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Publication List

Special Contributions:

  1. Chunlei Zhang, Mun Kim, Yi-Hui Zhang, Yi-Pu Wang, Deepanshu Trivedi, Alex Krasnok, Jianbo Wang, Dustin Isleifson, Roy Roshko, and Can-Ming Hu:
    (invited review)
    „Gain-Loss Coupled Systems”
    arXiv:2410.20338 (2024).
     
  2. Chenyang Lu, Mun Kim, Ying Yang, Y. S. Gui, and C.-M. Hu:
    (invited tutorial; editor's pick)
    „Synchronization of dissipatively coupled oscillators”
    J. Appl. Phys. 134, 221101 (2023).
     
  3. Babak Zare Rameshti, Silvia Viola Kusminskiy, James A. Haigh, Koji Usami, Dany Lachance-Quirion, Yasunobu Nakamura, Can-Ming Hu, Hong X. Tang, Gerrit E. W. Bauer, Yaroslav M. Blanter: (review of an emerging field)
    „Cavity Magnonics”
    Physics Reports, 979, 1-61 (2022). (Cited 260+ times.)
     
  4. A. V. Chumak et al.: (broad perspective)
    „Advances in Magnetics: Roadmap on Spin-Wave Computing”
    IEEE Transactions on Magnetics 58, 0800172 (2022). (Cited 360+ times.)
     
  5. Michael Harder, Bimu Yao, Yongsheng Gui, Can-Ming Hu: (invited tutorial)
    „Coherent and Dissipative Cavity Magnonics”,
    J. Appl. Phys. 129, 201101 (2021).
     
  6. Can-Ming Hu: (invited book chapter)
    „The 2020 roadmap for spin cavitronics”,
    Solid State Physics, 71, 117 (2020). R. Stamps (Ed.), Academic Press.
     
  7. Yi-Pu Wang, and Can-Ming Hu: (invited perspective; editor's pick)
    „Dissipative couplings in cavity magnonics”,
    J. Appl. Phys. 127, 130901 (2020).(cited 100+ times)
     
  8. Can-Ming Hu: (viewpoint)
    „Cavity Spintronics Gets More with Less”,
    Physics, 12, 97 (2019).
     
  9. Michael Harder and Can-Ming Hu: (invited book chapter)
    „Cavity Spintronics: An Early Review of Recent Progress in the Study of Magnon-Photon Level Repulsion”,
    Solid State Physics, 69, 47-121 (2018). R. Stamps and R. Camley (Ed.), Academic Press.
     
  10. Michael Harder, Yongsheng Gui, and Can-Ming Hu: (invited review)
    „Electrical Detection of Magnetization Dynamics via Spin Rectification Effects”,
    Physics Reports, 661, 1-59 (2016). (cited 220+ times)
     
  11. C.-M. Hu: (feature article; co-editor)
    „Dawn of Cavity Spintronics”,
    Physics in Canada, 72, No. 2, 76 (2016). (SI: Applied Magnetism)
    arXiv: 1508.01966.
     
  12. L.H. Bai, Y.S. Gui, and C.-M. Hu: (invited book chapter)
    „Electrical Detection of Ferromagnetic Resonance and Its New Applications in Spintronics”,
    Introduction to Spintronics, X.F. Han (Ed.), Science Publisher (Chinese Edition), 2014, Chapter 9.
     
  13. Y.S. Gui, Ali M. Mehrabani, Daniel Flores-Tapia, L. Fu, L.H. Bai, S. Pistorius, Lot Shafai, and C.-M. Hu: (invited paper)
    „New horizons for microwave applications using spin caloritronics”,
    Solid State Communications, 198, 45 (2014). (SI: Spin Mechanics)
     
  14. Z. X. Cao, W. Lu, L. Fu, Y. S. Gui, and C.-M. Hu: (invited paper)
    „Spintronic microwave imaging”,
    Applied Physics A, 111, 329-337 (2013). (SI: Spintronics' Applications)
     
  15. Gui Y. S., Bai L. H., Hu C.-M.: (invited review)
    „The physics of spin rectification and its application”,
    Sci China-Phys Mech Astron, 56, No. 1, 124-141 (2013). (SI: Spintronics)
     
  16. Detlef Heitmann and Can-Ming Hu: (invited book chapter)
    „Far-Infrared Spectroscopy of Low-Dimensional Electron Systems”,
    Quantum Materials, D. Heitmann (Ed.), Springer (Berlin), 2010, Chapter 5.
     
