, Taylor D V, Yamada T, Streiffer S 2006 J. Appl. Phys. 100 051606 Google Scholar
[5]	Choi S H, Ko H Y, Heo J E, Son Y H, Bae B J, Yoo D C, Im D H, Jung Y J, Byun K R, Hahm J H, Shin S H, Yoon B U, Hong C K, Cho H K, Moon J T 2006 Integr. Ferroelectr. 84 147 Google Scholar
[6]	Park M H, Lee Y H, Kim H J, Kim Y J, Moon T, Kim K D, Muller J, Kersch A, Schroeder U, Mikolajick T, Hwang C S 2015 Adv. Mater. 27 1811 Google Scholar
[7]	Müller J, Polakowski P, Mueller S, Mikolajick T, 2015 ECS J. Solid State Sci. Technol. 4 N30 Google Scholar
[8]	Böscke T S, Müller J, Bräuhaus D, Schröder U, Böttger U 2011 Appl. Phys. Lett. 99 102903 Google Scholar
[9]	Robertson J, Falabretti B 2006 J. Appl. Phys. 100 014111 Google Scholar
[10]	Fischer D, Kersch A 2008 Appl. Phys. Lett. 92 012908 Google Scholar
[11]	Robertson J 2004 Eur. Phys. J. Appl. Phys. 28 265 Google Scholar
[12]	Kim S J, Mohan J, Kim H S, Hwang S M, Kim N, Jung Y C, Sahota A, Kim K, Yu H Y, Cha P R, Young C D, Choi R, Ahn J, Kim J 2020 Materials 13 2968 Google Scholar
[13]	Min H P, Kim H J, Kim Y J, Moon T, Hwang C S 2014 Appl. Phys. Lett. 104 072901 Google Scholar
[14]	Polakowski P, Müller J 2015 Appl. Phys. Lett. 106 232905 Google Scholar
[15]	Starschich S, Griesche D, Schneller T, Waser R, Böttger U 2014 Appl. Phys. Lett. 104 202903 Google Scholar
[16]	Shimizu T, Katayama K, Kiguchi T, Akama A, Konno T J, Funakubo H 2015 Appl. Phys. Lett. 107 032910 Google Scholar
[17]	Shimizu T, Katayama K, Kiguchi T, Akama A, Konno T J, Sakata O, Funakubo H 2016 Sci. Rep. 6 32931 Google Scholar
[18]	Schroeder U, Yurchuk E, Müller J, Martin D, Schenk T, Polakowski P, Adelmann C, Popovici M I, Kalinin S V, Mikolajick T 2014 Jpn. J. Appl. Phys. 53 08LE02 Google Scholar
[19]	Müller J, Böscke T S, Schröder U, Mueller S, Bräuhaus D, Böttger U, Frey L, Mikolajick T 2012 Nano Lett. 12 4318 Google Scholar
[20]	Mueller S, Mueller J, Singh A, Riedel S, Sundqvist J, Schroeder U, Mikolajick T 2012 Adv. Funct. Mater. 22 2412 Google Scholar
[21]	Park M H, Kim H J, Kim Y J, Moon T, Kim K D, Hwang C S 2015 Nano Energy 12 131 Google Scholar
[22]	Park M H, Kim H J, Kim Y J, Moon T, Kim K D, Hwang C S 2014 Adv. Energy Mater. 4 1400610 Google Scholar
[23]	Kirbach S, Lederer M, Eßlinger S, Mart C, Czernohorsky M, Weinreich W, Wallmersperger T 2021 Appl. Phys. Lett. 118 012904 Google Scholar
[24]	Materlik R, Küenneth C, Kersch A 2015 J. Appl. Phys. 117 134109 Google Scholar
[25]	Ohtaka O, Fukui H, Kunisada T, Fujisawa T, Funakoshi K, Utsumi W, Irifune T, Kuroda K, Kikegawa T 2001 J. Am. Ceram. Soc. 84 1369 Google Scholar
[26]	Wei Y F, Nukala P, Salverda M, Matzen S, Zhao H J, Momand J, Everhardt A S, Agnus G, Blake G R, Lecoeur P, Kooi B J, Íñiguez J, Dkhil B, Noheda B 2018 Nat. Mater. 17 1095 Google Scholar
[27]	Kisi E H, 1998 J. Am. Ceram. Soc. 81 741 Google Scholar
[28]	Müller J, Schröder U, Böscke T S, Müller I, Böttger U, Wilde L, Sundqvist J, Lemberger M, Kucher P, Mikolajick T, Frey L 2011 J. Appl. Phys. 110 114113 Google Scholar
[29]	Huan T D, Sharma V, Rossetti G A, Jr, Ramprasad R 2014 Phys. Rev. B 90 064111 Google Scholar
[30]	Nukala P, Antoja-Lleonart J, Wei Y F, Yedra L, Dkhil B, Noheda B 2019 ACS Appl. Electron. Mater. 1 2585 Google Scholar
[31]	Park M H, Lee Y H, Kim H J, Schenk T, Lee W, Kim K D, Fengler F P G, Mikolajick T, Schroeder U, Hwang C S 2017 Nanoscale 9 9973 Google Scholar
[32]	Batra R, Huan T D, Jones J L, Rossetti G, Ramprasad R 2017 J. Phys. Chem. C 121 4139 Google Scholar
[33]	Park M H, Lee Y H, Mikolajick T, Schroeder U, Hwang C S 2019 Adv. Electron. Mater. 5 1800522 Google Scholar
[34]	Park M H, Lee Y H, Kim H J, Kim Y J, Moon T, Kim K D, Hyun S D, Mikolajick T, Schroeder U, Hwang C S 2018 Nanoscale 10 716 Google Scholar
[35]	Lee Y H, Hyun S D, Kim H J, Kim J S, Yoo C, Moon T, Kim K D, Park H W, Lee Y B, Kim B S, Roh J, Park M H, Hwang C S 2019 Adv. Electron. Mater. 5 1800436 Google Scholar
[36]	Mimura T, Shimizu T, Kiguchi T, Akama A, Konno T J, Katsuya Y, Sakata O, Funakubo H 2019 Jpn. J. Appl. Phys. 58 SBBB09 Google Scholar
[37]	Martin D, Yurchuk E, Müller S, Müller J, Paul J, Sundquist J, Slesazeck S, Schlöesser T, Bentum R V, Trentzsch M, Schröder U, Mikolajick T 2013 Solid-State Electron. 88 65 Google Scholar
[38]	Kashir A, Kim H, Oh S, Hwang H 2021 ACS Appl. Electron. Mater. 3 629 Google Scholar
[39]	Hoffmann M, Schroeder U, Schenk T, Shimizu T, Funakubo H, Sakata O, Pohl D, Drescher M, Adelmann C, Materlik R, Kersch A, Mikolajick T 2015 J. Appl. Phys. 118 072006 Google Scholar
[40]	Ku B, Choi S, Song Y, Choi C 2020 IEEE Symposium on VLSI Technology Honolulu, HI, USA, June 15-19, 2020 p1
[41]	Schroeder U, Richter C, Park M H, Schenk T, Pesic M, Hoffmann M, Fengler F P G, Pohl D, Rellinghaus B, Zhou C Z, Chung C C, Jones J L, Mikolajick T 2018 Inorg. Chem. 57 2752 Google Scholar
[42]	Schenk T, Mueller S, Schroeder U, Materlik R, Kersch A, Popovici M, Adelmann C, Elshocht S V, Mikolajick T 2013 Proceedings of the European Solid-State Device Research Conference (ESSDERC) Bucharest, Romania, September 16-20, 2013 p260
[43]	Luo C Q, Kang C Y, Song Y L, Wang W P, Zhang W F 2021 Appl. Phys. Lett. 119 042902 Google Scholar
[44]	Luo J D, Lai Y Y, Hsiang K Y, Wu C F, Yeh Y T, Chung H T, Li YS, Chuang K C, Li WS, Liao C Y, Chen P G, Chen K N, Cheng H C 2021 IEEE T. Electron Dev. 68 1374 Google Scholar
[45]	Liu Y J, Song S J, Gong P, Xu L J, Li K F, Tang X B, Li W W, Yang H 2022 Appl. Phys. Lett. 121 122902 Google Scholar
[46]	Jin L H, Tang X W, Song D P, Wei R H, Yang J, Dai J M, Song W H, Zhu X B, Suna Y P 2015 J. Mater. Chem. C 3 10742 Google Scholar
[47]	Park M H, Lee Y H, Kim H J, Kim Y J, Moon T, Kim K D, Hyun S D, Hwang C S 2018 ACS Appl. Mater. Inter. 10 42666 Google Scholar
[48]	Li T, Dong J C, Zhange N, Wen Z C, Suna Z Z, Hai Y, Wang K W, Liu H Y, Tamura N, Mi S B, Cheng S D, Ma C S, He Y B, Li L, Ke S M, Huang H T, Cao Y G 2021 Acta Mater. 207 116696 Google Scholar
[49]	Lomenzo P D, Jachalke S, Stoecker H, Mehner E, Richter C, Mikolajick T, Schroeder U 2020 Nano Energy 74 104733 Google Scholar
[50]	Martin D, Müller J, Schenk T, Arruda T M, Kumar A, Strelcov E, Yurchuk E, Müller S, Pohl D, Schröder U, Kalinin S V, Mikolajick T 2014 Adv. Mater. 26 8198 Google Scholar
[51]	Yurchuk E, Müller J, Knebel S, Sundqvist J, Graham A P, Melde T, Schröder U, Mikolajick T 2013 Thin Solid Films 533 88 Google Scholar
[52]	Materlik R, Künneth C, Falkowski M, Mikolajick T, Kersch A 2018 J. Appl. Phys. 123 164101 Google Scholar
[53]	Kozodaev M G, Chernikova A G, Korostylev E V, Park M H, Khakimov R R, Hwang C S, Markeev A M 2019 J. Appl. Phys. 125 034101 Google Scholar
[54]	Kozodaev M G, Chernikova A G, Khakimov R R, Park M H, Markeev A M, Hwang C S 2018 Appl. Phys. Lett. 113 123902 Google Scholar
[55]	Hoffmann M, Schroeder U, Künneth C, Kersch A, Starschich S, Böttger U, Mikolajick T 2015 Nano Energy 18 154 Google Scholar
[56]	Lomenzo P D, Zhao P, Takmeel Q, Moghaddam S, Nishida T, Nelson M, Fancher C M, Grimley E D, Sang X, LeBeau J M, Jones J L 2014 J. Vac. Sci. Technol. B 32 03d123 Google Scholar
[57]	Lee C K, Cho E, Lee H S, Hwang C S, Han S 2008 Phys. Rev. B 78 012102 Google Scholar
[58]	Park M H, Schenk T, Fancher C M, Grimley E D, Zhou C, Richter C, LeBeau J M, Jones J L, Mikolajick T, Schroeder U 2017 J. Mater. Chem. C 5 4677 Google Scholar
[59]	Starschich S, Boettger U 2017 J. Mater. Chem. C 5 333 Google Scholar
[60]	Yao Y F, Zhou D Y, Li S D, Wang J J, Sun N N, Liu F, Zhao X M 2019 J. Appl. Phys. 126 154103 Google Scholar
[61]	Mueller S, Adelmann C, Singh A, Elshocht S Van, Schroeder U, Mikolajick T 2012 ECS J. Solid State Sci. Technol. 1 N123 Google Scholar
[62]	Schroeder U, Mueller S, Mueller J, Yurchuk E, Martin D, Adelmann C, Schloesser T, Bentum R V, Mikolajick T 2013 ECS J. Solid State Sci. Technol. 2 N69 Google Scholar
[63]	Tromm T C U, Zhang J, Schubert J, Luysberg M, Zander W, Han Q, Meuffels P, Meertens D, Glass S, Bernardy P, Mantl S 2017 Appl. Phys. Lett. 111 142904 Google Scholar
[64]	Luo J D, Yeh Y T, Lai Y Y, Wu C F, Chung H T, Li Y S, Chuang K C, Li W S, Chen P G, Lee M H, Cheng H C 2020 Vacuum 176 109317 Google Scholar
[65]	Kim K D, Park M H, Kim H J, Kim Y J, Moon T, Lee Y H, Hyun S D, Gwon T, Hwang C S 2016 J. Mater. Chem. C 4 6864 Google Scholar
[66]	Park M H, Kim H J, Kim Y J, Lee W, Kim H K, C S Hwang 2013 Appl. Phys. Lett. 102 112914 Google Scholar
[67]	Oh S, Song J, Yoo I K, Hwang H 2019 IEEE Electr. Device L. 40 1092 Google Scholar
[68]	Zhou Y, Zhang Y K, Yang Q, Jiang J, Fan P, Liao M, Zhou Y C 2019 Comp. Mater. Sci. 167 143 Google Scholar
[69]	Xu L, Nishimura T, Shibayama S, Yajima T, Migita S, Toriumi A 2016 Appl. Phys. Express 9 091501 Google Scholar
[70]	Wang J, Li H P, Stevens R 1992 J. Mater. Sci. 27 5397 Google Scholar
[71]	Kim S J, Narayan D, Lee J G, Mohan J, Lee J S, Lee J, Kim H S, Byun Y C, Lucero A T, Young C D, Summerfelt S R, San T, Colombo L, Kim J 2017 Appl. Phys. Lett. 111 242901 Google Scholar
[72]	Lomenzo P D, Takmeel Q, Zhou C Z, Fancher C M, Lambers E, Rudawski N G, Jones J L, Moghaddam S, Nishida T 2015 J. Appl. Phys. 117 134105 Google Scholar
[73]	Karbasian G, Reis R D, Yadav A K, Tan A J, Hu C M, Salahuddin S 2017 Appl. Phys. Lett. 111 022907 Google Scholar
[74]	Lee Y, Goh Y, Hwang J, Das D, Jeon S 2021 IEEE Trans. Electr. Dev. 68 523 Google Scholar
[75]	Cao R R, Wang Y, Zhao S J, Yang Y, Zhao X L, Wang W, Zhang X M, Lv H B, Liu Q, Liu M 2018 IEEE Electr. Device L. 39 1207 Google Scholar
[76]	Zhang Y, Fan Z, Wang D, Wang J L, Zou Z M, Li Y S, Li Q, Tao R Q, Chen D Y, Zeng M, Gao X S, Dai J Y, Zhou G F, Lu X B, J M Liu 2020 ACS Appl. Mater. Inter. 12 40510 Google Scholar
[77]	Goh Y, Cho S H, Park S H K, Jeon S 2020 Nanoscale 12 9024 Google Scholar
