压电纳米发电机材料选用和结构设计研究进展

doi:10.11896/cldb.20070069

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Abstract Since the first appearance of the piezoelectric nanogenerator in 2006, various piezoelectric materials have been applied in this field. The pre-paration technology and device structure of the piezoelectric nanogenerator have been continuously optimized. At the same time, researchers are constantly using new methods to develop new piezoelectric materials to improve the performance of piezoelectric nanogenerator. However, the limitations of piezoelectric materials have led researchers to begin to redesign the device structures. The researchers have been constantly exploring a variety of structures involved conventional parallel plate structure, multi-layer structure, and hybrid devices, and have made abundant achievements. This review summarizes the relevant research results in recent years in terms of the structure of piezoelectric nanogenerator combining with its materials, preparation methods, properties, characteristics, etc. The output performance of nanogenerators for different piezoelectric materials and structures, and the problems and development prospects of piezoelectric nanogenerators in the future are analyzed to provide the reference on developing excellent piezoelectric nanogenerator with multisource energy harvesting ability.

Key words： nanogenerator piezoelectric material structure design piezoelectric performance output performance

Published: 25 June 2021

CLC number:

TM31

Fund:This work was financially supported by Youth Program of National Natural Science Foundation of China (51503168), Innovation Capability Support Plan of Shaanxi, China (2020PT-043), Innovation Talent Promotion Program of Shaanxi, China (2017KJXX-23), Special Funding for Postdoctoral Innovation Project of Shandong, China (201504) and Innovation Fund for Graduate Students of Xi’an Polytechnic University (chx2020001).

About author:: Qing Zhang, graduated from Xi’an Polytechnic University in June 2018 with a bachelor degree in enginee-ring. He is currently a master student in the School of Textile Science and Engineering, Xi’an Polytechnic University. His research has focused on preparation of nanofibers and piezoelectric nanogenerators.Chengkun Liu, is a professor and master tutor in the School of Textile Science and Engineering, Xi’an Polytechnic University. He received his Ph.D. from the Xi’an Jiaotong University in 2011. He is the visiting scholar of University of Manchester, UK and the Youth New Star of Science and Technology. He is mainly engaged in research of textile materials and textiles design, pre-paration of nanofibrous materials and development of functional product. He has presided over more than 10 vertical and horizontal scientific research projects. In addition, he has completed 2 patent transfers, published more than 30 papers (20 cited by SCI/EI) as the first or corresponding author, and authorized 10 patents.

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	ZHANG Qing
	LIU Chengkun
	MAO Xue
	WU Yuexia
	JIANG Zhiwei
	ZHAO Li
	HONG Jie

Cite this article:

ZHANG Qing,LIU Chengkun,MAO Xue, et al. Research Progress in Material Selection and Structure Design of Piezoelectric Nanogenerator[J]. Materials Reports, 2021, 35(11): 11066-11076.

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http://www.mater-rep.com/EN/10.11896/cldb.20070069 OR http://www.mater-rep.com/EN/Y2021/V35/I11/11066