  17. C.-M. Hu:
    „Recent Progress in Spin Dynamics Research in Canada”,
    Physics in Canada, 65, No. 1, 29 (Jan.-Mar. 2009).
     
  18. C.-M. Hu and W.-K. Ge: (invited article)
    „The spin-driven electrical currents”,
    Physics in Canada, 63, No. 2, 67 (Mar.-Apr. 2007).
     
  19. C.-M. Hu:
    „Interplay of spins, charges and photons in low-dimensional systems”,
    Cuvillier Verlag, Göttingen 2005, (Habilitationsschrift, University of Hamburg).
     
  20. C.-M. Hu: (invited review)
    „Spin Effects of Low-dimensional Electron Gases Studied by Far-infrared Photoconductivity Experiments”,
    MRS 2004 Spring Meeting Proceedings, Symposium G (Semiconductor Spintronics), MRS Proceedings Volume 825.
     
  21. C.-M. Hu, J. Nitta, A. Jensen, J.B. Hansen, H. Takayanagi, T. Matsuyama, D. Heitmann, and U. Merkt: (invited article)
    „Spin Injection across a Hybrid Heterojunction: Theoretical Understanding and Experimental Approach”,
    J. Appl. Phys. 91, 7251 (2002).
     

Patents:

  1. Can-Ming Hu, Yi-Pu Wang, Yongsheng Gui, Mun Kim:
    „Device and Related Method for Providing Unidirectional Microwave Propagation”,
    United States Patent Granted No.: US 11,946,878B2, Date of Patent: Apr. 2, 2024.
     
  2. Alex Reimer, Yongsheng Gui, Can-Ming Hu, Fuji Jian, Paul Fields, Digvir S. Jayas:
    „Compact Microwave Device for Monitoring Grain Conditions”,
    United States Patent Granted, No.: US 11442027 B2, Date of Patent: Sept. 9, 2022.
    Canadian Patent Application No. 3,016,064, Filling Date: Aug. 31, 2018.
     
  3. Can-Ming Hu, Yongsheng Gui, Lei Fu:
    „Rapid microwave phase detection with a solid state device”,
    United States Patent Granted, No.: US 9,989,481, Date of Patent: June 5, 2018.
     
  4. Can-Ming Hu, Andre Wirthmann, Xiaolong Fan, Yongsheng Gui:
    „Spintronic phase comparator permitting direct phase probing and mapping of electromagnetic signals”,
    United States Patent Granted, No.: US 9,069,034, Date of Patent: June 30, 2015.
     
  5. Can-Ming Hu, Nikolai Mecking, Yongsheng Gui, Andre Wirthmann, Lihui Bai:
    „Systems and Methods for RF Magnetic-Field Vector Detection Based on Spin Rectification Effects”,
    United States Patent Granted, No.: US 7,986,140, Date of Patent: Jul. 26, 2011.
     

Refereed Journals :

Physical Review Letters:

  1. Ying Yang, Jiguang Yao, Y. Xiao, Pak-Tik Fong, Hoi-Kwan Lau, and C.-M. Hu:
    „Anomalous Long-Distance Coherence in Critically-Driven Cavity Magnonics”,
    Phys. Rev. Lett., 132, 206902 (2024).
     
  2. Bimu Yao, Y.S. Gui, J.W. Rao, Y.H. Zhang, Wei Lu, and C.-M. Hu:
    „Coherent Microwave Emission of a Gain-Driven Polariton”,
    Phys. Rev. Lett., 130, 146702 (2023).
    (Selected as an Editor's Suggestion;
    Highlighted by Focus in Physics;
    Featured by Phys.org.)