[78]	Zhang Z M, Hsu S L, Stoica V A, Paik H, Parsonnet E, Qualls A, Wang J J, Xie L, Kumari M, Das S, Leng Z N, McBriarty M, Proksch R, Gruverman A, Schlom D G, Chen L Q, Salahuddin S, Martin L W, Ramesh R 2021 Adv. Mater. 33 2006089 Google Scholar
[79]	Shiraishi T, Katayama K, Yokouchi T, Shimizu T, Oikawa T, Sakata O, Uchida H, Imai Y, Kiguchi T, Konno T J, Funakubo H 2016 Appl. Phys. Lett. 108 262904 Google Scholar
[80]	Li T, Zhang N, Sun Z Z, Xie C X, Ye M, Mazumdar S, Shu L, Wang Y, Wang D Y, Chen L, Ke S, Huang H 2018 J. Mater. Chem. C 6 9224 Google Scholar
[81]	Katayama K, Shimizu T, Sakata O, Shiraishi T, Nakamura S, Kiguchi T, Akama A, Konno T J, Uchida H, Funakubo H 2016 Appl. Phys. Lett. 109 112901 Google Scholar
[82]	Song T F, Bachelet R, Saint-Girons G, Solanas R, Fina I, Sánchez F 2020 ACS Appl. Electron. Mater. 2 3221 Google Scholar
[83]	Estandia S, Dix N, Chisholm M F, Fina I, Sánchez F 2020 Cryst. Growth Des. 20 3801 Google Scholar
[84]	Li T, Ye M, Sun Z Z, Zhang N, Zhang W, Inguva S, Xie C X, Chen L, Wang Y, Ke S M, Huang H T 2019 ACS Appl. Mater. Inter. 11 4139 Google Scholar
[85]	Zhou H, Wu L J, Wang H Q, Zheng J C, Zhang L H, Kisslinger K, Li Y P, Wang Z Q, Cheng H, Ke S M, Li Y, Kang J Y, Zhu Y M 2017 Nat. Commun. 8 1474 Google Scholar
[86]	Lyu J, Fina I, Solanas R, Fontcuberta J, Sánchez F 2018 Appl. Phys. Lett. 113 082902 Google Scholar
[87]	Lyu J, Fina I, Bachelet R, Saint-Girons G, Estandía S, Gázquez J, Fontcuberta J, Sánchez F 2019 Appl. Phys. Lett. 114 222901 Google Scholar
[88]	Cheema S S, Kwon D, Shanker N, Reis R D, Hsu S L, Xiao J, Zhang H G, Wagner R, Datar A, McCarter M R, Serrao C R, Yadav A K, Karbasian G, Hsu C H, Tan A J, Wang L C, Thakare V, Zhang X, Mehta A, Karapetrova E, Chopdekar R V, Shafer P, Arenholz E, Hu C, Proksch R, Ramesh R, Ciston J, Salahuddin S 2020 Nature 580 478 Google Scholar
[89]	Xu X H, Huang F T, Qi Y B, Singh S, Rabe K M, Obeysekera D, Yang J J, Chu M W, Cheong S W 2021 Nat. Mater. 20 826 Google Scholar
[90]	Estandía S, Dix N, Gazquez J, Fina I, Lyu J, Chisholm M F, Fontcuberta J, Sánchez F 2019 ACS Appl. Electron Mater. 1 1449 Google Scholar
[91]	Lyu J, Fina I, Fontcuberta J, Sanchez F 2019 ACS Appl. Mater. Inter. 11 6224 Google Scholar
[92]	Park M H, Kim H J, Kim Y J, Lee W, Moon T, Kim K D, Hwang C S 2014 Appl. Phys. Lett. 105 072902 Google Scholar
[93]	Yan Y, Zhou D Y, Guo C X, Xu J, Yang X R, Liang H L, Zhou F Y, Chu S C, Liu X Y 2016 J. Sol-Gel Sci. Technol. 7 430 Google Scholar
[94]	Chernikova A G, Kuzmichev D S, Negrov D V, Kozodaev M G, Polyakov S N, Markeev A M 2016 Appl. Phys. Lett. 108 242905 Google Scholar
[95]	Mittmann T, Materano M, Lomenzo P D, Park M H, Stolichnov I, Cavalieri M, Zhou C Z, Chung C C, Jones J L, Szyjka T, Müller M, Kersch A, Mikolajick T, Schroeder U 2019 Adv. Mater. Inter. 6 1900042 Google Scholar
[96]	Liao J J, Zeng B J, Sun Q, Chen Q, Liao M, Qiu C G, Zhang Z Y, Zhou Y C 2019 IEEE Electr. Device L. 40 1868 Google Scholar
[97]	Migita S, Ota H, Asanuma S, Morita Y, Toriumi A 2021 Appl. Phys. Express 14 051006 Google Scholar
[98]	Chen Y H, Wang L, Liu L Y, Tang L, Yuan X, Chen H Y, Zhou K C, Zhang D 2021 J. Mater. Sci. 56 6064 Google Scholar
[99]	Shin H W, Son J Y 2020 Appl. Phys. Lett. 117 202902 Google Scholar
[100]	Chen Q, Zhang Y K, Liu W Y, Jiang J, Yang Q, Jiang L M 2021 Int. J. Mech. Sci. 212 106828 Google Scholar
[101]	Kim H J, Park M H, Kim Y J, Lee Y H, Jeon W, Gwon T, Moon T, Kim K D, Hwang C S 2014 Appl. Phys. Lett. 105 192903 Google Scholar
[102]	Nakayama S, Funakubo H, Uchida H 2018 Jpn. J. Appl. Phys. 57 11UF06 Google Scholar
[103]	Chen H Y, Chen Y H, Tang L, Luo H, Zhou K C, Yuan X, Zhang D 2020 J. Mater. Chem. C 8 2820 Google Scholar
[104]	Tang L, Chen C, Wei A Q, Li K, Zhang D, Zhou K C 2019 Ceram. Int. 45 3140 Google Scholar
[105]	Liu H, Zheng S Z, Chen Q, Zeng B J, Jiang J, Peng Q X, Liao M, Zhou Y C 2019 J. Mater. Sci. :Mater. Electron. 30 5771 Google Scholar
[106]	Wang X X, Zhou D Y, Li S D, Liu X H, Zhao P, Sun N N, Ali F, Wang J J 2018 Ceram. Int. 44 13867 Google Scholar
[107]	Weeks S L, Pal A, Narasimhan V K, Littau K A, Chiang T 2017 ACS Appl. Mater. Inter. 9 13440 Google Scholar
[108]	Park M H, Kim H J, Lee G, Park J, Lee Y H, Kim Y J, Moon T, Kim K D, Hyun S D, Park H W, Chang H J, Choi J H, Hwang C S 2019 Appl. Phys. Rev. 6 041403 Google Scholar
[109]	Si M W, Lyu X, Ye P D 2019 ACS Appl. Electron. Mater. 1 745 Google Scholar
[110]	Wang J L, Wang D, Li Q, Zhang A H, Gao D, Guo M, Feng J J, Fan Z, Chen D Y, Qin M H, Zeng M, Gao X S, Zhou G F, Lu X B, Liu J M 2019 IEEE Electr. Device L. 40 1937 Google Scholar
[111]	Chen H Y, Tang L, Liu L Y, Chen Y H, Luo H, Yuan X, Zhang D 2021 Appl. Surf. Sci. 542 148737 Google Scholar
[112]	Onaya T, Nabatame T, Sawamoto N, Ohi A, Ikeda N, Chikyow T, Ogura A 2017 Appl. Phys. Express 10 081501 Google Scholar
[113]	Wong H S P, Salahuddin S 2015 Nat. Nanotechnol. 10 191 Google Scholar
[114]	Müller J, Böscke T S, Müllera S, Yurchuk E, Polakowski P, Paul J, Martin D, Schenk T, Khullar K, Kersch A, Weinreich W, Riedel S, Seidel K, Kumar A, Arruda T M, Kalinin S V, Schlösser T, Boschke R, Bentum R V, Schröder U, Mikolajick T 2013 IEEE International Electron Devices Meeting (IEDM) 13 280 Google Scholar
[115]	Huang F, Wang Y, Liang X, Qin J, Zhang Y, Yuan X F, Wang Z, Peng B, Deng L J, Liu Q, Bi L, Liu M 2017 IEEE International Electron Devices Meeting (IEDM) 38 330 Google Scholar
[116]	Mueller S, Slesazeck S, Henker S, Flachowsky S, Polakowski P, Paul J, Smith E, Müller J, Mikolajick T 2016 Ferroelectrics 497 42 Google Scholar
[117]	Chernikova A, Kozodaev M, Markeev A, Negrov D, Spiridonov M, Zarubin S, Bak O, Buragohain P, Lu H, Suvorova E, Gruverman A, Zenkevich A 2016 ACS Appl. Mater. Inter. 8 7232 Google Scholar
[118]	Fox G R, Chu F, Davenport T 2001 J. Vac. Sci. Technol. B 19 1967 Google Scholar
[119]	Fan Z, Chen J S, Wang J 2016 J. Adv. Dielectr. 6 1630003 Google Scholar
[120]	Ishiwara H 2012 J. Nanosci. Nanotechnol. 12 7619 Google Scholar
[121]	Okuno J, Kunihiro T, Konishi K, Materano M, Ali T, Kuehnel K, Seidel K, Mikolajick T, Schroeder U, Tsukamoto M, Umebayashi T 2021 IEEE J. Electron Devi. 10 29 Google Scholar
[122]	Mulaosmanovic H, Ocker J, Müller S, Schroeder U, Müller J, Polakowski P, Flachowsky S, Bentum R V, Mikolajick T, Slesazeck S 2017 ACS Appl. Mater. Interf. 9 3792 Google Scholar
[123]	Yan S C, Lan G M, Sun C J, Chen Y H, Wu C H, Peng H K, Lin Y H, Wu Y H, Wu Y C 2021 IEEE Electr. Device L. 42 1307 Google Scholar
[124]	Choi W Y, Park B G, Lee J D, Liu T J K, 2007 IEEE Electr. Device L. 28 743 Google Scholar
[125]	Salahuddin S, Datta S 2008 Nano Lett. 8 405 Google Scholar
[126]	谭欣, 翟亚红 2019 材料导报 33 433 Google Scholar Tan X, Zhai Y H 2019 Materials Reports 33 433 Google Scholar
[127]	Ionescu A M 2018 Nat. Nanotechnol. 13 7 Google Scholar
[128]	Si M W, Su C J, Jiang C S, Conrad N J, Zhou H, Maize K D, Qiu G, Wu C T, Shakouri A, Alam M A, Ye P D 2018 Nat. Nanotechnol 13 24 Google Scholar
[129]	McGuire F A, Lin Y C, Price K, Rayner G B, Khandelwal S, Salahuddin S, Franklin A D 2017 Nano Lett. 17 4801 Google Scholar
[130]	Esaki L, Laibowitz R B, Stiles P J 1971 IBM Tech. Discl. Bull. 13 2161
[131]	Zhuravlev M Y, Sabirianov R F, Jaswal S S, Tsymbal E Y 2005 Phys. Rev. Lett. 94 246802 Google Scholar
[132]	Garcia V, Bibes M 2014 Nat. Commun. 5 4289 Google Scholar
[133]	Du X Z, Sun H Y, Wang H, Li J C, Yin Y W, Li X G 2022 ACS Appl. Mater. Inter. 14 1355 Google Scholar
[134]	Goh Y, Hwang J, Lee Y, Kim M, Jeon S 2020 Appl. Phys. Lett. 117 242901 Google Scholar
[135]	Cheema S S, Shanker N, Hsu C H, Datar A, Bae J, Kwon D, Salahuddin S 2021 Adv. Electron. Mater. 8 2100499 Google Scholar
[136]	Drachman D A 2005 Neurology 64 2004 Google Scholar
[137]	Kim M K, Lee J S 2020 Adv. Mater. 32 1907826 Google Scholar
[138]	Majumdar S 2021 Adv. Intell. Syst. 4 2100175 Google Scholar
[139]	Lee D H, Park G H, Kim S H, Park J Y, Yang K, Slesazeck S, Mikolajick T, Park M H 2022 InfoMat 4 e12380 Google Scholar
[140]	Kim M K, Lee J S 2019 Nano Lett. 19 2044 Google Scholar
[141]	Xi F B, Han Y, M S Liu, Bae J H, Tiedemann A, Grützmacher D, Zhao Q T 2021 ACS Appl. Mater. Inter. 13 32005 Google Scholar
[142]	Goh Y, Hwang J, Kim M, Lee Y, Jung M, Jeon S 2021 ACS Appl. Mater. Inter. 13 59422 Google Scholar
[143]	Yao Z H, Song Z, Hao H, Yu Z Y, Cao M H, Zhang S J, Lanagan M T, Liu H X 2017 Adv. Mater. 29 1601727 Google Scholar
[144]	Ali F, Zhou D Y, Sun N N, Ali H W, Abbas A, Iqbal F, Dong F, Kim K H 2020 ACS Appl. Energy Mater. 3 6036 Google Scholar
[145]	Yao M W, Li Q X, Li F, Peng Y, Su Z, Yao X 2018 Mater. Chem. Phys. 206 48 Google Scholar
[146]	Yang B B, Guo M Y, Jin L H, Tang X W, Wei R H, Hu L, Yang J, Song W H, Dai J M, Lou X J, Zhu X B, Sun Y P 2018 Appl. Phys. Lett. 112 033904 Google Scholar
[147]	Lomenzo P D, Chung C C, Zhou C Z, Jones J L, Nishida T 2017 Appl. Phys. Lett. 110 232904 Google Scholar
[148]	Hoffmann M, Fengler F P G, Max B, Schroeder U, Slesazeck S, Mikolajick T 2019 Adv. Energy Mater. 9 1901154 Google Scholar
[149]	He Y, Zheng G, Wu X, Liu W J, Zhang D W, Ding S J 2022 Nanoscale Adv. 4 4648 Google Scholar
[150]	Spahr H, Nowak C, Hirschberg F, Reinker J, Kowalsky W, Hente D, Johannes H H 2013 Appl. Phys. Lett. 103 042907 Google Scholar
[151]	Zhang T D, Li W L, Hou Y F, Yu Y, Song R X, Cao W P, Fei W D 2017 J. Am. Ceram. Soc. 100 3080 Google Scholar
[152]	Lee H J, Won S S, Cho K H, Han C K, Mostovych N, Kingon A I, Kim S H, Lee H Y 2018 Appl. Phys. Lett. 112 092901 Google Scholar
[153]	Zhang X, Shen Y, Xu B, Zhang Q H, Gu L, Jiang J Y, Ma J, Lin Y H, Nan C W 2016 Adv. Mater. 28 2055 Google Scholar
[154]	电子工程师 https://m.elecfans.com/article/620744.html [2023-03-07]
[155]	Sun K, Chen J, Yan X 2021 Adv. Funct. Mater. 31 2006773 Google Scholar
[156]	Schenk T, Godard N, Mahjoub A, Girod S, Matavz A, Bobnar V, Defay E, Glinsek S 2019 Phys. Status Solidi-R 14 1900626 Google Scholar

