{"id":13,"date":"2017-09-11T10:03:35","date_gmt":"2017-09-11T16:03:35","guid":{"rendered":"https:\/\/physlabs.colostate.edu\/chengroup\/?page_id=13"},"modified":"2025-08-19T12:09:01","modified_gmt":"2025-08-19T18:09:01","slug":"publications","status":"publish","type":"page","link":"https:\/\/physlabs.colostate.edu\/chengroup\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

Papers (Google Scholar<\/a>)<\/strong><\/p>\n

    \n
  1. H. Chen<\/u>, \u201cAnomalous Hall scaling revisited in noncollinear antiferromagnets\u201d, Newton<\/em> 1<\/strong>, 100100 (2025)<\/a>.<\/li>\n
  2. C. Ard<\/u>, E. Camrud, O. Pinaud, and H. Chen<\/u>, \u201cBounds and anomalies of inhomogeneous anomalous Hall effects\u201d, arXiv:2408.15195<\/a>. \u00a0Communications Physics<\/em> 8<\/strong>, 209 (2025).<\/a><\/li>\n
  3. Yejun Feng, Yishu Wang, Thomas F. Rosenbaum, Peter B. Littlewood, Hua Chen<\/u>, \u201cFermi surface origin of the low-temperature magnetoresistance anomaly\u201d, Matter<\/em> 8<\/strong>, 102105 (2025)<\/a>.<\/li>\n
  4. Luke Wernert<\/u>, Basti\u00e1n Pradenas, Oleg Tchernyshyov, and Hua Chen<\/u>, \u201cHall mass and transverse Noether spin currents in noncollinear antiferromagnets\u201d, arXiv:2404.12898<\/a>, Phys. Rev. Lett.<\/em> 134<\/strong>, 016706 (2025)<\/a>.<\/li>\n
  5. Senlei Li, Zeliang Sun, Nathan J McLaughlin, Afsana Sharmin<\/u>, Nishkarsh Agarwal, Mengqi Huang, Suk Hyun Sung, Hanyi Lu, Shaohua Yan, Hechang Lei, Robert Hovden, Hailong Wang, Hua Chen<\/u>, Liuyan Zhao, and Chunhui Rita Du, \u201cObservation of stacking engineered magnetic phase transitions within moir\u00e9 supercells of twisted van der Waals magnets\u201d, Nature Communications<\/em> 15<\/strong>, 5712 (2024)<\/a>.<\/li>\n
  6. ZhuangEn Fu, Piumi I. Samarawickrama, John Ackerman, Yanglin Zhu, Zhiqiang Mao, Kenji Watanabe, Takashi Taniguchi, Wenyong Wang, Yuri Dahnovsky, Mingzhong Wu, TeYu Chien, Jinke Tang, Allan H. MacDonald, Hua Chen<\/u>* & Jifa Tian*, \u201cTunneling current-controlled spin states in few-layer van der Waals magnets\u201d, Nature Communications<\/em> 15<\/strong>, 3630 (2024)<\/a>. (*Corresponding author)<\/li>\n
  7. Winblad<\/u> and H. Chen<\/u>, \u201cSuperconducting triangular islands as a platform for manipulating Majorana zero modes\u201d, arXiv:2309.11607<\/a>, Phys. Rev. B<\/em> 109<\/strong>, 205158 (2024)<\/a>.<\/li>\n
  8. Feng, Y. Wang, T. F. Rosenbaum, P. B. Littlewood, and H. Chen<\/u>, \u201cQuantum interference in superposed lattices\u201d, Proc. Natl. Acad. Sci.<\/em> 121<\/strong>, e2315787121 (2024)<\/a>.<\/li>\n
  9. K. Zhao*, Y. Tokiwa, H. Chen<\/u>*, and P. Gegenwart*, \u201cDiscrete degeneracies distinguished by the anomalous Hall effect in a metallic kagome ice compound\u201d, Nature Physics (2024)<\/em><\/a>. (*<\/sup>Corresponding author)<\/li>\n
  10. Tahir<\/u> and Hua Chen<\/u>, \u201cTransport of Spin Magnetic Multipole Moments Carried by Bloch Quasiparticles\u201d, Phys. Rev. Lett.<\/em>, 131, 106701 (2023).<\/li>\n