     
  3. Y. Yang, Yi-Pu Wang, J. W. Rao, Y. S. Gui, B. M. Yao, W. Lu, and C.-M. Hu:
    „Unconventional singularity in anti-parity-time symmetric cavity magnonics”,
    Phys. Rev. Lett., 125, 147202 (2020). (Cited 130+ times.)
     
  4. Yi-Pu Wang, J.W. Rao, Y. Yang, Peng-Chao Xu, Y.S. Gui, B.M. Yao, J. Q. You, and C.-M. Hu:
    „Nonreciprocity and Unidirectional Invisibility in Cavity Magnonics”,
    Phys. Rev. Lett., 123, 127202 (2019). (Cited 310+ times.)
    (Selected as an Editor's Suggestion;
    Highlighted by Synopsis in Physics;
    Featured by Phys.org.)

     
  5. M. Harder, Y. Yang, B.M. Yao, C.H. Yu, J.W. Rao, Y.S. Gui, R.L. Stamps, and C.-M. Hu:
    „Level Attraction Due to Dissipative Magnon-Photon Coupling”,
    Phys. Rev. Lett., 121, 137203 (2018). (Cited 290+ times.)
    (Selected as an Editor's Suggestion.)
     
  6. Yi-Pu Wang, Guo-Qiang Zhang, Dengke Zhang, Tie-Fu Li, C.-M. Hu, and J. Q. You:
    „Bistability of Cavity Magnon Polaritons”,
    Phys. Rev. Lett., 120, 057202 (2018). (Cited 450+ times.)
     
  7. Lihui Bai, Michael Harder, Paul Hyde, Zhaohui Zhang, Can-Ming Hu, Y. P. Chen, and John Q. Xiao:
    „Cavity mediated manipulation of distant spin currents using a cavity-magnon-polariton”,
    Phys. Rev. Lett., 118, 217201 (2017). (Cited 160+ times.)
     
  8. Lihui Bai, M. Harder, Y. P. Chen, X. Fan, J. Q. Xiao, and C.-M. Hu:
    „Spin Pumping in Electrodynamically Coupled Magnon-Photon Systems”,
    Phys. Rev. Lett., 114, 227201 (2015). (Cited 480+ times.)
    (Selected as an Editor's Suggestion;
    Highlighted by Viewpoint in Physics.)

     
  9. Lihui Bai, P. Hyde, Y. S. Gui, C.-M. Hu, V. Vlaminck, J. E. Pearson, S. D. Bader, and A. Hoffmann:
    „Universal Method for Separating Spin Pumping from Spin Rectification Voltage of Ferromagnetic Resonance”,
    Phys. Rev. Lett., 111, 217602 (2013). (Cited 140+ times.)
     
  10. Z. H. Zhang, Y. S. Gui, L. Fu, X. L. Fan, J. W. Cao, D. S. Xue, P. P. Freitas, D. Houssameddine, S. Hemour, K. Wu, and C.-M. Hu:
    „Seebeck Rectification Enabled by Intrinsic Thermoelectrical Coupling in Magnetic Tunneling Junctions”,
    Phys. Rev. Lett., 109, 037206 (2012).
     
  11. A. Wirthmann, Xiaolong Fan, Y. S. Gui, K. Martens, G. Williams, J. Dietrich, G. E. Bridges, and C.-M. Hu:
    „Direct phase probing and mapping via spintronic Michelson interferometry”,
    Phys. Rev. Lett., 105, 017202 (2010).
     
  12. Y.S. Gui, N. Mecking, and C.-M. Hu:
    „Quantized Spin Excitations in a Ferromagnetic Microstrip from Microwave Photovoltage Measurements”,
    Phys. Rev. Lett., 98, 217603 (2007).
    (Featured by the Science News.)
     
  13. Y.S. Gui, N. Mecking, X. Zhou, G. Williams, and C.-M. Hu:
    „Realization of a Room-Temperature Spin Dynamo: The Spin Rectification Effect”,
    Phys. Rev. Lett., 98, 107602 (2007). (cited 210+ times.)
    (Selected as an Editor's Suggestion.)
     