施引文献

图 1 HfO₂基薄膜可以具有优异的铁电、压电、介电、反铁电和热释电性, 在很多领域具有广泛的应用前景

Fig. 1. HfO₂ based films exhibit excellent ferroelectric, piezoelectric, dielectric, antiferroelectric and pyroelectric properties, so they have wide application prospects in many fields.

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图 2 (a)—(f) HfO₂晶体结构示意图, 其中(a) m相, (b) t相, (c) c相, (d) oI相^[24]以及(e)极化向下和(f)极化向上的oIII相; (g) Hf_0.5Zr_0.5O₂薄膜的自由能曲线; (h) 不同晶粒尺寸的Hf_0.5Zr_0.5O₂ 薄膜在不同温度下的相图^[33]; (i) Hf_0.93Y_0.07O₂热处理过程中的相变流程图^[36]

Fig. 2. Crystal structures of HfO₂ with (a) m phase, (b) t phase, (c) c phase, (d) oI phase^[24], oIII phase with (e) downward polarization and (f) upward polarization; (g) free energy curve of Hf_0.5Zr_0.5O₂ films; (h) phase diagrams of Hf_0.5Zr_0.5O₂ films with different grain sizes at different temperatures^[33]; (i) phase evolution during Hf_0.93Y_0.07O₂ heat treatment ^[36].

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图 3 (a) Hf_1–xZr_xO₂薄膜的P-E和ε_r-E曲线^[19]; (b) Hf_1–xY_xO_2–δ薄膜的P-V曲线^[28]; (c) Hf_1–xA_xO₂ (A = Si, Al, Y, Gd, La或Sr)薄膜的P_r值随晶体半径和A掺杂量变化的等值线图^[18]

Fig. 3. (a) P-E and ε_r-E curve of Hf_1–xZr_xO₂ films^[19]; (b) P-V curves of Hf_1–xY_xO_2–δ films^[28]; (c) contour plot of the P_r of Hf_1–xA_xO₂ (A = Si, Al, Y, Gd, La and Sr) as a function of crystal radius and dopant content^[18].

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图 4 (a)退火温度为300—500 ℃时Hf_0.5Zr_0.5O₂薄膜的P-E曲线; (b) TiN电极的厚度为45—180 nm时Hf_0.5Zr_0.5O₂薄膜的P-E曲线^[71]; (c)不同电极的Hf_0.5Zr_0.5O₂的o相比例; (d)不同电极的Hf_0.5Zr_0.5O₂的2P_r值^[74]; (e), (f)有无VO_x上电极的Hf_0.5Zr_0.5O₂薄膜的P-V曲线和不同次数铁电极化翻转后的P_r^[76]

Fig. 4. P-E curves of Hf_0.5Zr_0.5O₂ film at (a) 300–500 ℃ annealing temperatures or with (b) 45–180 nm thick TiN electrode^[71]. (c) o-phase ratio and (d) 2P_r of Hf_0.5Zr_0.5O₂ with different electrodes^[74]. (e) P-E curves of Hf_0.5Zr_0.5O₂ film with or without VO_x top electrode^[76]. (f) P_r values of Hf_0.5Zr_0.5O₂ film with or without VO_x top electrode after different polarization switching cycles^76].

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图 5 (a) ALD和PVD制备的HfO₂薄膜的2P_r与厚度的关系^[95]; (b), (c)不同膜厚的(b) Hf_0.5Zr_0.5O₂薄膜和(c) Hf_0.5Zr_0.5O₂/Al₂O₃/Hf_0.5Zr_0.5O₂薄膜的P-E曲线^[101]; (d) 4×(HfO₂(1 nm)/ ZrO₂(1 nm))薄膜和8 nm Hf_0.5Zr_0.5O₂固溶体薄膜的P-E曲线^[107]; (e), (f) Al₂O₃/Hf_0.5Zr_0.5O₂ (20 nm)双层薄膜随Al₂O₃厚度变化的(e) C-V和(f) P-V曲线^[109]

Fig. 5. (a) Thickness dependence of the 2P_r of HfO₂ films prepared by ALD and PVD^[95]. P-E curves of the (b) Hf_0.5Zr_0.5O₂ films and (c) Hf_0.5Zr_0.5O₂/Al₂O₃/Hf_0.5Zr_0.5O₂ films with various thicknesses^[101]. (d) P-E curves of HfO₂(1 nm)/ ZrO₂(1 nm) × 4 nanolaminates and the Hf_0.5Zr_0.5O₂ solid solution^[107]. (e) C-V and (f) P-V curves of Al₂O₃/Hf_0.5Zr_0.5O₂ with different Al₂O₃ thicknesses^[109].

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图 6 (a) 1T1C铁电随机存储器结构示意图; (b) 1T1C存储器的SHMOO图^[121]; (c)平面型铁电场效应管结构示意图和(d)相应器件在上、下铁电极化方向时的转移特性曲线^[122]; (e)铁电鳍片式场效应管结构示意图; (f) HfO₂铁电鳍片式场效应管的转移特性曲线^[123]

Fig. 6. (a) Structure diagram and (b) SHMOO plot of a 1T1C ferroelectric random-access memory^[121]; (c) schematic diagram of planar ferroelectric field effect transistor and (d) the transfer characteristic curve of FeFET device with upward and downward polarization^[122]; (e) structure diagram of fin field-effect transistor; (f) the transfer characteristic curve of HfO₂ ferroelectric fin field-effect transistor ^[123].

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图 7 (a)铁电电容器从正电容到负电容的能量-电荷变化曲线^[127]; (b) 负电容对NC-FET亚阈值斜率的影响^[127]; (c) Al₂O₃/Hf_0.5Zr_0.5O₂TiN/Si^[128]负电容晶体管; (d) HfO₂/TiN/Hf_0.5Zr_0.5O₂TiN/SiO₂/Si^[129]负电容晶体管

Fig. 7. (a) Energy landscape of a ferroelectric capacitor^[127]; (b) effect of negative capacitance on the subthreshold (SS) slope of the NC-FET^[127]; (c) device architecture of Al₂O₃/Hf_0.5Zr_0.5O₂TiN/Si NC-FET^[128]; (d) device architecture of HfO₂/TiN/Hf_0.5Zr_0.5O₂TiN/SiO₂/Si NC-FET^[129].

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图 8 铁电薄膜(Fe)在(a)“低势垒Φ^–”和(b) “高势垒Φ⁺”状态下的FTJ结构^[132]; Au/Hf_0.5Zr_0.5O₂/La_2/3Sr_1/3MnO₃/NSTO FTJ在(c)不同脉冲电压V_p下和(d)多次铁电极化翻转循环后的电阻值^[133]; (e) TiN/Hf_0.5Zr_0.5O₂/W结构FTJ在1—10⁸次铁电极化翻转后的隧穿电流值^[134]; (f) W/Hf_0.8Zr_0.2O₂(1 nm)/SiO₂(1 nm)/Si结构 FTJ在1—10³次铁电极化翻转后的隧穿电流密度^[135]

Fig. 8. (a), (b) FTJ structures with low or high barrier potential states (i.e. Φ^– or Φ⁺)^[132]. Resistance of Au/Hf_0.5Zr_0.5O₂/La_2/3Sr_1/3MnO₃/NSTO FTJ as a function of (c) pulse voltage V_p and (d) polarization switching cycles^[133]. (e) Tunneling current value of TiN/Hf_0.5Zr_0.5O₂/W FTJ after different polarization switching cycles^[134]. (f) Tunneling current density of W/Hf_0.8Zr_0.2O₂(1 nm)/SiO₂(1 nm)/Si FTJ after polarization switching cycles^[135].

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图 9 (a)生物突触和动作电位示意图^[137]; (b) FeFET模拟生物突触示意图; (c) LTP和LTD的突触权重-时间曲线^[141]; (d) FeFET的光子突触结构示意图及其光电导-衰减时间曲线; (e) HZO薄膜铁电极化向下时器件的突触权重-时间曲线^[137]

Fig. 9. (a) Schematic illustrations of biological synapses and action potential^[137]. (b) Sketches on how a FeFET based synapse device; (c) synaptic weight as a function of time (Δt), showing a biological STDP behavior^[141]. (d) Schematic device structure of the photonic synapse and optical responses; (e) the synaptic weight as a function of relaxing time^[137].