  11. Senlei Li, Mengqi Huang, Hanyi Lu, Nathan J McLaughlin, Yuxuan Xiao, Jingcheng Zhou, Eric E Fullerton, Hua Chen<\/u>, Hailong Wang, Chunhui Rita Du, \u201cNanoscale Magnetic Domains in Polycrystalline Mn3<\/sub>Sn Films Imaged by a Scanning Single-Spin Magnetometer\u201d, Nano Letters<\/em> 23<\/strong>, 5326-5333 (2023).<\/li>\n
  12. Hua Chen<\/u>, \u201cElectronic chiralization as an indicator of the anomalous Hall effect in unconventional magnetic systems\u201d, Phys. Rev. B<\/em> 106<\/strong>, 024421 (2022).<\/li>\n
  13. Gerald Q. Yan,, Senlei Li, Hanyi Lu, Mengqi Huang, Yuxuan Xiao, Luke Wernert<\/u>, \u202aJeffrey A. Brock, Eric E. Fullerton, Hua Chen<\/u>, Hailong Wang, and Chunhui Rita Du, \u201cNanoscale quantum sensing and imaging of spin-orbit-torque-driven spin dynamics in noncollinear antiferromagnet Mn3<\/sub>Sn\u201d, Advanced Materials <\/em>34<\/strong>, 2200327 (2022).<\/li>\n
  14. Ian P. Moseley, Christopher P. Ard<\/u>, Joseph A. DiVerdi, Andrew Ozarowski, Hua Chen<\/u>, and Joseph M. Zadrozny, \u201cSlowing Magnetic Relaxation with Open-Shell Diluents\u201d, Cell Reports Physical Science<\/em> 3<\/strong>, 100802 (2022).<\/li>\n
  15. Kouta Kondou, Hua Chen<\/u>, Takahiro Tomita, Muhammad Ikhlas, Tomoya Higo, Allan H MacDonald, Satoru Nakatsuji, YoshiChika Otani, \u201cGiant field-like torque by the out-of-plane magnetic spin Hall effect in a topological antiferromagnet\u201d, Nature Communications 12<\/strong>, 6491 (2021).<\/li>\n
  16. Jinjun Ding, Chuanpu Liu, Vijaysankar Kalappattil, Yuejie Zhang, Oleksandr Mosendz, Uppalaiah Erugu, Rui Yu, Jifa Tian, August DeMann, Stuart B Field, Xiaofei Yang, Haifeng Ding, Jinke Tang, Bruce Terris, Albert Fert, Hua Chen<\/u>, Mingzhong Wu, \u201cSwitching of a Magnet by Spin\u2010Orbit Torque from a Topological Dirac Semimetal\u201d, Advanced Materials<\/em> 33<\/strong>, 2005909 (2021).<\/li>\n
  17. Hua Chen<\/u>, Olivier Pinaud, and Muhammad Tahir<\/u>, \u201cA simple real-space scheme for periodic Dirac operators\u201d, Comm.\u00a0 <\/em>Math. Sci.<\/em> 19<\/strong>, 1735-1750 (2021).<\/li>\n
  18. Jinjun Ding, Chuanpu Liu, Yuejie Zhang, Vijaysankar Kalappattil, Rui Yu, Uppalaiah Erugu, Jinke Tang, Haifeng Ding, Hua Chen<\/u>, and Mingzhong Wu, \u201cLarge Damping Enhancement in Dirac-Semimetal-Ferromagnetic-Metal Layered Structures Caused by Topological Surface States\u201d, Advanced Functional Materials<\/em>, 2008411 (2021).<\/li>\n
  19. Ahmed, T., Tahir, M.<\/u>, Low, M. X., Ren, Y., Tawfik, S. A., Mayes, E. L. H., Kuriakose, S., Nawaz, S., Spencer, M. J. S., Chen, H.<\/u>, Bhaskaran, M., Sriram, S., Walia, S. \u201cFully Light-Controlled Memory and Neuromorphic Computation in Layered Black Phosphorus\u201d, Advanced Materials<\/em>, 2004207 (2020).<\/li>\n
  20. Tahir<\/u>, O. Pinaud, and H. Chen<\/u>. \u201cEmergent flat band lattices in spatially periodic magnetic fields\u201d, Phys. Rev. B<\/em>, 102<\/strong>, 035425 (2020).<\/li>\n