  14. Y.S. Gui, S. Holland, N. Mecking, and C.-M. Hu:
    „Resonances in ferromagnetic gratings detected by microwave photoconductivity”,
    Phys. Rev. Lett., 95, 056807 (2005).
     
  15. S. Holland, Ch. Heyn, D. Heitmann, E. Batke, R. Hey, K.J. Friedland, and C.-M. Hu:
    „Quantized dispersion of two-dimensional magnetoplasmons detected by photoconductivity spectroscopy”,
    Phys. Rev. Lett., 93, 186804 (2004).
     
  16. C.-M. Hu, and T. Matsuyama:
    „Spin injection across a heterojunction: a ballistic picture”,
    Phys. Rev. Lett., 87, 066803 (2001). (cited 140+ times)
     
  17. C.-M. Hu, E. Batke, K. Köhler and P. Ganser:
    „Resonant polaron coupling of high index electron Landau levels in GaAs heterostructures”,
    Phys. Rev. Lett., 76, 1904 (1996).
     
  18. C.-M. Hu, E. Batke, K. Köhler and P. Ganser:
    „Interaction coupled cyclotron transitions of two-dimensional electrons in GaAs at high temperatures”,
    Phys. Rev. Lett., 75, 918 (1995).
     

Open Access Journals:

  1. Yan Li, Zhitao Zhang, Chen Liu, Dongxing Zheng, Bin Fang, Chenhui Zhang, Aitian Chen, Yinchang Ma, Chunmei Wang, Haoliang Liu, Ka Shen, Aurélien Manchon, John Q. Xiao, Ziqiang Qiu, Can-Ming Hu, and Xixiang Zhang:
    „Reconfigurable spin current transmission and magnon–magnon coupling in hybrid ferrimagnetic insulators”,
    Nature Communications, 15, 2234 (2024).
     
  2. Youcai Han, Changhao Meng, Hong Pan, Jie Qian, Zejin Rao, Liping Zhu, Yongsheng Gui, Can-Ming Hu, and Zhenghua An:
    „Bound chiral magnonic polariton states for ideal microwave isolation”,
    Science Advances, 9, eadg4730 (2023).
     
  3. Jie Qian, C. H. Meng, J. W. Rao, Z. J. Rao, Zhenghua An, Yongsheng Gui, and C. -M. Hu:
    „Non-Hermitian control between absorption and transparency in perfect zero-reflection magnonics”,
    Nature Communications, 14, 3437 (2023).
     
  4. J.W. Rao, P.C. Xu, Y.S. Gui, Y.P. Wang, Y. Yang, Bimu Yao, J. Dietrich, G. E. Bridges, X. L. Fan, D. S. Xue, and C.-M. Hu:
    „Interferometric control of magnon-induced nearly perfect absorption in cavity magnonics”,
    Nature Communications, 12, 1933 (2021).
     
  5. J. W. Rao, S. Kaur, B. M. Yao, E. R. J. Edwards, Y. T. Zhao, Xiaolong Fan, Desheng Xue, T. J. Silva, Y. S. Gui, and C.-M. Hu:
    „Analogue of dynamic Hall effect in cavity magnon polariton system and coherently controlled logic device”,
    Nature Communications, 10, 2934 (2019).
     
  6. Bimu Yao, Y.S. Gui, J.W. Rao, S. Kaur, X.S. Chen, W.Lu, Y. Xiao, H. Guo, K.-P. Marzlin, and C.-M. Hu:
    „Cooperative polariton dynamics in feedback-coupled cavities”,
    Nature Communications, 8, 1437 (2017).
     

Other Journals:

  1. Chenyang Lu, Mun Kim, Chunlei Zhang, and Can-Ming Hu:
    „Solid-state injection locking microwave amplifier”,
    J. Appl. Phys. 136, 053903 (2024).
     
  2. Chunlei Zhang, Mun Kim, Jianbo Wang, and Can-Ming Hu:
    „Van der Pol–Duffing oscillator and its application to gain-driven light-matter interaction”,
    Phys. Rev. Applied 22, 014034 (2024).
     
