Page 15 - Read Online

P. 15

Page 10 of 10 Ouyang et al. Microstructures 2023;3:2023027 https://dx.doi.org/10.20517/microstructures.2023.22

4. Dai L, Lin F, Zhu Z, Li J. Electrical characteristics of high energy density multilayer ceramic capacitor for pulse power application.
IEEE Trans Magn 2005;41:281-4. DOI
5. Chen XF, Dong XL, Wang GS, Cao F, Wang YL. Doped Pb(Zr,Sn,Ti)O slim-loop ferroelectric ceramics for high-power pulse
3
capacitors application. Ferroelectrics 2008;363:56-63. DOI
6. Zhu L, Wang Q. Novel ferroelectric polymers for high energy density and low loss dielectrics. Macromolecules 2012;45:2937-54.
DOI
7. Wang Y, Zhou X, Chen Q, Chu B, Zhang Q. Recent development of high energy density polymers for dielectric capacitors. IEEE
Trans Dielect Electr Insul 2010;17:1036-42. DOI
8. Kim Y, Kathaperumal M, Smith OL, et al. High-energy-density sol-gel thin film based on neat 2-cyanoethyltrimethoxysilane. ACS
Appl Mater Interfaces 2013;5:1544-7. DOI
9. Ouyang J, Yang SY, Chen L, Ramesh R, Roytburd AL. Orientation dependence of the converse piezoelectric constantsfor epitaxial
single domain ferroelectric films. Appl Phys Lett 2004;85:278-80. DOI
10. Wang J, Su Y, Wang B, Ouyang J, Ren Y, Chen L. Strain engineering of dischargeable energy density of ferroelectric thin-film
capacitors. Nano Energy 2020;72:104665. DOI
11. Niu M, Zhu H, Wang Y, et al. Integration-friendly, chemically stoichiometric BiFeO films with a piezoelectric performance
3
challenging that of PZT. ACS Appl Mater Interfaces 2020;12:33899-907. DOI
12. Su Y, Ouyang J, Zhao YY. Nanograins in ferroelectric films. In: Ouyang J, editor, Nanostructures in ferroelectric films for energy
applications. Amsterdam: Elsevier; 2019; pp. 129-62.
13. Zhao Y, Ouyang J, Wang K, et al. Achieving an ultra-high capacitive energy density in ferroelectric films consisting of superfine
columnar nanograins. Energy Stor Mater 2021;39:81-8. DOI
14. Wang K, Zhang Y, Wang S, et al. High energy performance ferroelectric (Ba,Sr)(Zr,Ti)O film capacitors integrated on Si at 400 °C.
3
ACS Appl Mater Interfaces 2021;13:22717-27. DOI
15. Zhu H, Zhao YY, Ouyang J, Wang K, Cheng H, Su Y. Achieving a record-high capacitive energy density on Si with columnar
nanograined ferroelectric films. ACS Appl Mater Interfaces 2022;14:7805-13. DOI
16. Park S, Jang J, Ahn C, et al. Buffered template strategy for improving texture quality and piezoelectric properties of heterogeneous
templated grain growth (K,Na)NbO -based ceramics through interface engineering. J Eur Ceram Soc 2023;43:1932-40. DOI
3
17. Yuan M, Zhang W, Wang X, Pan W, Wang L, Ouyang J. In situ preparation of high dielectric constant, low-loss ferroelectric BaTiO 3
films on Si at 500 °C. Appl Surf Sci 2013;270:319-23. DOI
18. Wakiya N, Azuma T, Shinozaki K, Mizutani N. Low-temperature epitaxial growth of conductive LaNiO thin films by RF magnetron
3
sputtering. Thin Solid Films 2002;410:114-20. DOI
19. Zhang W, Cheng H, Yang Q, Hu F, Ouyang J. Crystallographic orientation dependent dielectric properties of epitaxial BaTiO thin
3
films. Ceram Int 2016;42:4400-5. DOI
20. Xu F, Trolier-mckinstry S, Ren W, Xu B, Xie Z, Hemker KJ. Domain wall motion and its contribution to the dielectric and
piezoelectric properties of lead zirconate titanate films. J Appl Phys 2001;89:1336-48. DOI
21. Burn I, Smyth DM. Energy storage in ceramic dielectrics. J Mater Sci 1972;7:339-43. DOI

10 11 12 13 14 15 16 17 18 19 20