  21. Wang, Z. N. Nilsson, M. Tahir<\/u>, H. Chen<\/u>, and J. B. Sambur, \u201cInfluence of the Substrate on the Optical and Photo-electrochemical Properties of Monolayer MoS2<\/sub>\u201d, ACS Applied Materials & Interfaces<\/em>, 12<\/strong>, 15034-15042 (2020).<\/li>\n
  22. Xiao Li, Hua Chen<\/u>, and Qian Niu, \u201cOut-of-plane carrier spin in transition-metal dichalcogenides under electric current\u201d, Proceedings of the National Academy of Sciences<\/em>, 117<\/strong> 16749-16755 (2020).<\/li>\n
  23. Hua Chen<\/u>, Tzu-Cheng Wang, Di Xiao, Guang-Yu Guo, Qian Niu, and Allan H. MacDonald, \u201cManipulating anomalous Hall antiferromagnets with magnetic fields\u201d, Rev. B<\/em>, 101<\/strong>, 104418 (2020). (Editors\u2019 Suggestion)<\/li>\n
  24. Cong Xiao, Hua Chen<\/u>, Yang Gao, Di Xiao, Allan H. MacDonald, and Qian Niu, \u201cLinear magnetoresistance induced by intra-scattering semiclassics of Bloch electrons\u201d, Rev. B<\/em>, 101<\/strong>, 201410(R) (2020). (Rapid Communication)<\/li>\n
  25. Kan Zhao*<\/sup>, Hao Deng*<\/sup>, Hua Chen<\/u>*<\/sup>, Kate A. Ross, Vaclav Pet\u0159\u00ed\u010dek, Vladimir Hutanu, and Philipp Gegenwart, \u201cDiscovery of kagome spin ice with crystallized magnetic monopoles in an intermetallic compound\u201d, Science<\/em> 367<\/strong>, 1218-1223 (2020). (*<\/sup>Joint first author)<\/li>\n
  26. Li Wang, Tahir<\/u>, Hua Chen<\/u>, and Justin B. Sambur, \u201cProbing Charge Carrier Transport and Recombination Pathways in Monolayer MoS2<\/sub>\/WS2<\/sub> Heterojunction Photoelectrodes\u201d, Nano Letters<\/em> 19<\/strong>, 9084 (2019).<\/li>\n
  27. Li Wang, Merranda Schmid, Muhammad Tahir<\/u>, Hua Chen<\/u>, and Justin Sambur, \u201cLaser Annealing Improves Photoelectrochemical Activity of Ultrathin MoSe2<\/sub> Photoelectrodes\u201d, ACS Appl. Mater. Interfaces<\/em>, 11<\/strong>, 19207 (2019).<\/li>\n
  28. Kan Zhao, T. Hajiri, Hua Chen<\/u>, R. Miki, H. Asano, and P. Gegenwart, \u201cAnomalous Hall effect in the noncollinear antiferromagnetic antiperovskite Mn3<\/sub>Ni1-x<\/em><\/sub>Cux<\/sub><\/em>N\u201d Rev. B<\/em> 100<\/strong>, 045109 (2019).<\/li>\n
  29. Motoi Kimata, Hua Chen<\/u>, Kouta Kondou, Satoshi Sugimoto, Prasanta K. Muduli, Muhammad Ikhlas, Yasutomo Omori, Takahiro Tomita, Allan. H. MacDonald, Satoru Nakatsuji & Yoshichika Otani, \u201cMagnetic and magnetic inverse spin Hall effects in a non-collinear antiferromagnet\u201d, Nature<\/em> 565<\/strong>, 627-630 (2019).<\/li>\n
  30. Hyoungdo Nam, Hua Chen<\/u>, Philip W. Adams, Syu-You Guan, Tien-Ming Chuang, Chia-Seng Chang, Allan H. MacDonald & Chih-Kang Shih, \u201cGeometric quenching of orbital pair breaking in a single crystalline superconducting nanomesh network\u201d, Nature Communications<\/em> 9<\/strong>, 5431 (2018).<\/li>\n
  31. Q. Liu, H. Chen<\/u>, J. M. Wang, J. H. Liu, K. Wang, Z. X. Feng, H. Yang, X. R. Wang, C. B. Jiang, J. M. D. Coey, and A. H. MacDonald, \u201cElectrical Switching of the Topological Anomalous Hall Effect in a Noncollinear Antiferromagnet above Room Temperature\u201d, Nature Electronics<\/em>, 1<\/strong>, 172-177 (2018). Accompanying News & Views by Christoph S\u00fcrgers.<\/li>\n