  3. Chunlei Zhang, Mun Kim, Jianbo Wang, and Can-Ming Hu:
    „Gain-driven synchronization and asymmetric bound states in the continuum within non-Hermitian circuit model”,
    AIP Advances 14, 065215 (2024).
     
  4. Y. S. Gui, and C.-M. Hu:
    „Transient response of a gain-driven polariton”,
    Phys. Rev. Applied, 21, 044023 (2024).
    (Selected as an Editor's Suggestion.)
     
  5. Jun Li, C.-M. Hu, and Yaping Yang:
    „Enhancement of photon blockade via topological edge states”
    Phys. Rev. Applied 21, 034058 (2024).
     
  6. Jun Li, Yaping Yang, and C.-M. Hu:
    „Multichannel coupling induced topological insulating phases with full multimerization”
    Photonics Research 12, 491 (2024).
     
  7. Mun Kim, Chunlei Zhang, Chenyang Lu, and Can-Ming Hu:
    „Low Phase Noise Microwave Oscillator Based on Gain Driven Polariton”
    Appl. Phys. Lett. 124, 114103 (2024).
     
  8. Mun Kim, Armin Tabesh, Tyler Zegray, Shabir Barzanjeh, and Can-Ming Hu:
    „Nonreciprocity in cavity magnonics at millikelvin temperature”
    J. Appl. Phys. 135, 063904 (2024).
     
  9. Hong Pan, Z.H. An, and C.-M. Hu:
    „Magnon-magnon coupling mediated by topological edge states”
    Phys. Rev. Research 6, 013020 (2024).
     
  10. Chenyang Lu, Bentley Turner, Yongsheng Gui, Jacob Burgess, Jiang Xiao, and Can-Ming Hu:
    „An experimental demonstration of level attraction with coupled pendulums”
    Am. J. Phys. 91, 585 (2023).
     
  11. Ying Yang, Yang Xiao, and C.-M. Hu:
    „Theory of Floquet-driven dissipative cavity magnonics”
    Phys. Rev. B 107, 054413 (2023).
     
  12. H. Pan, J. Qian, Z. Rao, C.-M. Hu, and Z.H. An:
    „Spin Pumping of Magnons Coherently Coupled to a Cavity Dark Mode”
    Phys. Rev. Applied 19, 014075 (2023).
     
  13. Zhi-Bo Yang, Yi-Pu Wang, Jie Li, C.-M. Hu, and J. Q. You:
    „Entanglement emerges from dissipation-driven quantum self-organization”
    Journal of Magnetism and Magnetic Materials, 564, 170139 (2022).
    (Special Issue in Honor of Professor Chia-Ling Chien)
     
  14. Hong Pan, Ying Yang, Zhenghua An, and Can-Ming Hu:
    „Bistability in dissipatively coupled cavity magnonics”
    Phys. Rev. B 106, 054425 (2022).
     
  15. Kang He, Jun Cheng, Man Yang, Yihui Zhang, Longqian Yu, Qi Liu, Liang Sun, Bingfeng Miao, Can-Ming Hu, and Haifeng Ding:
    „Spin rectification effect induced by planar Hall effect and its strong impact on spin-pumping measurements”,
    Phys. Rev. B 105, 104406 (2022).
     
  16. M. Kim, J.W. Rao, Y.P. Wang, Y.S. Gui, G.E. Bridges, and C.-M. Hu:
    „Prototyping of Novel Isolator Design Based on Cavity Magnonics”,
    IEEE Transactions on Microwave Theory and Techniques 70, 3020 (2022).
     
  17. M. Kim, Y. Yang, Y.S. Gui, and C.-M. Hu:
    „Visualization of synchronization zone on the Bloch sphere through an anti-PT-symmetric electrical circuit”,
    AIP Advances 12, 035217 (2022).
     