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图 10 (a)线性介电、(b)铁电和(c)反铁电材料的P-E曲线, 其中蓝色区域代表储能密度^[144], P表示材料的极化, E表示施加的电场; (d), (e) Hf_xZr_1–xO₂ (x = 0.1—0.4)薄膜的(d) P-E电滞回线和(e)储能密度^[22]

Fig. 10. P-E curves of (a) linear dielectric, (b) ferroelectric, and (c) antiferroelectric materials, where P represents the polarization of the material, E represents the applied electric field and the blue area represents the energy storage density of each material^144]. (d) P-E hysteresis loops and (e) energy storage density of Hf_xZr_1–xO₂ (x = 0.1–0.4) thin films^[22].

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表 1 常见HfO₂基铁电薄膜的制备条件和铁电性能汇总

Table 1. Summary of preparation conditions and ferroelectric properties of common HfO₂-based ferroelectric films.

掺杂元素	掺杂浓度	结构	沉积方法	薄膜厚度/nm	沉积温度/℃	退火	电场/(MV·cm^–1)	2P_r/(μC·m^–2)	2E_c/(MV·cm^–1)	极化翻转次数/cycle
Si^[37]	4.4 mol%	TiN/Si:HfO₂/TiN	ALD	9	N/A	800 ℃, N²	4.5	48	1.74	N/A
Zr^[38]	50 at%	W/Zr:HfO₂/W	ALD	10	250	700 ℃, N², 5 s	3.5	65	2.4	10⁴ at3.0 MV cm^–1
Y^[28]	5.2 mol%	TiN/Y:HfO₂/TiN	ALD	10	N/A	600 ℃, N², 20 s	4.5	48	2.4	N/A
Gd^[39]	3.4 cat%	TaN/Gd:HfO₂/TaN	ALD	10	300	800 ℃, N², 20 s	—	70	N/A	10⁵ at4.0 MV cm^–1
Al^[40]	6.4 mol%	W/TiN/Al:HfO₂/Si	ALD	10	280	700 ℃, N², 10 s	8	100	9.5	10⁶ at8.0 MV cm^–1
La^[41]	10.0 cat%	TiN/La:HfO₂/TiN	ALD	12	280	800 ℃, N², 20 s	4.5	55	2.8	5×10⁵at 4 MV cm^–1
Sr^[42]	9.9 mol%	TiN/Sr:HfO₂/TiN	ALD	10	300	800 ℃, N², 20 s	3.5	46	$ \sim $3.2	10⁶ at3.0 MV cm^–1
Ta^[43]	16 at%	Pt/Ta:HfO₂/Pt/Ti	PVD	60	500	No anneal	1.25	106	1.6	10⁷ at0.8 MV cm^–1
非掺杂^[44]	N/A	TiN/HfO₂/TiN	PEALD	8	N/A	600 ℃, Ar, 30 s	3.125	26	2.4	> 10⁸ at2.5 MV cm^–1
对照^[45]		Pb(Zr_0.53Ti_0.47)O₃	PLD	500	650	650 ℃, O₂, 15 min	N/A	151	0.14	1×10¹⁰
对照^[46]		BiFeO₃	CSD	525	N/A	650 ℃, N²	N/A	142	1.0	10⁶ at0.4 MV cm^–1

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表 2 几种HfO₂基反铁电薄膜与其他常见材料的储能性能

Table 2. Energy storage performance of some HfO₂ based antiferroelectric film and other common materials.

材料	类型	厚度/nm	电场/(MV·cm^–1)	ESD/(J·cm^–3)	η/%	Ref.
Hf_0.5Zr_0.5O₂	铁电	9.2	4.9	55	57	[22]
Ta₂O₅/Hf_0.5Zr_0.5O₂	介电/反铁电	25	7	100	>95	[148]
Hf_0.5Zr_0.5O₂/Hf_0.25Zr_0.75O₂	铁电/反铁电	10	6	71.95	57.8	[149]
Hf_0.3Zr_0.7O₂	反铁电	9.2	4.35	45	51	[22]
Si:Hf_0.5Zr_0.5O₂	反铁电	10	4	53	82	[147]
Al:Hf_0.5Zr_0.5O₂	反铁电	10	5	52	80	[147]
La:Hf_0.5Zr_0.5O₂	反铁电	10	4	50	70	[53]
Al₂O₃	线性	5	—	50	—	[150]
BiFeO₃	铁电	$ \sim $40	—	3.2	—	[146]
BaTiO₃	铁电	$ \sim $300	2.6	28.5	75	[145]
Pb(Zr_0.52Ti_0.48)O₃	铁电	350	1.13	15.6	58.8	[151]
La:PbZrO₃	反铁电	10³	1	17.3	80.8	[152]
PVDF-HFP	铁电	10⁴	7.9	31.2	—	[153]