  32. Chao Lei, Hua Chen<\/u>, and Allan H. MacDonald, \u201cUltrathin Films of Superconducting Metals as a Platform for Topological Superconductivity\u201d, Physical Review Letters<\/em> 121<\/strong>, 227701 (2018).<\/li>\n
  33. Bangguo Xiong, Hua Chen<\/u>, Xiao Li, and Qian Niu, \u201cGeometric Dynamics of Magnetization: Electronic Contribution\u201d, Physical Review B<\/em> 98<\/strong>, 035123 (2018).<\/li>\n
  34. Ping Li, Xiao Li, Wei Zhao, Hua Chen<\/u>, Ming-Xing Chen, Zhi-Xin Guo, Ji Feng, Xingao Gong, and Allan H. MacDonald, \u201cTopological Dirac states beyond \u03c0 orbitals for silicene on SiC(0001) surface\u201d, Nano Letters<\/em> 17<\/strong>, 6195 (2017).<\/li>\n
  35. Xianzhe Chen, Hao Liu, Hua Chen<\/u>, Y. Z. Tan, Miao Jiang, Xiangjun Zhou, Lifeng Yin, Cheng Song, and Feng Pan, \u201cDomain wall Hall effect during antiferromagntic to ferromagnetic phase transition\u201d, Journal of Physics D: Applied Physics<\/em> 50<\/strong>, 505004 (2017).<\/li>\n
  36. Alejandro Jara, Igor Barsukov, Brian Youngblood, Yu-Jin Chen, John Read,\u00a0Hua Chen<\/u>, Patrick Braganca, and Ilya Krivorotov, “Highly textured IrMn3<\/sub>(111) thin films grown by magnetron sputtering”,\u00a0IEEE Magnetics Letters<\/em> 7<\/strong>, 3104805 (2016)<\/a>.<\/li>\n
  37. D. Nam, Hua Chen<\/u>, T. J. Liu, J. S. Kim, C. D. Zhang, J. Yong, T. R. Lemberger, P. A. Kratz, J. R. Kirtley, K. A. Moler, P. W. Adams, A. H. MacDonald, and C. K. Shih, \u201cUltrathin Two-Dimensional Superconductivity with Strong Spin-Orbit Coupling\u201d, Proceedings of the National Academy of Sciences<\/em> 113<\/strong>, 10513-10517 (2016)<\/a>.<\/li>\n
  38. Yufeng Hao, Lei Wang, Yuanyue Liu, Hua Chen<\/u>, Xiaohan Wang, Cheng Tan, Shu Nie, Ji Won Suk, Tengfei Jiang, Tengfei Liang, Junfeng Xiao, Wenjing Ye, Cory R. Dean, Boris I. Yakobson, Kevin F. McCarty, Philip Kim, James Hone, Luigi Colombo, and Rodney S. Ruoff, \u201cOxygen-Activated Growth of Large Single-Crystal Bilayer Graphene on Copper\u201d, Nature Nanotechnology<\/em> 11<\/strong>, 426-431 (2016)<\/a> (Cover Article<\/a>).<\/li>\n
  39. Shifei Qi, Zhenhua Qiao, Xinzhou Deng, Ekin Cubuk, Hua Chen<\/u>, Wenguang Zhu, Efthimios Kaxiras, Shengbai Zhang, Xiaohong Xu, and Zhenyu Zhang, \u201cHigh-Temperature Quantum Anomalous Hall Effect in n<\/em>–p<\/em> codoped topological insulators\u201d, Physical Review Letters<\/em> 117<\/strong>, 056804 (2016)<\/a>.<\/li>\n
  40. Hua Chen<\/u> and Allan H. MacDonald, \u201cSpin-Superfluidity and Spin-Current Mediated Non-Local Transport\u201d, arXiv:1604.02429.<\/li>\n
  41. Zhe Wang, Dong-Keun Ki, Hua Chen<\/u>, Helmuth Berger, Allan H. MacDonald and Alberto Morpurgo, \u201cStrong interface-induced spin-orbit coupling in graphene on WS2<\/sub>\u201d, Nature Communications<\/em> 6<\/strong>, 8339 (2015)<\/a>.<\/li>\n