  18. Yang Xiao, Huaiqiang Wang, Dinghui Wang, Ruifeng Lu, Xiaohong Yan, Hong Guo, C.-M. Hu, Ke Xia, Haijun Zhang, and Dingyu Xing:
    „Nonlinear level attraction of cavity axion polariton in antiferromagnetic topological insulator”,
    Phys. Rev. B 104, 115147 (2021).
     
  19. Y. Xiao, X.H. Yan, L.H. Bai, H. Guo, C.-M. Hu, and K. Xia:
    „Magnon photon coupling for magnetization antiparallel to the magnetic field”,
    Phys. Rev. B 103, 104432 (2021).
     
  20. J.W. Rao, Y.T. Zhao, Y.S. Gui, X. L. Fan, D. S. Xue, and C.-M. Hu:
    „Controlling Microwaves in Non-Hermitian Metamaterials”,
    Phys. Rev. Applied 15, L021003 (2021). (Letter)
     
  21. J. Qian, J.W. Rao, Y.S. Gui, Y.P. Wang, Z.H. An, and C.-M. Hu:
    „Manipulation of the zero-damping conditions and unidirectional invisibility in cavity magnonics”,
    Appl. Phys. Lett. 116, 192401 (2020). (Editor's pick)
     
  22. Jie Qian, Peng Gou, Hong Pan, Liping Zhu, Y. S. Gui, C.-M. Hu, and Zhenghua An:
    „Hybrid perfect metamaterial absorber for microwave spin rectification applications”,
    Scientific Reports 10, 19240 (2020).
     
  23. Y.T. Zhao, J.W. Rao, Y.S. Gui, Y.P. Wang, and C.-M. Hu:
    „Broadband Nonreciprocity Realized by Locally Controlling the Magnon’s Radiation”,
    Phys. Rev. Applied 14, 014035 (2020).
     
  24. Peng-Chao Xu, J. W. Rao, Y. Wang, Y. S. Gui, John Q. Xiao, Xiaofeng Jin, and C.-M. Hu:
    „Electrical detection of magnon-photon interaction via auxiliary spin wave mode”,
    Phys. Rev. B 102, 014453 (2020).
     
  25. J. W. Rao, Y. P. Wang, Y. Yang, T. Yu, Y. S. Gui, X. L. Fan, D. S. Xue, and C.-M. Hu:
    „Interactions between a magnon mode and a cavity photon mode mediated by traveling photons”,
    Phys. Rev. B 101, 064404 (2020).
     
  26. J.W. Rao, C.H Yu, Y.T Zhao, Y.S. Gui, X.L. Fan, D.S. Xue, and C.-M. Hu:
    „Level attraction and level repulsion of magnon coupled with a cavity anti-resonance”,
    New J. Phys. 21, 065001 (2019).
     
  27. Y. Yang, J.W. Rao, Y.S. Gui, B.M. Yao, W. Lu, and C.-M. Hu:
    „Control of the magnon-photon level attraction in a planar cavity”,
    Phys. Rev. Applied 11, 054023 (2019).
     
  28. Bimu Yao, Tao Yu, Xiang Zhang, Wei Lu, Yongsheng Gui, Can-Ming Hu, and Yaroslav M. Blanter:
    „The microscopic origin of magnon-photon level attraction by traveling waves: Theory and experiment”,
    Phys. Rev. B 100, 214426 (2019).
     
  29. Peng-Chao Xu, J.W. Rao, Y.S. Gui, Xiaofeng Jin, and C.-M. Hu:
    „Cavity mediated dissipative coupling of distant magnetic moments: theory and experiment”,
    Phys. Rev. B 100, 094415 (2019).
     
  30. Christophe Match, Michael Harder, Lihui Bai, Paul Hyde, and Can-Ming Hu:
    „Transient Response of the Cavity-Magnon-Polariton”,
    Phys. Rev. B 99, 134445 (2019).
     
  31. Y. Xiao, X. H. Yan, Y. Zhang, V. L. Grigoryan, C.-M. Hu, H. Guo, and K. Xia:
    „Magnon dark mode of an antiferromagnetic insulator in a microwave cavity”,
    Phys. Rev. B 99, 094407 (2019).
     
