简介:
2018年12月起,加入中国科学院物理研究所担任副研究员。2014年毕业于澳大利亚卧龙岗大学,获得博士学位,期间获得国家留学基金委颁发的“2012年度国家优秀自费留学生奖学金”;2014-2018期间,先后在北京高压科学研究中心和美国劳伦斯伯克利国家实验室从事博士后研究。
主要研究方向:
主要关注高压条件下物质的相变行为、相变机理、基本物理性质(光学、电学等)的演化和调控,及其与结构的关联;结合实验室常规手段和同步辐射高压技术,探索物质在高压环境下的新现象。
代表性论文及专利:
一、关联电子体系的高压物性研究和调控
[12] X. Ma, E. Karaca, H. Zhang, W. Zhong, S. Kawaguchi, H. Kadobayashi, X. Yu*, B. Yue*, D. Errandonea*, and F. Hong*, Lifshitz transition and superconductivity in Bi2S3 powder via interchain bonding under quasihydrostatic pressure, Phys. Rev. B 110, 245143 (2024).
[11] Y. Meng, Y. Yang, H. Sun, S. Zhang, J. Luo, L. Chen, X. Ma, M. Wang*, F. Hong*, X. Wang*, and X.H. Yu*, Density-wave-like gap evolution in La3Ni2O7 under high pressure revealed by ultrafast optical spectroscopy, Nature Commun. 15, 10408 (2024)
[10] Y. L. Wu, X. H. Yu, J. Z. L. Hasaien, F. Hong*, P. F. Shan, Z. Y. Tian, Y. N. Zhai, J. P. Hu, J. G. Cheng*, and J. Zhao*, Ultrafast dynamics evidence of strong coupling superconductivity in LaH10±δ, Nature Commun. 15, 9683 (2024).
[9] J. Zhou, W. Zhong, H. Zhang, S. Kawaguchi, H. Kadobayashi, X. Yu, B. Yue*, and F. Hong*, Absence of metallic ground state across the spin state transition in crystalline MnS2 under pressure, Phys. Rev. B 110, 165204 (2024).
[8] L. Wu., J. Si, S. Guan, H. Zhang, J.Dou, J. Luo, J. Yang, H. Yu, J. Zhang, X. Ma, P. Yang, R. Zhou, M. Liu*, F. Hong*, X. Yu*, Record-High Tc and Dome-Shaped Superconductivity in a Medium-Entropy Alloy TaNbHfZr under Pressure up to 160 GPa, Phys. Rev. Lett. 132, 166002 (2024)
[7] H. Zhang, W. Zhong, Y. Meng, B. Tang, B. Yue*, X. Yu*, and F. Hong*, Helicity transitions and emerging superconductivity in chiral a-HgS, Phys. Rev. B 110, L060502 (2024).
[6] B. Yue*, W. Zhong, W. Deng, T. Wen, Y. Wang, Y. Yin, P. Shan, J.-T. Wang, X. Yu*, F. Hong*, Insulator-to-Superconductor Transition in Quasi-One-Dimensional HfS3 under Pressure; J. Am. Chem. Soc., 145, 1301-1309 (2023)
[5] B. Yue*, W. Zhong, T. Wen, Y. Wang, H. Yu, X. Yu, C. Chen, J.-T. Wang*, F. Hong*, Pressure-induced ferroelectric-to-superconductor transition in SnPS3; Phys. Rev. B, 107, L140501 (2023).
[4] H. Zhang, W. Zhong, Y. Meng, B. Yue*, X. Yu*, J.-T. Wang, and F. Hong*, Superconductivity above 12 K with possible multiband features in CsCl-type PbS; Phys. Rev. B, 107, 174502 (2023)
[3] F. Hong, P. F. Shan, L. X. Yang, B. B. Yue, P. T. Yang, Z. Y. Liu, J. P. Sun, J. H. Dai, H. Yu, Y. Y. Yin, X. H. Yu, J. G. Cheng, Z. X. Zhao, Possible superconductivity at ∼70 K in tin hydride SnHx under high pressure; Materials Today Physics, 22, 100596 (2022)
[2] Y. Yin, X. Ma, D. Yan, C. Yi, B. Yue, J. Dai, L. Zhao, X. Yu, Y. Shi*, J.-T. Wang*, F. Hong*, Pressure-driven electronic and structural phase transition in intrinsic magnetic topological insulator MnSb2Te4; Phys. Rev. B, 104, 174114 (2021)
[1] F. Hong, L.X. Yang, P.F. Shan, P.T. Yang, Z.Y. Liu, J.P. Sun, Y.Y. Yin, X.H. Yu, J.G. Cheng, Z.X. Zhao, Superconductivity of Lanthanum Superhydride Investigated Using the Standard Four-Probe Configuration under High Pressures; Chin. Phys. Lett., 37, 107401 (2020)
二、二维材料及其异质结在高压下的物性研究
[9] H. Zhang, W. Zhong, B. Yue*, X. Yu*, and F. Hong*, Anomalous metal-semiconductor transition and superconductivity in van der Waals TiS2 under pressure, Phys. Rev. B 110, 134525 (2024).