  42. Jian Li*<\/sup>, Hua Chen<\/u>*<\/sup>, Ilya K. Drozdov, Ali Yazdani, B. Andrei Bernevig, and Allan H. MacDonald, \u201cTopological Superconductivity induced by Ferromagnetic Metal Chains\u201d, Physical Review B<\/em> 90<\/strong>, 235433 (2014)<\/a>. (*<\/sup>Joint first author) (Editors\u2019 Suggestion)<\/li>\n
  43. Inti Sodemann, Hua Chen<\/u>, and Allan H. MacDonald, \u201cTheory of Transport Phenomena in Coherent Quantum Hall Bilayers\u201d, arXiv:1411.0008<\/a>.<\/li>\n
  44. Hua Chen<\/u>, Andrew D. Kent, Allan H. MacDonald, and Inti Sodemann, \u201cNon-Local Transport Mediated by Spin-Supercurrents\u201d, Physical Review B<\/em> 90<\/strong>, 220401(R) (2014)<\/a>.<\/li>\n
  45. Stevan Nadj-Perge*<\/sup>, Ilya K. Drozdov*<\/sup>, Jian Li*<\/sup>, Hua Chen<\/u>*<\/sup>, Sangjun Jeon, Jungpil Seo, Allan H. MacDonald, B. A. Bernevig, and Ali Yazdani, \u201cObservation of Majorana Fermions in Ferromagnetic Atomic Chains on a Superconductor\u201d, Science<\/em> 346<\/strong>, 602 (2014)<\/a>. (*<\/sup>Joint first author)<\/li>\n
  46. Zhenhua Qiao, Wei Ren, Hua Chen<\/u>, L. Bellaiche, Zhenyu Zhang, Allan H. MacDonald, and Qian Niu, \u201cQuantum Anomalous Hall Effect in Graphene Proximity Coupled to an Antiferromagnetic Insulator\u201d, Physical Review Letters<\/em> 112<\/strong>, 116404 (2014)<\/a> (Editors’ Suggestion).<\/li>\n
  47. Hua Chen<\/u>, Qian Niu, and Allan H. MacDonald, \u201cAnomalous Hall effect arising from noncollinear antiferromagnetism\u201d, Physical Review Letters<\/em> 112<\/strong>, 017205 (2014)<\/a>.<\/li>\n
  48. Yufeng Hao, M. S. Bharathi, Lei Wang, Yuanyue Liu, Hua Chen<\/u>, Shu Nie, Xiaohan Wang, Harry Chou, Cheng Tan, Babak Fallahazad, H. Ramanarayan, Carl W. Magnuson, Emanuel Tutuc, Boris I. Yakobson, Kevin F. McCarty, Yong-Wei Zhang, Philip Kim, James Hone, Luigi Colombo, and Rodney S. Ruoff, \u201cThe Role of Surface Oxygen in the Growth of Large Single-Crystals of Graphene on Copper\u201d, Science<\/em> 342<\/strong>, 720-723 (2013)<\/a> (Cover Article<\/a>).<\/li>\n
  49. Hua Chen<\/u>, Qian Niu, Zhenyu Zhang, and Allan H. MacDonald, \u201cGate-Tunable Exchange Coupling Between Cobalt Clusters on Graphene\u201d, Physical Review B<\/em> 87<\/strong>, 144410 (2013)<\/a>.<\/li>\n
  50. Xiaoguang Li, Gufeng Zhang, Guangfen Wu, Hua Chen<\/u>, Dimitrie Culcer, and Zhenyu Zhang, \u201cProximity Effects in Topological Insulator Heterostructures\u201d, Chinese Physics B<\/em> 22<\/strong>, 097306 (2013)<\/a>. (Invited Review)<\/li>\n
  51. Shifei Qi, Hua Chen<\/u>, Xiaohong Xu, and Zhenyu Zhang, \u201cDiluted Ferromagnetic Graphene via Compensated n<\/em>–p<\/em> Codoping\u201d, Carbon<\/em> 61<\/strong>, 609 (2013)<\/a>.<\/li>\n
  52. Guangfen Wu, Hua Chen<\/u>, Yan Sun, Xiaoguang Li, Ping Cui, Cesare Franchini, Jinlan Wang, Xing-Qiu Chen, and Zhenyu Zhang, \u201cTuning the Vertical Location of Helical Surface States in Topological Insulator Heterostructures via Dual-Proximity Effects\u201d, Scientific Reports<\/em> 3<\/strong>, 1233 (2013)<\/a>.<\/li>\n