  32. B. M. Yao, Y. S. Gui, T. Yu, J. W. Rao, Y. T. Zhao, W. Lu, and C.-M. Hu:
    „Coherent control of magnon radiative damping with local photon states”,
    Communications Physics 2, 161 (2019).
     
  33. C.H. Yu, Y. Yang, J.W. Rao, P. Hyde, Y.P. Wang, B. Zhang, Y.S. Gui, and C.-M. Hu:
    „Spin number dependent dissipative coupling strength”,
    AIP Advances 9, 115012 (2019).
     
  34. P. Hyde, B.M. Yao, Y.S. Gui, Guo-Qiang Zhang, J.Q. You, and C.-M. Hu:
    „Direct measurement of foldover in cavity magnon-polariton systems”,
    Phys. Rev. B 98, 174423 (2018).
     
  35. J. W. Rao, B. M. Yao, X. L. Fan, D. S. Xue, Y. S. Gui, and C.-M. Hu:
    „Electric control of cooperative polariton dynamics in a cavity-magnon system”,
    Appl. Phys. Lett. 112, 262401 (2018). (Editor's pick for the cover of APL)
     
  36. Qihan Zhang, Xiaolong Fan, Hengan Zhou, Wenwen Kong, Shiming Zhou, Y.S. Gui, C.-M. Hu, and Desheng Xue:
    „Investigation of the difference between spin Hall magnetoresistance rectification and spin pumping from the viewpoint of magnetization dynamics”,
    Appl. Phys. Lett. 112, 092406 (2018).
     
  37. Y. Yang, M. Harder, J. W. Rao, B. M. Yao, W. Lu, Y. S. Gui, and C.-M. Hu:
    „Influence of stripline coupling on the magnetostatic mode line width of an yttrium-iron-garnet sphere”,
    AIP Advances 8, 075315 (2018).
     
  38. Xiaobin Chen, Jiangtao Yuan, Gaomin Tang, Jian Wang, Zhaohui Zhang, Can-Ming Hu, and Hong Guo:
    „Transient spin current under a thermal switch”,
    Journal of Physics D: Applied Physics 51, 274004 (2018).
     
  39. A. Reimer, K. Wiebe, J.W. Rao, B.M. Yao, Y.S. Gui, F. Jian, P. Fields, D.S. Jayas, and C.-M. Hu:
    „A compact microwave device for monitoring insect activity in grain samples”,
    Biosystems Engineering 175, 27 (2018).
     
  40. H.H. Jiang, Y. Xiao, C.-M. Hu, H. Guo and K. Xia:
    „Effect of magnetization boundary condition on cavity magnon polariton of YIG thin film”,
    Nanotechnology 29, 154002 (2018).
     
  41. Jie Qian, Peng Gou, Y. S. Gui, C.-M. Hu, and Zhenghua An:
    „Plasmonic diabolo cavity enhanced spin pumping”,
    Appl. Phys. Lett. 111, 122402 (2017).
     
  42. J. W. Rao, S. Kaur, X. L. Fan, D. S. Xue, B. M. Yao, Y. S. Gui, and C.-M. Hu:
    „Characterization of the non-resonant radiation damping in coupled cavity photon magnon system”,
    Appl. Phys. Lett. 110, 262404 (2017).
     
  43. Michael Harder, Lihui Bai, Paul Hyde, and Can-Ming Hu:
    „Topological properties of a coupled spin-photon system induced by damping”,
    Phys. Rev. B 95, 214411 (2017).
     
  44. Xiaobin Chen, Chenyi Zhou, Zhaohui Zhang, Jingzhe Chen, Xiaohong Zheng, Lei Zhang, Can-Ming Hu, and Hong Guo:
    „Enhancing the spin transfer torque in magnetic tunnel junctions by ac modulation”,
    Phys. Rev. B 95, 115417 (2017).
     
  45. Paul Hyde, Lihui Bai, Michael Harder, Christopher Dyck, and Can-Ming Hu:
    „Linking Magnon-Cavity Strong Coupling to Magnon-Polaritons through Effective Permeability”,
    Phys. Rev. B 95, 094416 (2017).
     