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[1]	McAdams H P, Acklin K, Blake T, Du X H, Eliason J, Fong J, Kraus W F, Liu D, Madan S, Moise T, Natarajan S, Qian N, Qiu Y C, Remack K A, Rodriguez J, Roscher J, Seshadri A, Summerfelt S R 2004 IEEE J. Solid-St. Circ. 39 667 Google Scholar
[2]	Krupanidhi S B, Maffei N, Sayer M, ElAssal K 1983 J. Appl. Phys. 54 6601 Google Scholar
[3]	Eaton S, Butler D, Parris M, Wilson D, McNeille H 1988 ISSCC Dig. Techn. Papers p130
[4]	Setter N, Damjanovic D, L Eng, Fox G, Gevorgian S, Hong S, Kingon A, Kohlstedt H, Park N Y, Stephenson G B, Stolitchnov I, Taganstev A K, Taylor D V, Yamada T, Streiffer S 2006 J. Appl. Phys. 100 051606 Google Scholar
[5]	Choi S H, Ko H Y, Heo J E, Son Y H, Bae B J, Yoo D C, Im D H, Jung Y J, Byun K R, Hahm J H, Shin S H, Yoon B U, Hong C K, Cho H K, Moon J T 2006 Integr. Ferroelectr. 84 147 Google Scholar
[6]	Park M H, Lee Y H, Kim H J, Kim Y J, Moon T, Kim K D, Muller J, Kersch A, Schroeder U, Mikolajick T, Hwang C S 2015 Adv. Mater. 27 1811 Google Scholar
[7]	Müller J, Polakowski P, Mueller S, Mikolajick T, 2015 ECS J. Solid State Sci. Technol. 4 N30 Google Scholar
[8]	Böscke T S, Müller J, Bräuhaus D, Schröder U, Böttger U 2011 Appl. Phys. Lett. 99 102903 Google Scholar
[9]	Robertson J, Falabretti B 2006 J. Appl. Phys. 100 014111 Google Scholar
[10]	Fischer D, Kersch A 2008 Appl. Phys. Lett. 92 012908 Google Scholar
[11]	Robertson J 2004 Eur. Phys. J. Appl. Phys. 28 265 Google Scholar
[12]	Kim S J, Mohan J, Kim H S, Hwang S M, Kim N, Jung Y C, Sahota A, Kim K, Yu H Y, Cha P R, Young C D, Choi R, Ahn J, Kim J 2020 Materials 13 2968 Google Scholar
[13]	Min H P, Kim H J, Kim Y J, Moon T, Hwang C S 2014 Appl. Phys. Lett. 104 072901 Google Scholar
[14]	Polakowski P, Müller J 2015 Appl. Phys. Lett. 106 232905 Google Scholar
[15]	Starschich S, Griesche D, Schneller T, Waser R, Böttger U 2014 Appl. Phys. Lett. 104 202903 Google Scholar
[16]	Shimizu T, Katayama K, Kiguchi T, Akama A, Konno T J, Funakubo H 2015 Appl. Phys. Lett. 107 032910 Google Scholar
[17]	Shimizu T, Katayama K, Kiguchi T, Akama A, Konno T J, Sakata O, Funakubo H 2016 Sci. Rep. 6 32931 Google Scholar
[18]	Schroeder U, Yurchuk E, Müller J, Martin D, Schenk T, Polakowski P, Adelmann C, Popovici M I, Kalinin S V, Mikolajick T 2014 Jpn. J. Appl. Phys. 53 08LE02 Google Scholar
[19]	Müller J, Böscke T S, Schröder U, Mueller S, Bräuhaus D, Böttger U, Frey L, Mikolajick T 2012 Nano Lett. 12 4318 Google Scholar
[20]	Mueller S, Mueller J, Singh A, Riedel S, Sundqvist J, Schroeder U, Mikolajick T 2012 Adv. Funct. Mater. 22 2412 Google Scholar
[21]	Park M H, Kim H J, Kim Y J, Moon T, Kim K D, Hwang C S 2015 Nano Energy 12 131 Google Scholar
[22]	Park M H, Kim H J, Kim Y J, Moon T, Kim K D, Hwang C S 2014 Adv. Energy Mater. 4 1400610 Google Scholar
[23]	Kirbach S, Lederer M, Eßlinger S, Mart C, Czernohorsky M, Weinreich W, Wallmersperger T 2021 Appl. Phys. Lett. 118 012904 Google Scholar
[24]	Materlik R, Küenneth C, Kersch A 2015 J. Appl. Phys. 117 134109 Google Scholar
[25]	Ohtaka O, Fukui H, Kunisada T, Fujisawa T, Funakoshi K, Utsumi W, Irifune T, Kuroda K, Kikegawa T 2001 J. Am. Ceram. Soc. 84 1369 Google Scholar
[26]	Wei Y F, Nukala P, Salverda M, Matzen S, Zhao H J, Momand J, Everhardt A S, Agnus G, Blake G R, Lecoeur P, Kooi B J, Íñiguez J, Dkhil B, Noheda B 2018 Nat. Mater. 17 1095 Google Scholar
[27]	Kisi E H, 1998 J. Am. Ceram. Soc. 81 741 Google Scholar
[28]	Müller J, Schröder U, Böscke T S, Müller I, Böttger U, Wilde L, Sundqvist J, Lemberger M, Kucher P, Mikolajick T, Frey L 2011 J. Appl. Phys. 110 114113 Google Scholar
[29]	Huan T D, Sharma V, Rossetti G A, Jr, Ramprasad R 2014 Phys. Rev. B 90 064111 Google Scholar
[30]	Nukala P, Antoja-Lleonart J, Wei Y F, Yedra L, Dkhil B, Noheda B 2019 ACS Appl. Electron. Mater. 1 2585 Google Scholar
[31]	Park M H, Lee Y H, Kim H J, Schenk T, Lee W, Kim K D, Fengler F P G, Mikolajick T, Schroeder U, Hwang C S 2017 Nanoscale 9 9973 Google Scholar
[32]	Batra R, Huan T D, Jones J L, Rossetti G, Ramprasad R 2017 J. Phys. Chem. C 121 4139 Google Scholar
[33]	Park M H, Lee Y H, Mikolajick T, Schroeder U, Hwang C S 2019 Adv. Electron. Mater. 5 1800522 Google Scholar
[34]	Park M H, Lee Y H, Kim H J, Kim Y J, Moon T, Kim K D, Hyun S D, Mikolajick T, Schroeder U, Hwang C S 2018 Nanoscale 10 716 Google Scholar
[35]	Lee Y H, Hyun S D, Kim H J, Kim J S, Yoo C, Moon T, Kim K D, Park H W, Lee Y B, Kim B S, Roh J, Park M H, Hwang C S 2019 Adv. Electron. Mater. 5 1800436 Google Scholar
[36]	Mimura T, Shimizu T, Kiguchi T, Akama A, Konno T J, Katsuya Y, Sakata O, Funakubo H 2019 Jpn. J. Appl. Phys. 58 SBBB09 Google Scholar
[37]	Martin D, Yurchuk E, Müller S, Müller J, Paul J, Sundquist J, Slesazeck S, Schlöesser T, Bentum R V, Trentzsch M, Schröder U, Mikolajick T 2013 Solid-State Electron. 88 65 Google Scholar
[38]	Kashir A, Kim H, Oh S, Hwang H 2021 ACS Appl. Electron. Mater. 3 629 Google Scholar
[39]	Hoffmann M, Schroeder U, Schenk T, Shimizu T, Funakubo H, Sakata O, Pohl D, Drescher M, Adelmann C, Materlik R, Kersch A, Mikolajick T 2015 J. Appl. Phys. 118 072006 Google Scholar
[40]	Ku B, Choi S, Song Y, Choi C 2020 IEEE Symposium on VLSI Technology Honolulu, HI, USA, June 15-19, 2020 p1
[41]	Schroeder U, Richter C, Park M H, Schenk T, Pesic M, Hoffmann M, Fengler F P G, Pohl D, Rellinghaus B, Zhou C Z, Chung C C, Jones J L, Mikolajick T 2018 Inorg. Chem. 57 2752 Google Scholar
[42]	Schenk T, Mueller S, Schroeder U, Materlik R, Kersch A, Popovici M, Adelmann C, Elshocht S V, Mikolajick T 2013 Proceedings of the European Solid-State Device Research Conference (ESSDERC) Bucharest, Romania, September 16-20, 2013 p260
[43]	Luo C Q, Kang C Y, Song Y L, Wang W P, Zhang W F 2021 Appl. Phys. Lett. 119 042902 Google Scholar
[44]	Luo J D, Lai Y Y, Hsiang K Y, Wu C F, Yeh Y T, Chung H T, Li YS, Chuang K C, Li WS, Liao C Y, Chen P G, Chen K N, Cheng H C 2021 IEEE T. Electron Dev. 68 1374 Google Scholar
[45]	Liu Y J, Song S J, Gong P, Xu L J, Li K F, Tang X B, Li W W, Yang H 2022 Appl. Phys. Lett. 121 122902 Google Scholar
[46]	Jin L H, Tang X W, Song D P, Wei R H, Yang J, Dai J M, Song W H, Zhu X B, Suna Y P 2015 J. Mater. Chem. C 3 10742 Google Scholar
[47]	Park M H, Lee Y H, Kim H J, Kim Y J, Moon T, Kim K D, Hyun S D, Hwang C S 2018 ACS Appl. Mater. Inter. 10 42666 Google Scholar
[48]	Li T, Dong J C, Zhange N, Wen Z C, Suna Z Z, Hai Y, Wang K W, Liu H Y, Tamura N, Mi S B, Cheng S D, Ma C S, He Y B, Li L, Ke S M, Huang H T, Cao Y G 2021 Acta Mater. 207 116696 Google Scholar
[49]	Lomenzo P D, Jachalke S, Stoecker H, Mehner E, Richter C, Mikolajick T, Schroeder U 2020 Nano Energy 74 104733 Google Scholar