1	Guo C C, Cheng L F, Ye F. Materials China,2019,38(9),831(in Chinese).
	郭楚楚,成来飞,叶昉.中国材料进展,2019,38(9),831.
2	Wei J, Zhang Q, Zhao L L, et al. Journal of Nanoscience and Nanotech?nolgy,2018,18(2),1224.
3	Kim J H, Choi S C. Journal of the Korean Ceramic Society,2018,55(3),285.
4	Wang F, Qin X F, Zhu D D, et al. Materials Science in Semiconductor Processing,2015,29(1),155.
5	Li Z J, Gao W D, Meng A L, et al. The Journal of Physical Chemistry C,2009,113(1),91.
6	Zhang Y F, Sheng L M, FangY H, et al. Chemical Physics Letters,2017,678(1),17.
7	Liu S, Wang J G. Physica E: Low?dimensional Systems and Nanostructures,2016,81(1),268.
8	Liu H T, Huang Z H, Fang M H, et al. Journal of Crystal Growth,2015,419(1),20.
9	Zhou X T, Wang N, Lai H L, et al. Applied Physics Letters,1999,74(26),3942.
10	Yang G Z, Cui H, Sun Y, et al. Rural Economy,2009,113(36),15969.
11	Wei J, Li K Z, Chen J, et al. Journal of Crystal Growth,2011,335(1),160.
12	Chen J J, Shi Q, Xin L P, et al. Current Nanoscience,2012,8(2),226.
13	Wu R B, Pan Y, Yang G Y, et al. The Journal of Physical Chemistry C,2007,111(17),6233.
14	Li B B, Mao B X, Huang H Q, et al. International Journal of Applied Ceramic Technology,2020,00(1),1.
15	Li J, Zhu X L, Ding P, et al. Nanotechnology,2009,20(14),145602.
16	Wei J, Li K Z, Chen J, et al. Journal of the American Ceramic Society,2013,96(2),627.
17	Duan X F, Lieber C M. Journal of the American Chemical Society,2000,122(1),188.
18	Zhang B C, Wang H, He L, et al. Nano Letters,2017,17(12),7323.
19	Wu S T, Wang L C, Yi X Y, et al. Journal of Applied Physics,2017,122(20),205302.
20	Amnon R, Tamir F,Yarden D, et al. The Journal of Physical Chemistry C,2018,122(23),12413.
21	Huang M H, Wu Y Y, Feick H N, et al. Advanced Materials,2001,13(2),113.
22	Kenry, Lim C T. Progress in Materials Science,2013,58(5),705.
23	Prakash J. Silicon?based Nanomaterials,2013,187(1),179.
24	Krishnan B, Kotamraju S P, Sundaresan S G, et al. Materials Science Forum,2010,645?648(1),187.
25	Panda S K, Sengupta J, Jacob C. Journal of Nanoscience and Nanotech?nology,2010,10(5),3046.
26	Zhang Y F, Nishitani?Gamo M, Xiao C Y, et al. Journal of Applied Phy?sics,2002,91(9),6066.
27	Lopez?Camacho E, Fernandez M, Gomez?Aleixandre C. Journal of Phy?sics D: Applied Physics,2009,42(4),45302.
28	Nazarudin N F F B, Azizan S N A B, Rahman S A, et al. Thin Solid Films,2014,570(Part B),243.
29	Goh B T, Abdul R S. Journal of Crystal Growth,2014,407(1),25.
30	Zhang H F, Wang C M, Wang L S. Nano Letters,2002,2(9),941.
31	Sun Y, Cui H, Yang G Z, et al. CrystEngComm,2010,12(4),1134.
32	Kohno H, Yagi K, Niioka H. Japanese Journal of Applied Physics,2011,50(1),18001.
33	Zheng H W, Zhao T T, Tian Y, et al. Materials Letters,2014,120(1),13.
34	Yu J S, Liu H S, Zhou X G, et al. IOP Conference Series: Materials Science and Engineering,2019,504(1),12039.
35	Wang X C, Tang B, Gao F M, et al. Journal of Physics D: Applied Phy?sics,2011,44(24),245404.
36	Kim H Y, Bae S Y, Kim N S, et al. Chemical Communications,2003,9(20),2634.
37	Zhang M, Zhao J, Li Z J, et al. Journal of Solid State Chemistry,2016,243(1),247.
38	Wang J K, Zhang Y Z, Li J Y, et al. Powder Technology,2017,317(1),209.
39	Li Z J, Ma F L, Zhang M, et al. The Journal of Chemical Physics,2015,31(6),1191(in Chinese).
	李镇江,马凤麟,张猛,等.物理化学学报,2015,31(6),1191.
40	Wu R B, Zhou K, Wei J, et al. The Journal of Physical Chemistry C,2012,116(23),12940.
41	Zhang J, Liu X H, Jia Q L, et al. Ceramics International,2015,42(3),4600.
42	Zhang J, Jia Q L, Zhang S M, et al. Ceramics International,2015,42(2),2227.
43	Zhang D Q, Alkhateeb A, Han H M, et al. Nano Letters,2003,3(7),983.
44	Ho G W, Wong A S W, Kang D J, et al. Nanotechnology,2004,15(8),996.
45	Li L, Chu Y H, Li H J, et al. Ceramics International,2014,40(3),4455.
46	Ke K C, Jiang M, Ding L J, et al. Journal of the American Ceramic Society,2019,102(6),3070.
47	Li H J, He Z B, Chu Y H, et al. Materials Letters,2013,109(1),275.
48	Hu P, Dong S, Zhang D Y, et al. Ceramics International,2016,42(1,Part B),1581.
49	Arendt R H. Journal of Applied Physics,1973,44(7),3300.
50	Zhang J. Study on SiC nanowires assisted by molten salt and their photoluminescence properties. Master's Thesis, Zhengzhou University, China,2016(in Chinese).
	张举.熔盐辅助制备SiC纳米线及其光致发光性能研究.硕士学位论文,郑州大学,2016.
51	Xie W, Moebus G, Zhang S W. Journal of Materials Chemistry,2011,21(45),18325.
52	Wu R B, Zhou K, Yang Z H, et al. CrystEngComm,2013,15(3),570.
53	Sun Z G, Qiao X J, Ren Q G, et al. Advanced Powder Technology,2016,27(4),1552.
54	Liu R Z, Liu M L, Chang J X, et al. Chemical Vapor Deposition,2015,21(7?9),196.
55	Longkullabutra H, Nhuapeng W, Thamjaree W. Current Applied Physics,2012,12(S2),S112.
56	Chen X Y, Qin Y M, Jia Q L, et al. Materials Letters,2019,234(1),187.
57	Chen X Y, Zhang Q, Zhou Y, et al. Ceramics International,2018,44(18),22890.
58	Chen X Y, Liu X H, Geng X J, et al. Ceramics International,2018,44(10),11204.
59	Chang J X, Liu R Z, Liu M L, et al. Key Engineering Materials,2016,697(1),841.
60	Yu W P, Zheng Y, Yang E, et al. Journal of Rare Earths,2010,28(3),365.
61	Han W Q, Redlich P, Ernst F, et al. Applied Physics Letters,1999,75(13),1875.
62	Jintakosol T, Singjai P. Key Engineering Materials,2007,353?358(1),2171.