[8] B. Yue*, W. Zhong, H. Zhang, J. Zhou, J. Miao, S. Kawaguchi, H. Kadobayashi, and F. Hong*, Pressure-induced superconductivity in quasi-one-dimensional ZrS3, Phys. Rev. B 110, 144515 (2024).
[7] W. Zhong, H. Zhang, E. Karaca, J. Zhou, S. Kawaguchi, H. Kadobayashi, X. Yu, D. Errandonea, B. Yue*, and F. Hong*, Pressure-Sensitive Multiple Superconducting Phases and Their Structural Origin in Van der Waals HfS2 Up to 160 GPa, Phys. Rev. Lett. 133, 066001 (2024).
[6] H. Zhang, W. Zhong, X. Yu*, B. Yue*, and F. Hong*, Electronic phase transitions and superconductivity in ferroelectric Sn2P2Se6 under pressure, Phys. Rev. B 109, 214517 (2024).
[5] W. Zhong, W. Deng, F. Hong*, and B. Yue*, Structural and electronic phase transition in the van der Waals crystal HfS2 under high pressure; Phys. Rev. B, 107, 134118 (2023)
[4] B. Yue*, W. Zhong, X. Yu, F. Hong*, Superconductivity in the van der Waals crystal SnS2 up to 105 GPa; Phys. Rev. B, 105, 104514 (2022)
[3] X. Ma, S. Fu, J. Ding, M. Liu, A. Bian, F. Hong*, J.T. Sun*, X.X. Zhang*, X.H. Yu*, D.W. He, Robust Interlayer Exciton in WS2/MoSe2 van der Waals Heterostructure under High Pressure; Nano Letters, 21, 8035-8042 (2021)
[2] X. Ma, Y. Wang, Y. Yin, B. Yue, J. Dai, J. Cheng, J. Ji, F. Jin, F. Hong*, J.-T. Wang*, Q. Zhang*, X. Yu*, Dimensional crossover tuned by pressure in layered magnetic NiPS3; Science China Physics, Mechanics & Astronomy, 64, 1-8 (2021)
[1] L. Zhao, C. Yi, C.-T. Wang, Z. Chi, Y. Yin, X. Ma, J. Dai, P. Yang, B. Yue, J. Cheng, F. Hong, J.-T. Wang, Y. Han, Y. Shi, X. Yu, Monoclinic EuSn2As2: A Novel High-Pressure Network Structure; Phys. Rev. Lett., 126, 155701 (2021)
三、高压结构相变行为及其机理研究
[6] J. Zhou, F. Peng*, F. Hong*, and B. Yue*, Dislocation-mediated ultrahigh mechanical properties in nano-TiN, Phys. Rev. Mater. 8, 036001 (2024)
[5] B. Yue*, M. Krug, C. Sanchez-Valle, S. Merkel*, F. Hong*, Deformation and slip systems of CaCl2-type MnO2 under high pressure; Phys. Rev. Mater., 6, 053603 (2022)
[4] B. Yue*, W. Dai, X. Zhang, H. Zhang, W. Zhong, B. Liu, S. Kawaguchi, F. Hong*, Deformation behavior of high-entropy oxide (Mg, Co, Ni, Cu, Zn) O under extreme compression; Scr. Mater., 219, 114879 (2022)
[3] C. Zhang, B. Yue, U. Bhandari, O. N. Starovoytov, Y. Yang, D. P. Young, J. Yan, F. Hong*, S. Yang*; In situ study on the compression deformation of MoNbTaVW high-entropy alloy; J. Alloys. Compd., 871, 159557 (2021).
[2] B. Yue#, F. Hong#, N. Hirao, R. Vasin, H.-R. Wenk, B. Chen, H.-K. Mao, A simple variant selection in stress-driven martensitic transformation; Proc. Natl. Acad. Sci., 116, 14905-14909 (2019)
[1] B. Yue, F. Hong*, S. Merkel*, D. Tan, J. Yan, B. Chen*, H.-K. Mao, Deformation Behavior across the Zircon-Scheelite Phase Transition; Phys. Rev. Lett., 117, 135701 (2016)
目前的研究课题及展望:
目前,主要从事以下3个方面的课题研究:
1、关联电子体系的高压物性研究和调控
2、二维材料及其异质结在高压下的物性研究
3、高压结构相变行为及其机理研究
通过对结构的系统研究,从而获得结构和物性之间的关联,进而促进对复杂材料体系的有效调控。
其他联系方式:
010-81258550
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