[50]	Martin D, Müller J, Schenk T, Arruda T M, Kumar A, Strelcov E, Yurchuk E, Müller S, Pohl D, Schröder U, Kalinin S V, Mikolajick T 2014 Adv. Mater. 26 8198 Google Scholar
[51]	Yurchuk E, Müller J, Knebel S, Sundqvist J, Graham A P, Melde T, Schröder U, Mikolajick T 2013 Thin Solid Films 533 88 Google Scholar
[52]	Materlik R, Künneth C, Falkowski M, Mikolajick T, Kersch A 2018 J. Appl. Phys. 123 164101 Google Scholar
[53]	Kozodaev M G, Chernikova A G, Korostylev E V, Park M H, Khakimov R R, Hwang C S, Markeev A M 2019 J. Appl. Phys. 125 034101 Google Scholar
[54]	Kozodaev M G, Chernikova A G, Khakimov R R, Park M H, Markeev A M, Hwang C S 2018 Appl. Phys. Lett. 113 123902 Google Scholar
[55]	Hoffmann M, Schroeder U, Künneth C, Kersch A, Starschich S, Böttger U, Mikolajick T 2015 Nano Energy 18 154 Google Scholar
[56]	Lomenzo P D, Zhao P, Takmeel Q, Moghaddam S, Nishida T, Nelson M, Fancher C M, Grimley E D, Sang X, LeBeau J M, Jones J L 2014 J. Vac. Sci. Technol. B 32 03d123 Google Scholar
[57]	Lee C K, Cho E, Lee H S, Hwang C S, Han S 2008 Phys. Rev. B 78 012102 Google Scholar
[58]	Park M H, Schenk T, Fancher C M, Grimley E D, Zhou C, Richter C, LeBeau J M, Jones J L, Mikolajick T, Schroeder U 2017 J. Mater. Chem. C 5 4677 Google Scholar
[59]	Starschich S, Boettger U 2017 J. Mater. Chem. C 5 333 Google Scholar
[60]	Yao Y F, Zhou D Y, Li S D, Wang J J, Sun N N, Liu F, Zhao X M 2019 J. Appl. Phys. 126 154103 Google Scholar
[61]	Mueller S, Adelmann C, Singh A, Elshocht S Van, Schroeder U, Mikolajick T 2012 ECS J. Solid State Sci. Technol. 1 N123 Google Scholar
[62]	Schroeder U, Mueller S, Mueller J, Yurchuk E, Martin D, Adelmann C, Schloesser T, Bentum R V, Mikolajick T 2013 ECS J. Solid State Sci. Technol. 2 N69 Google Scholar
[63]	Tromm T C U, Zhang J, Schubert J, Luysberg M, Zander W, Han Q, Meuffels P, Meertens D, Glass S, Bernardy P, Mantl S 2017 Appl. Phys. Lett. 111 142904 Google Scholar
[64]	Luo J D, Yeh Y T, Lai Y Y, Wu C F, Chung H T, Li Y S, Chuang K C, Li W S, Chen P G, Lee M H, Cheng H C 2020 Vacuum 176 109317 Google Scholar
[65]	Kim K D, Park M H, Kim H J, Kim Y J, Moon T, Lee Y H, Hyun S D, Gwon T, Hwang C S 2016 J. Mater. Chem. C 4 6864 Google Scholar
[66]	Park M H, Kim H J, Kim Y J, Lee W, Kim H K, C S Hwang 2013 Appl. Phys. Lett. 102 112914 Google Scholar
[67]	Oh S, Song J, Yoo I K, Hwang H 2019 IEEE Electr. Device L. 40 1092 Google Scholar
[68]	Zhou Y, Zhang Y K, Yang Q, Jiang J, Fan P, Liao M, Zhou Y C 2019 Comp. Mater. Sci. 167 143 Google Scholar
[69]	Xu L, Nishimura T, Shibayama S, Yajima T, Migita S, Toriumi A 2016 Appl. Phys. Express 9 091501 Google Scholar
[70]	Wang J, Li H P, Stevens R 1992 J. Mater. Sci. 27 5397 Google Scholar
[71]	Kim S J, Narayan D, Lee J G, Mohan J, Lee J S, Lee J, Kim H S, Byun Y C, Lucero A T, Young C D, Summerfelt S R, San T, Colombo L, Kim J 2017 Appl. Phys. Lett. 111 242901 Google Scholar
[72]	Lomenzo P D, Takmeel Q, Zhou C Z, Fancher C M, Lambers E, Rudawski N G, Jones J L, Moghaddam S, Nishida T 2015 J. Appl. Phys. 117 134105 Google Scholar
[73]	Karbasian G, Reis R D, Yadav A K, Tan A J, Hu C M, Salahuddin S 2017 Appl. Phys. Lett. 111 022907 Google Scholar
[74]	Lee Y, Goh Y, Hwang J, Das D, Jeon S 2021 IEEE Trans. Electr. Dev. 68 523 Google Scholar
[75]	Cao R R, Wang Y, Zhao S J, Yang Y, Zhao X L, Wang W, Zhang X M, Lv H B, Liu Q, Liu M 2018 IEEE Electr. Device L. 39 1207 Google Scholar
[76]	Zhang Y, Fan Z, Wang D, Wang J L, Zou Z M, Li Y S, Li Q, Tao R Q, Chen D Y, Zeng M, Gao X S, Dai J Y, Zhou G F, Lu X B, J M Liu 2020 ACS Appl. Mater. Inter. 12 40510 Google Scholar
[77]	Goh Y, Cho S H, Park S H K, Jeon S 2020 Nanoscale 12 9024 Google Scholar
[78]	Zhang Z M, Hsu S L, Stoica V A, Paik H, Parsonnet E, Qualls A, Wang J J, Xie L, Kumari M, Das S, Leng Z N, McBriarty M, Proksch R, Gruverman A, Schlom D G, Chen L Q, Salahuddin S, Martin L W, Ramesh R 2021 Adv. Mater. 33 2006089 Google Scholar
[79]	Shiraishi T, Katayama K, Yokouchi T, Shimizu T, Oikawa T, Sakata O, Uchida H, Imai Y, Kiguchi T, Konno T J, Funakubo H 2016 Appl. Phys. Lett. 108 262904 Google Scholar
[80]	Li T, Zhang N, Sun Z Z, Xie C X, Ye M, Mazumdar S, Shu L, Wang Y, Wang D Y, Chen L, Ke S, Huang H 2018 J. Mater. Chem. C 6 9224 Google Scholar
[81]	Katayama K, Shimizu T, Sakata O, Shiraishi T, Nakamura S, Kiguchi T, Akama A, Konno T J, Uchida H, Funakubo H 2016 Appl. Phys. Lett. 109 112901 Google Scholar
[82]	Song T F, Bachelet R, Saint-Girons G, Solanas R, Fina I, Sánchez F 2020 ACS Appl. Electron. Mater. 2 3221 Google Scholar
[83]	Estandia S, Dix N, Chisholm M F, Fina I, Sánchez F 2020 Cryst. Growth Des. 20 3801 Google Scholar
[84]	Li T, Ye M, Sun Z Z, Zhang N, Zhang W, Inguva S, Xie C X, Chen L, Wang Y, Ke S M, Huang H T 2019 ACS Appl. Mater. Inter. 11 4139 Google Scholar
[85]	Zhou H, Wu L J, Wang H Q, Zheng J C, Zhang L H, Kisslinger K, Li Y P, Wang Z Q, Cheng H, Ke S M, Li Y, Kang J Y, Zhu Y M 2017 Nat. Commun. 8 1474 Google Scholar
[86]	Lyu J, Fina I, Solanas R, Fontcuberta J, Sánchez F 2018 Appl. Phys. Lett. 113 082902 Google Scholar
[87]	Lyu J, Fina I, Bachelet R, Saint-Girons G, Estandía S, Gázquez J, Fontcuberta J, Sánchez F 2019 Appl. Phys. Lett. 114 222901 Google Scholar
[88]	Cheema S S, Kwon D, Shanker N, Reis R D, Hsu S L, Xiao J, Zhang H G, Wagner R, Datar A, McCarter M R, Serrao C R, Yadav A K, Karbasian G, Hsu C H, Tan A J, Wang L C, Thakare V, Zhang X, Mehta A, Karapetrova E, Chopdekar R V, Shafer P, Arenholz E, Hu C, Proksch R, Ramesh R, Ciston J, Salahuddin S 2020 Nature 580 478 Google Scholar
[89]	Xu X H, Huang F T, Qi Y B, Singh S, Rabe K M, Obeysekera D, Yang J J, Chu M W, Cheong S W 2021 Nat. Mater. 20 826 Google Scholar
[90]	Estandía S, Dix N, Gazquez J, Fina I, Lyu J, Chisholm M F, Fontcuberta J, Sánchez F 2019 ACS Appl. Electron Mater. 1 1449 Google Scholar
[91]	Lyu J, Fina I, Fontcuberta J, Sanchez F 2019 ACS Appl. Mater. Inter. 11 6224 Google Scholar
[92]	Park M H, Kim H J, Kim Y J, Lee W, Moon T, Kim K D, Hwang C S 2014 Appl. Phys. Lett. 105 072902 Google Scholar
[93]	Yan Y, Zhou D Y, Guo C X, Xu J, Yang X R, Liang H L, Zhou F Y, Chu S C, Liu X Y 2016 J. Sol-Gel Sci. Technol. 7 430 Google Scholar
[94]	Chernikova A G, Kuzmichev D S, Negrov D V, Kozodaev M G, Polyakov S N, Markeev A M 2016 Appl. Phys. Lett. 108 242905 Google Scholar
[95]	Mittmann T, Materano M, Lomenzo P D, Park M H, Stolichnov I, Cavalieri M, Zhou C Z, Chung C C, Jones J L, Szyjka T, Müller M, Kersch A, Mikolajick T, Schroeder U 2019 Adv. Mater. Inter. 6 1900042 Google Scholar
[96]	Liao J J, Zeng B J, Sun Q, Chen Q, Liao M, Qiu C G, Zhang Z Y, Zhou Y C 2019 IEEE Electr. Device L. 40 1868 Google Scholar
[97]	Migita S, Ota H, Asanuma S, Morita Y, Toriumi A 2021 Appl. Phys. Express 14 051006 Google Scholar
[98]	Chen Y H, Wang L, Liu L Y, Tang L, Yuan X, Chen H Y, Zhou K C, Zhang D 2021 J. Mater. Sci. 56 6064 Google Scholar
