Cui-Zu Chang | Eberly College of Science (2024)

Selected Publications

(A complete list is available here) (^#corresponding authors, *equal first authors).

[1]. Interface-Induced Superconductivity in Magnetic Topological Insulators

H. Yi*, Y.-F. Zhao*, Y.-T. Chan*, J. Cai*, R. Mei, X. Wu, Z.-J. Yan, L.-J. Zhou, R. Zhang, Z. Wang, S. Paolini, R. Xiao, K. Wang, A. R. Richardella, J. Singleton, L. E. Winter, T. Prokscha, Z. Salman, A. Suter, P. P. Balakrishnan, A. J. Grutter, M. H. W. Chan, N. Samarth, X. Xu, W. Wu^#, C.-X. Liu^#, and C.-Z. Chang^#

Science (2024, in press).

[2]. Electrical switching of the edge current chirality in quantum anomalous Hall insulators

W. Yuan*, L.-J. Zhou*, K. Yang, Y.-F. Zhao, R. Zhang, Z. Yan, D. Zhuo, R. Mei, M. H. W. Chan, M. Kayyalha, C.-X. Liu^#, and C.-Z. Chang^#

Nature Mater. 23, 58-64 (2024).

[3]. Confinement-induced chiral edge channel interaction in quantum anomalous hall insulators

L.-J. Zhou*, R. Mei*, Y.-F. Zhao*, R. Zhang, D. Zhuo, Z. Yan, W. Yuan, M. Kayyalha, M. H. W. Chan, C.-X. Liu^#, and C.-Z. Chang^#

Phys.Rev.Lett.130,086201(2023).

[4]. Axion Insulator State in Hundred-Nanometer-Thick Magnetic Topological Insulator Sandwich Heterostructures

D. Zhuo*, Z.-J. Yan*, L.-J. Zhou, Z.-T. Sun, Y.-F. Zhao, R. Zhang, H. Yi, K. Wang, M. H. W. Chan, C.-X. Liu, K. T. Law^#, and C.-Z. Chang^#

Nature Commun. 14, 7596 (2023).

[5]. Dirac-fermion-assisted interfacial superconductivity in epitaxial topological-insulator/iron-chalcogenide heterostructures

H. Yi*, L.-H. Hu*, X. Wu, Y.-F. Zhao, L.-J. Zhou, Z. Yan, R. Zhang, W. Yuan, Z. Wang, D. R. Hickey, A. R. Richardella, J. Singleton, L. E. Winter, M. H. W. Chan, N. Samarth, C.-X. Liu, and C.-Z. Chang^#

Nature Commun.14, 7119(2023).

[6]. Creation of chiral interface channels for quantized transport in magnetic topological insulator multilayer heterostructures

Y.-F. Zhao*, R. Zhang*, J. Cai, D. Zhuo, L.-J. Zhou, Z.-J. Yan, M. H. W. Chan, X. Xu, and C.-Z. Chang^#

NatureCommun.14, 770(2023).

[7]. Colloquium: Quantum anomalous Hall effect

C.-Z. Chang^#, C.-X. Liu^#, andA. H. MacDonald^#

Rev. Mod. Phys. 95, 011002 (2023).

[8]. Crossover from Ising-to Rashba-type superconductivity in epitaxial Bi₂Se₃/monolayer NbSe₂ heterostructures

H. Yi*, L.-H. Hu*, Y. Wang*, R. Xiao, J. Cai, D. R. Hickey, C. Dong, Y.-F. Zhao, L.-J.ie Zhou, R. Zhang, A. R. Richardella, J. A. Robinson, M. H. W. Chan, X. Xu, N. Samarth, C.-X. Liu, and C.-Z. Chang^#

Nature Mater. 21, 1366(2022).

[9]. Zero magnetic field plateau phase transition in higher Chern number quantum anomalous Hall insulators

Y.-F. Zhao*, R. Zhang*, L.-J. Zhou, R. Mei, Z.-J. Yan, M. H. W. Chan, C.-X. Liu, andC.-Z. Chang^#

Phys. Rev. Lett. 128, 216801(2022).

[10]. Interface-Induced Sign Reversal of the Anomalous Hall Effect in Magnetic Topological Insulator Heterostructures

F. Wang*, X. Wang*, Y.-F. Zhao*, D. Xiao, L.-J. Zhou, W. Liu, Z. Zhang, W. Zhao, M. H. W. Chan, N. Samarth, C. Liu, H. Zhang#,andC.-Z. Chang^#

Nature Commun.12,79 (2021).