  53. Wei Chen, Hua Chen<\/u>, Haiping Lan, Ping Cui, Tim P. Schulze, Wenguang Zhu, and Zhenyu Zhang, \u201cSuppression of Grain Boundaries in Graphene Growth on Superstructured Mn-Cu(111) Surface\u201d, Physical Review Letters<\/em> 109<\/strong>, 265507 (2012)<\/a>.<\/li>\n
  54. Hua Chen<\/u>, Wenguang Zhu, Di Xiao, and Zhenyu Zhang, \u201cCO Oxidation Facilitated by Robust Surface States on Au-Covered Topological Insulators\u201d, Physical Review Letters<\/em> 107<\/strong>, 056804 (2011)<\/a> (Editors’ Suggestion). Accompanying Synopsis: \u201cTopological Catalysis<\/a>\u201d in APS\u2019s online journal Physics.<\/li>\n
  55. Robert Van Wesep, Hua Chen<\/u>, Wenguang Zhu, and Zhenyu Zhang, \u201cStable Carbon Nanoarches in the Initial Stages of Epitaxial Growth of Graphene on Cu(111)\u201d, Journal of Chemical Physics<\/em> 134<\/strong>, 171105 (2011)<\/a>.<\/li>\n
  56. Wenguang Zhu, Hua Chen<\/u>, Kirk Bevan, and Zhenyu Zhang, \u201cFormation of Graphene p-n Supperlattices on Pb Quantum Wedged Islands\u201d, ACS Nano<\/em> 5<\/strong>, 3707 (2011)<\/a>.<\/li>\n
  57. Hua Chen<\/u>, Wenguang Zhu, and Zhenyu Zhang, \u201cContrasting Behavior of Carbon Nucleation in the Initial Stages of Graphene Epitaxial Growth on Stepped Metal Surfaces\u201d, Physical Review Letters<\/em> 104<\/strong>, 186101 (2010)<\/a>.<\/li>\n
  58. Hua Chen<\/u>, Wenguang Zhu, Efthimios Kaxiras, and Zhenyu Zhang, \u201cOptimization of Mn doping in group-IV-based dilute magnetic semiconductors by electronic codopants\u201d, Physical Review B<\/em> 79<\/strong>, 235202 (2009)<\/a>.<\/li>\n
  59. Shenyuan Yang, Lixin Zhang, Hua Chen<\/u>, Enge Wang, and Zhenyu Zhang, \u201cGeneric Guiding Principle for the Prediction of Metal-induced Reconstructions of Compound Semiconductor Surfaces\u201d, Physical Review B<\/em> 78<\/strong>, 075305 (2008)<\/a>.<\/li>\n<\/ol>\n

    Books<\/strong><\/p>\n

      \n
    1. Hua Chen<\/u>\u00a0and Allan H. MacDonald, “Spin Superfluidity and Easy Plane Magnetism”, in\u00a0Universal Themes of Bose-Einstein Condensation<\/em>\u00a0edited by D. W. Snoke, N. P. Proukakis, and P. B. Littlewood, Cambridge University Press, London, 2017<\/a>.<\/li>\n<\/ol>\n

      Patents<\/strong><\/p>\n

        \n
      1. S. K. Banerjee, A. H. MacDonald, L. F. Register II, E. Tutuc, I. Sodemann, H. Chen<\/u>, and X. Mou, “Transistor that Employs Collective Magnetic Effects Thereby Providing Improved Energy Efficiency”, US Patent 9,825,218.<\/li>\n<\/ol>\n","protected":false},"excerpt":{"rendered":"

        Papers (Google Scholar) H. Chen, \u201cAnomalous Hall scaling revisited in noncollinear antiferromagnets\u201d, Newton 1, 100100 (2025). C. Ard, E. Camrud, O. Pinaud, and H. Chen, \u201cBounds and anomalies of inhomogeneous anomalous Hall effects\u201d, arXiv:2408.15195. \u00a0Communications Physics 8, 209 (2025). Yejun Feng, Yishu Wang, Thomas F. Rosenbaum, Peter B. Littlewood, Hua Chen, \u201cFermi surface origin of … <\/p>\n

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