[99]	Shin H W, Son J Y 2020 Appl. Phys. Lett. 117 202902 Google Scholar
[100]	Chen Q, Zhang Y K, Liu W Y, Jiang J, Yang Q, Jiang L M 2021 Int. J. Mech. Sci. 212 106828 Google Scholar
[101]	Kim H J, Park M H, Kim Y J, Lee Y H, Jeon W, Gwon T, Moon T, Kim K D, Hwang C S 2014 Appl. Phys. Lett. 105 192903 Google Scholar
[102]	Nakayama S, Funakubo H, Uchida H 2018 Jpn. J. Appl. Phys. 57 11UF06 Google Scholar
[103]	Chen H Y, Chen Y H, Tang L, Luo H, Zhou K C, Yuan X, Zhang D 2020 J. Mater. Chem. C 8 2820 Google Scholar
[104]	Tang L, Chen C, Wei A Q, Li K, Zhang D, Zhou K C 2019 Ceram. Int. 45 3140 Google Scholar
[105]	Liu H, Zheng S Z, Chen Q, Zeng B J, Jiang J, Peng Q X, Liao M, Zhou Y C 2019 J. Mater. Sci. :Mater. Electron. 30 5771 Google Scholar
[106]	Wang X X, Zhou D Y, Li S D, Liu X H, Zhao P, Sun N N, Ali F, Wang J J 2018 Ceram. Int. 44 13867 Google Scholar
[107]	Weeks S L, Pal A, Narasimhan V K, Littau K A, Chiang T 2017 ACS Appl. Mater. Inter. 9 13440 Google Scholar
[108]	Park M H, Kim H J, Lee G, Park J, Lee Y H, Kim Y J, Moon T, Kim K D, Hyun S D, Park H W, Chang H J, Choi J H, Hwang C S 2019 Appl. Phys. Rev. 6 041403 Google Scholar
[109]	Si M W, Lyu X, Ye P D 2019 ACS Appl. Electron. Mater. 1 745 Google Scholar
[110]	Wang J L, Wang D, Li Q, Zhang A H, Gao D, Guo M, Feng J J, Fan Z, Chen D Y, Qin M H, Zeng M, Gao X S, Zhou G F, Lu X B, Liu J M 2019 IEEE Electr. Device L. 40 1937 Google Scholar
[111]	Chen H Y, Tang L, Liu L Y, Chen Y H, Luo H, Yuan X, Zhang D 2021 Appl. Surf. Sci. 542 148737 Google Scholar
[112]	Onaya T, Nabatame T, Sawamoto N, Ohi A, Ikeda N, Chikyow T, Ogura A 2017 Appl. Phys. Express 10 081501 Google Scholar
[113]	Wong H S P, Salahuddin S 2015 Nat. Nanotechnol. 10 191 Google Scholar
[114]	Müller J, Böscke T S, Müllera S, Yurchuk E, Polakowski P, Paul J, Martin D, Schenk T, Khullar K, Kersch A, Weinreich W, Riedel S, Seidel K, Kumar A, Arruda T M, Kalinin S V, Schlösser T, Boschke R, Bentum R V, Schröder U, Mikolajick T 2013 IEEE International Electron Devices Meeting (IEDM) 13 280 Google Scholar
[115]	Huang F, Wang Y, Liang X, Qin J, Zhang Y, Yuan X F, Wang Z, Peng B, Deng L J, Liu Q, Bi L, Liu M 2017 IEEE International Electron Devices Meeting (IEDM) 38 330 Google Scholar
[116]	Mueller S, Slesazeck S, Henker S, Flachowsky S, Polakowski P, Paul J, Smith E, Müller J, Mikolajick T 2016 Ferroelectrics 497 42 Google Scholar
[117]	Chernikova A, Kozodaev M, Markeev A, Negrov D, Spiridonov M, Zarubin S, Bak O, Buragohain P, Lu H, Suvorova E, Gruverman A, Zenkevich A 2016 ACS Appl. Mater. Inter. 8 7232 Google Scholar
[118]	Fox G R, Chu F, Davenport T 2001 J. Vac. Sci. Technol. B 19 1967 Google Scholar
[119]	Fan Z, Chen J S, Wang J 2016 J. Adv. Dielectr. 6 1630003 Google Scholar
[120]	Ishiwara H 2012 J. Nanosci. Nanotechnol. 12 7619 Google Scholar
[121]	Okuno J, Kunihiro T, Konishi K, Materano M, Ali T, Kuehnel K, Seidel K, Mikolajick T, Schroeder U, Tsukamoto M, Umebayashi T 2021 IEEE J. Electron Devi. 10 29 Google Scholar
[122]	Mulaosmanovic H, Ocker J, Müller S, Schroeder U, Müller J, Polakowski P, Flachowsky S, Bentum R V, Mikolajick T, Slesazeck S 2017 ACS Appl. Mater. Interf. 9 3792 Google Scholar
[123]	Yan S C, Lan G M, Sun C J, Chen Y H, Wu C H, Peng H K, Lin Y H, Wu Y H, Wu Y C 2021 IEEE Electr. Device L. 42 1307 Google Scholar
[124]	Choi W Y, Park B G, Lee J D, Liu T J K, 2007 IEEE Electr. Device L. 28 743 Google Scholar
[125]	Salahuddin S, Datta S 2008 Nano Lett. 8 405 Google Scholar
[126]	谭欣, 翟亚红 2019 材料导报 33 433 Google Scholar Tan X, Zhai Y H 2019 Materials Reports 33 433 Google Scholar
[127]	Ionescu A M 2018 Nat. Nanotechnol. 13 7 Google Scholar
[128]	Si M W, Su C J, Jiang C S, Conrad N J, Zhou H, Maize K D, Qiu G, Wu C T, Shakouri A, Alam M A, Ye P D 2018 Nat. Nanotechnol 13 24 Google Scholar
[129]	McGuire F A, Lin Y C, Price K, Rayner G B, Khandelwal S, Salahuddin S, Franklin A D 2017 Nano Lett. 17 4801 Google Scholar
[130]	Esaki L, Laibowitz R B, Stiles P J 1971 IBM Tech. Discl. Bull. 13 2161
[131]	Zhuravlev M Y, Sabirianov R F, Jaswal S S, Tsymbal E Y 2005 Phys. Rev. Lett. 94 246802 Google Scholar
[132]	Garcia V, Bibes M 2014 Nat. Commun. 5 4289 Google Scholar
[133]	Du X Z, Sun H Y, Wang H, Li J C, Yin Y W, Li X G 2022 ACS Appl. Mater. Inter. 14 1355 Google Scholar
[134]	Goh Y, Hwang J, Lee Y, Kim M, Jeon S 2020 Appl. Phys. Lett. 117 242901 Google Scholar
[135]	Cheema S S, Shanker N, Hsu C H, Datar A, Bae J, Kwon D, Salahuddin S 2021 Adv. Electron. Mater. 8 2100499 Google Scholar
[136]	Drachman D A 2005 Neurology 64 2004 Google Scholar
[137]	Kim M K, Lee J S 2020 Adv. Mater. 32 1907826 Google Scholar
[138]	Majumdar S 2021 Adv. Intell. Syst. 4 2100175 Google Scholar
[139]	Lee D H, Park G H, Kim S H, Park J Y, Yang K, Slesazeck S, Mikolajick T, Park M H 2022 InfoMat 4 e12380 Google Scholar
[140]	Kim M K, Lee J S 2019 Nano Lett. 19 2044 Google Scholar
[141]	Xi F B, Han Y, M S Liu, Bae J H, Tiedemann A, Grützmacher D, Zhao Q T 2021 ACS Appl. Mater. Inter. 13 32005 Google Scholar
[142]	Goh Y, Hwang J, Kim M, Lee Y, Jung M, Jeon S 2021 ACS Appl. Mater. Inter. 13 59422 Google Scholar
[143]	Yao Z H, Song Z, Hao H, Yu Z Y, Cao M H, Zhang S J, Lanagan M T, Liu H X 2017 Adv. Mater. 29 1601727 Google Scholar
[144]	Ali F, Zhou D Y, Sun N N, Ali H W, Abbas A, Iqbal F, Dong F, Kim K H 2020 ACS Appl. Energy Mater. 3 6036 Google Scholar
[145]	Yao M W, Li Q X, Li F, Peng Y, Su Z, Yao X 2018 Mater. Chem. Phys. 206 48 Google Scholar
[146]	Yang B B, Guo M Y, Jin L H, Tang X W, Wei R H, Hu L, Yang J, Song W H, Dai J M, Lou X J, Zhu X B, Sun Y P 2018 Appl. Phys. Lett. 112 033904 Google Scholar
[147]	Lomenzo P D, Chung C C, Zhou C Z, Jones J L, Nishida T 2017 Appl. Phys. Lett. 110 232904 Google Scholar
[148]	Hoffmann M, Fengler F P G, Max B, Schroeder U, Slesazeck S, Mikolajick T 2019 Adv. Energy Mater. 9 1901154 Google Scholar
[149]	He Y, Zheng G, Wu X, Liu W J, Zhang D W, Ding S J 2022 Nanoscale Adv. 4 4648 Google Scholar
[150]	Spahr H, Nowak C, Hirschberg F, Reinker J, Kowalsky W, Hente D, Johannes H H 2013 Appl. Phys. Lett. 103 042907 Google Scholar
[151]	Zhang T D, Li W L, Hou Y F, Yu Y, Song R X, Cao W P, Fei W D 2017 J. Am. Ceram. Soc. 100 3080 Google Scholar
[152]	Lee H J, Won S S, Cho K H, Han C K, Mostovych N, Kingon A I, Kim S H, Lee H Y 2018 Appl. Phys. Lett. 112 092901 Google Scholar
[153]	Zhang X, Shen Y, Xu B, Zhang Q H, Gu L, Jiang J Y, Ma J, Lin Y H, Nan C W 2016 Adv. Mater. 28 2055 Google Scholar
[154]	电子工程师 https://m.elecfans.com/article/620744.html [2023-03-07]
[155]	Sun K, Chen J, Yan X 2021 Adv. Funct. Mater. 31 2006773 Google Scholar
[156]	Schenk T, Godard N, Mahjoub A, Girod S, Matavz A, Bobnar V, Defay E, Glinsek S 2019 Phys. Status Solidi-R 14 1900626 Google Scholar

