Manipulate emergent physical properties of complex oxide via multiple external stimuli and quantum confinement effect

Complex oxides system displays exotic properties such as high temperature superconductivity, colossal magnetoresistance and multiferroics. Owing to the strong correlation between lattice, spin, charge and orbital degrees of freedom, competing electronic states in complex oxides system often have close energy scales leading to rich phase diagrams and spatial coexistence of different electronic phases known as electronic phase separation (EPS). When the dimension of complex oxides system is reduced to the length scale of the correlation length of the EPS, one would expect fundamental changes of the correlated behavior. This offers a way to control the physical properties in the EPS system.

In Shen lab, we manipulate emergent physical properties of complex oxide via multiple external stimuli and quantum confinement effect. We discovered a pronounced ferromagnetic edge state in manganite strips; By using lithographic techniques, we also fabricated antidot arrays in manganite, which show strongly enhanced metal-insulator transition temperature and reduced resistance. Moreover, we discovered a spatial confinement-induced transition from an EPS state featuring coexistence of ferromagnetic metallic and charge order insulating phases to a single ferromagnetic metallic state in manganite. In addition, by using unit cell by unit cell superlattice growth technique, we determined the role of chemical ordering of the dopant in manganite. We show that spatial distribution of the chemical dopants has strong influence on their EPS and physical properties. These works open a new way to manipulate EPS and thus the global physical properties of the complex oxides systems, which is potentially useful for oxides electronic and spintronic device applications.


References

1. K. Du, K. Zhang, S. Dong, W. G. Wei, J. Shao, J. B. Niu, J. J. Chen, Y. Y. Zhu, H. X. Lin, X. L. Yin, S. H. Liou, L. F. Yin, J. Shen. Visualization of a ferromagnetic metallic edge state in manganite strips. Nat. Commun. 6, 6179 (2015).

2. K. Zhang, K. Du, H. Liu, X. G. Zhang, F. L. Lan, H. X. Lin, W. G. Wei, Y. Y. Zhu, Y. F. Kou, J. Shao, J. B. Niu, W. B. Wang, R. Q. Wu, L. F. Yin, E. W. Plummer, J. Shen. Manipulating electronic phase separation in strongly correlated oxides with an ordered array of antidots. Proc. Natl. Acad. Sci. U. S. A. 112, 9558-9562 (2015).

3. J. Shao, H. Liu, K. Zhang, Y. Yu, W. C. Yu, H. X. Lin, J. B. Niu, K. Du, Y. F. Kou, W. G. Wei, F. L. Lan, Y. Y. Zhu, W. B. Wang, J. Xiao, L. F. Yin, E. W. Plummer, J. Shen. Emerging single-phase state in small manganite nanodisks. Proc. Natl. Acad. Sci. U. S. A. 113, 9228-9231 (2016).

4. Y. Y. Zhu, K. Du, J. B. Niu, L. F. Lin, W. G. Wei, H. Liu, H. X. Lin, K. Zhang, T. Y. Yang, Y. F. Kou, J. Shao, X. Y. Gao, X. S. Xu, X. S. Wu, S. Dong, L. F. Yin, J. Shen. Chemical ordering suppresses large-scale electronic phase separation in doped manganites. Nat. Commun. 7, 11260 (2016).

5. H. X. Lin, H. Liu, L. F. Lin, S. Dong, H. Y. Chen, Y. Bai, T. Miao, Y. Yu, W. C. Yu, J. Tang, Y. Y. Zhu, Y. F. Kou, J. B. Niu, Z. H. Cheng, J. Xiao, W. B. Wang, E. Dagotto, L. F. Yin, J. Shen. Unexpected Intermediate State Photoinduced in the Metal-Insulator Transition of Submicrometer Phase-Separated Manganites. Phys. Rev. Lett. 120, 267202 (2018).

6. Q. Shi, F. X. Jiang, Y. Yu, H. X. Lin, Y. F. Kou, T. Miao, H. Liu, W. T. Yang, W. B. Wang, P. Cai, X. H. Xu, H. W. Guo, L. F. Yin, J. Shen. An Electric-Field-Controlled High-Speed Coexisting Multibit Memory and Boolean Logic Operations in Manganite Nanowire via Local Gating. Adv. Electron. Mater. 5, 1900020 (2019).

7. W. T. Yang, Q. Shi, T. Miao, Q. Li, P. Cai, H. Liu, H. X. Lin, Y. Bai, Y. Y. Zhu, Y. Yu, L. Deng, W. B. Wang, L. F. Yin, D. L. Sun, X. G. Zhang, J. Shen. Achieving large and nonvolatile tunable magnetoresistance in organic spin valves using electronic phase separated manganites. Nat. Commun. 10, 3877 (2019).

8. T. Miao, L. N. Deng, W. T. Yang, J. Y. Ni, C. L. Zheng, J. Etheridge, S. S. Wang, H. Liu, H. X. Lin, Y. Yu, Q. Shi, P. Cai, Y. Y. Zhu, T. Y. Yang, X. M. Zhang, X. Y. Gao, C. Y. Xi, M. L. Tian, X. S. Wu, H. J. Xiang, E. Dagotto, L. F. Yin, J. Shen. Direct experimental evidence of physical origin of electronic phase separation in manganites. Proc. Natl. Acad. Sci. U. S. A. 117, 7090-7094 (2020).

9. Q. Li, T. Miao, H. M. Zhang, W. Y. Lin, W. H. He, Y. Zhong, L. F. Xiang, L. N. Deng, B. Y. Ye, Q. Shi, Y. Y. Zhu, H. W. Guo, W. B. Wang, C. L. Zheng, L. F. Yin, X. D. Zhou, H. J. Xiang, J. Shen. Electronically phase separated nano-network in antiferromagnetic insulating LaMnO3/PrMnO3/CaMnO3 tricolor superlattice. Nat. Commun. 13, 86593 (2022) .

10. W. Y. Lin, H. Y. Zhang, Y. Kalcheim, X. C. Zhou, F. B. Yang, Y. Shi, Y. Feng, Y. H. Wang, J. P. Huang, I. K. Schuller, X. D. Zhou, J. Shen. Direct visualization of percolating metal-insulator transition in V2O3 using scanning microwave impedance microscopy. Sci. China Phys. Mech. 65, 297411 (2022).

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