[11]. Tuning the Chern Number in Quantum Anomalous Hall Insulators

Y.-F. Zhao*, R. Zhang*, R. Mei*, L.-J. Zhou, H. Yi, Y.-Q. Zhang, J. Yu, R. Xiao, K. Wang, N. Samarth, M. H. W. Chan, C.-X. Liu^#, andC.-Z. Chang^#

Nature588, 419-423(2020).

[12]. Scaling Behavior of the Quantum Phase Transition from a Quantum Anomalous Hall Insulator to an Axion Insulator

X. Wu, D. Xiao, C.-Z. Chen, J. Sun, L. Zhang, M. H. W. Chan, N. Samarth, X. C. Xie, X. Lin^#, and C.-Z. Chang^#

Nature Commun. 11, 4532 (2020).

[13]. Concurrence of Quantum Anomalous Hall and Topological Hall Effects in Magnetic Topological Insulator Sandwich Heterostructures

J. Jiang*, D. Xiao*, F. Wang, J.-H. Shin, D. Andreoli, J. Zhang, R. Xiao, Y.-F. Zhao, M. Kayyalha, L. Zhang, K. Wang, J. Zang, C. Liu, N. Samarth^#, M. H. W. Chan^#, and C.-Z. Chang^#

Nature Mater. 19,732–737 (2020).

[14]. Absence of Evidence for Chiral Majorana Modes in Quantum Anomalous Hall-Superconductor Devices

M. Kayyalha*, D. Xiao*, R. Zhang*, J. Shin, J. Jiang, F. Wang, Y.-F. Zhao, L. Zhang, K. M. Fijalkowski, P. Mandal, M. Winnerlein, C. Gould, Q. Li, L. W. Molenkamp, M. H. W. Chan^#, N. Samarth^#, and C.-Z. Chang^#

Science 367, 64-67(2020).

[15]. Realization of the Axion Insulator State in Quantum Anomalous Hall Sandwich Heterostructures

D. Xiao*, J. Jiang*, J.-H. Shin, W. Wang, F. Wang, Y.-F. Zhao, C. Liu, W. Wu, M. H. W. Chan^#, N. Samarth^#, and C.-Z. Chang^#

Phys. Rev. Lett. 120, 056801 (2018) (Editors’ Suggestion).

[16]. Observation of the quantum phase transition from quantum anomalous Hall insulator to Anderson insulator and its scaling behavior

C.-Z. Chang*, W. Zhao*, J. Li*, J. K. Jain, C. Liu, J. S. Moodera, and M. H. W. Chan

Phys. Rev. Lett.117, 126802 (2016)(Editors’ Suggestion).

[17]. High-precision realization of robust quantum anomalous Hall state in a hard ferromagnetic topological insulator

C.-Z. Chang^#, W. Zhao^#, D. Kim, H. Zhang, B. A. Assaf, D. Heiman, S. C. Zhang, C. Liu, M. H. W. Chan, and J. S. Moodera^#

Nature Mater.14, 473 (2015).

[18]. Zero-field dissipationless chiral edge transport and the nature of dissipation in the quantum anomalous Hall state

C.-Z. Chang*^#, W. Zhao*, D. Kim, P. Wei, J. K. Jain, C. Liu, M. H. W. Chan^#, and J. S. Moodera^#

Phys. Rev. Lett.115, 057206 (2015).

[19]. Band engineering of Dirac surface states in topological insulators-based van der Waals heterostructures

C.-Z. Chang^#, P. Z. Tang, X. Feng, K. Li, X. Ma,W. H. Duan^#, K. He^#,and Q. K. Xue

Phys. Rev. Lett.115, 136801 (2015).

[20]. Chemical-Potential-Dependent Gap Opening at the Dirac Surface States ofBi₂Se₃Induced by Aggregated Substitutional Cr Atoms

C.-Z. Chang*, P. Z. Tang*, Y. L. Wang, X. Feng, K. Li, Z. Zhang, Y. Wang, L. Wang, X. Chen, C. X. Liu, W. H. Duan, K. He, X. Ma, and Q. K. Xue

Phys. Rev. Lett.112, 056801 (2014).

[21]. Experimental observation of the quantum anomalous Hall effect in a magnetic topological insulator

C.-Z. Chang*,J. Zhang*, X. Feng*, J. Shen*, Z. Zhang, M. H. Guo, K. Li, Y. B. Ou, P. Wei, L. Wang, Z. Q. Ji, Y. Feng, S. H. Ji, X. Chen, J. F. Jia, X. Dai, Z. Fang, S.C. Zhang, K. He, Y. Wang, L. Lu, X. C. Ma, and Q. K. Xue

Science340, 167 (2013)

This work was featured in the scientific background of the 2016 Nobel Prize in Physics for Haldane, Kosterlitz, and Thouless.