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HfO₂基铁电薄膜的结构、性能调控及典型器件应用

Structure, performance regulation and typical device applications of HfO₂-based ferroelectric films

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1.
南京理工大学材料科学与工程学院, 南京　210094

2.
华南师范大学华南先进光电子研究院, 广州　510006

通信作者: 袁国亮, yuanguoliang@njust.edu.cn ; 陆旭兵, luxubing@m.scnu.edu.cn

Authors and contacts

1.
School of Material Science and Engineering, Nanjing University of Science and Technology, Nanjing 210094, China

2.
South China Academy of Advanced Optoelectronics, South China Normal University, Guangzhou 510006, China

Corresponding author: Yuan Guo-Liang, yuanguoliang@njust.edu.cn ; Lu Xu-Bing, luxubing@m.scnu.edu.cn

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HfO2基铁电薄膜的结构、性能调控及典型器件应用

Structure, performance regulation and typical device applications of HfO2-based ferroelectric films

摘要

Abstract

作者及机构信息

1. 南京理工大学材料科学与工程学院, 南京 210094 2. 华南师范大学华南先进光电子研究院, 广州 510006

通信作者: 袁国亮, yuanguoliang@njust.edu.cn ; 陆旭兵, luxubing@m.scnu.edu.cn

Authors and contacts

1. School of Material Science and Engineering, Nanjing University of Science and Technology, Nanjing 210094, China 2. South China Academy of Advanced Optoelectronics, South China Normal University, Guangzhou 510006, China

Corresponding author: Yuan Guo-Liang, yuanguoliang@njust.edu.cn ; Lu Xu-Bing, luxubing@m.scnu.edu.cn

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HfO₂基铁电薄膜的结构、性能调控及典型器件应用

Structure, performance regulation and typical device applications of HfO₂-based ferroelectric films

1.
南京理工大学材料科学与工程学院, 南京　210094

2.
华南师范大学华南先进光电子研究院, 广州　510006

1.
School of Material Science and Engineering, Nanjing University of Science and Technology, Nanjing 210094, China

2.
South China Academy of Advanced Optoelectronics, South China Normal University, Guangzhou 510006, China