Your search keyword '"Zheng Duan"' showing total 5 results

1. Electric-field control of ferromagnetism through oxygen ion gating

Author

Hao-Bo Li, Nianpeng Lu, Qinghua Zhang, Yujia Wang, Deqiang Feng, Tianzhe Chen, Shuzhen Yang, Zheng Duan, Zhuolu Li, Yujun Shi, Weichao Wang, Wei-Hua Wang, Kui Jin, Hui Liu, Jing Ma, Lin Gu, Cewen Nan, and Pu Yu

Subjects

Science

Abstract

It has been suggested that the magnetic properties of metal layers using reversible redox reactions could form the basis of memory devices but this requires fast electric control to be practical. Here the authors demonstrate this on sub-millisecond timescales in a metal–oxide heterostructure.

Published

2017

2. Publisher Correction: Electric-field control of ferromagnetism through oxygen ion gating

Author

Hao-Bo Li, Nianpeng Lu, Qinghua Zhang, Yujia Wang, Deqiang Feng, Tianzhe Chen, Shuzhen Yang, Zheng Duan, Zhuolu Li, Yujun Shi, Weichao Wang, Wei-Hua Wang, Kui Jin, Hui Liu, Jing Ma, Lin Gu, Cewen Nan, and Pu Yu

Subjects

Science

Abstract

In the original version of this Article, Figs. 4c and 4d contained incorrectly sized error bars. This has now been corrected in both the PDF and HTML versions of the Article

Published

2018

3. Complex phase transitions and phase engineering in the aqueous solution of an isopolyoxometalate cluster

Author

Zhi-Da Wang, Song Liang, Yuqing Yang, Zhen-Ning Liu, Xiao-Zheng Duan, Xinpei Li, Tianbo Liu, and Hong-Ying Zang

Subjects

Multidisciplinary, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology

Abstract

Inorganic salts usually demonstrate simple phasal behaviors in dilute aqueous solution mainly involving soluble (homogeneous) and insoluble (macrophase separation) scenarios. Herein, we report the discovery of complex phase behavior involving multiple phase transitions of clear solution – macrophase separation – gelation – solution – macrophase separation in the dilute aqueous solutions of a structurally well-defined molecular cluster [Mo7O24]6− macroanions with the continuous addition of Fe3+. No chemical reaction was involved. The transitions are closely related to the strong electrostatic interaction between [Mo7O24]6− and their Fe3+ counterions, the counterion-mediated attraction and the consequent charge inversion, leading to the formation of linear/branched supramolecular structures, as confirmed by experimental results and molecular dynamics simulations. The rich phase behavior demonstrated by the inorganic cluster [Mo7O24]6− expands our understanding of nanoscale ions in solution.

Published

2023

4. Electric-field control of ferromagnetism through oxygen ion gating

Author

Zheng Duan, Nianpeng Lu, Weichao Wang, Wei-Hua Wang, Ce-Wen Nan, Yujia Wang, Pu Yu, Tianzhe Chen, Yujun Shi, Hao-Bo Li, Qinghua Zhang, Hui Liu, Zhuolu Li, Shuzhen Yang, Deqiang Feng, Kui Jin, Jing Ma, and Lin Gu

Subjects

Materials science, Science, Oxide, General Physics and Astronomy, 02 engineering and technology, Gating, 01 natural sciences, Redox, Article, General Biochemistry, Genetics and Molecular Biology, Metal, Condensed Matter::Materials Science, chemistry.chemical_compound, Electric field, 0103 physical sciences, 010306 general physics, lcsh:Science, Multidisciplinary, Heterojunction, General Chemistry, 021001 nanoscience & nanotechnology, Coupling (electronics), Ferromagnetism, chemistry, Chemical physics, visual_art, visual_art.visual_art_medium, lcsh:Q, 0210 nano-technology

Abstract

Electric-field-driven oxygen ion evolution in the metal/oxide heterostructures emerges as an effective approach to achieve the electric-field control of ferromagnetism. However, the involved redox reaction of the metal layer typically requires extended operation time and elevated temperature condition, which greatly hinders its practical applications. Here, we achieve reversible sub-millisecond and room-temperature electric-field control of ferromagnetism in the Co layer of a Co/SrCoO2.5 system accompanied by bipolar resistance switching. In contrast to the previously reported redox reaction scenario, the oxygen ion evolution occurs only within the SrCoO2.5 layer, which serves as an oxygen ion gating layer, leading to modulation of the interfacial oxygen stoichiometry and magnetic state. This work identifies a simple and effective pathway to realize the electric-field control of ferromagnetism at room temperature, and may lead to applications that take advantage of both the resistance switching and magnetoelectric coupling., It has been suggested that the magnetic properties of metal layers using reversible redox reactions could form the basis of memory devices but this requires fast electric control to be practical. Here the authors demonstrate this on sub-millisecond timescales in a metal–oxide heterostructure.

Published

2017

5. Publisher Correction: Electric-field control of ferromagnetism through oxygen ion gating

Author

Weichao Wang, Ce-Wen Nan, Yujia Wang, Jing Ma, Zhuolu Li, Zheng Duan, Pu Yu, Tianzhe Chen, Shuzhen Yang, Qinghua Zhang, Lin Gu, Nianpeng Lu, Hao-Bo Li, Yujun Shi, Hui Liu, Deqiang Feng, Kui Jin, and Wei-Hua Wang

Subjects

Physics, Multidisciplinary, Condensed matter physics, Science, Published Erratum, General Physics and Astronomy, General Chemistry, Gating, Publisher Correction, General Biochemistry, Genetics and Molecular Biology, Ferromagnetism, Electric field, Error bar, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, Oxygen ions, lcsh:Q, lcsh:Science

Abstract

Electric-field-driven oxygen ion evolution in the metal/oxide heterostructures emerges as an effective approach to achieve the electric-field control of ferromagnetism. However, the involved redox reaction of the metal layer typically requires extended operation time and elevated temperature condition, which greatly hinders its practical applications. Here, we achieve reversible sub-millisecond and room-temperature electric-field control of ferromagnetism in the Co layer of a Co/SrCoO

Published

2018