  46. Yi-Pu Wang, Guo-Qiang Zhang, Dengke Zhang, Xiao-Qing Luo, Wei Xiong, Shuai-Peng Wang, Tie-Fu Li, C.-M. Hu, and J. Q. You:
    „Magnon Kerr effect in a strongly coupled cavity-magnon system”,
    Phys. Rev. B 94, 224410 (2016). (cited 300+ times)
     
  47. Hengan Zhou, Xiaolong Fan, Li Ma, Qihan Zhang, Lei Cui, Shiming Zhou, Y. S. Gui, C.-M. Hu, and Desheng Xue:
    „Spatial symmetry of spin pumping and inverse spin Hall effect in the Pt/Y3Fe5O12 system”,
    Phys. Rev. B 94, 134421 (2016).
     
  48. Zhaohui Zhang, Lihui Bai, Xiaobin Chen, Hong Guo, X. L. Fan, D. S. Xue, D. Houssameddine, and C.-M. Hu:
    „Observation of thermal spin-transfer torque via ferromagnetic resonance in magnetic tunnel junctions”,
    Phys. Rev. B 94, 064414 (2016).
     
  49. Michael Harder, Paul Hyde, Lihui Bai, Christophe Match, and Can-Ming Hu:
    „Spin dynamical phase and anti-resonance in a strongly coupled magnon-photon system”,
    Phys. Rev. B 94, 054403 (2016).
     
  50. Wenwen Kong, Xiaolong Fan, Hengan Zhou, Jiangwei Cao, Dangwei Guo, YS Gui, C-M Hu, and Desheng Xue:
    „Electrical detection of magnetization dynamics in an ultrathin CoFeB film with perpendicular anisotropy”,
    Appl. Phys. Lett. 109, 182406 (2016).
     
  51. Paul Hyde, Lihui Bai, Michael Harder, Christophe Match, and Can-Ming Hu:
    „Indirect Coupling between Two Cavity Photon Systems via Ferromagnetic Resonance”,
    Appl. Phys. Lett. 109, 152405 (2016).
     
  52. Stefan Klingler, Hannes Maier-Flaig, Rudolf Gross, Can-Ming Hu, Hans Huebl, Sebastian T.B. Goennenwein, Mathias Weiler:
    „Combined Brillouin light scattering and microwave absorption study of magnon-photon coupling in a split-ring resonator/YIG film system”,
    Appl. Phys. Lett. 109, 072402 (2016).
     
  53. S. Kaur, B.M. Yao, J.W. Rao, Y.S. Gui, and C.-M. Hu:
    „Voltage control of cavity magnon polariton”,
    Appl. Phys. Lett., 109, 032404 (2016).
     
  54. Hengan Zhou, Xiaolong Fan, Li Ma, Lei Cui, Chenlong Jia, Shiming Zhou, Y. S. Gui, C.-M. Hu, and Desheng Xue:
    „Spin pumping in the nonlinear dynamic regime of a Pt/Y3Fe5O12 heterostructure”,
    Appl. Phys. Lett., 108, 192408 (2016).
     
  55. Michael Harder, Lihui Bai, Christophe Match, Jesko Sirker, and Can-Ming Hu:
    „Study of the cavity-magnon-polariton transmission line shape”,
    Sci. China-Phys. Mech. Astron. 59, 117511 (2016).
     
  56. Sandeep Kaur, Bimu Yao, Yong-Sheng Gui, and Can-Ming Hu:
    „On-chip artificial magnon-polariton device for voltage control of electromagnetically induced transparency”,
    J. Phys. D: Appl. Phys. 49, 475103 (2016).
     
  57. Lihui Bai, Keagan Blanchette, Michael Harder, Yunpeng Chen, Xin Fan, John Xiao, and C.-M. Hu:
    „Control of the Magnon-Photon Coupling”,
    IEEE Transactions on Magnetics, 52, 1000107 (2016).
     
  58. Daniel Flores-Tapia, Diego Rodriguez, Mario Solis, Nikita Kopotun, Saeed Latif, Oleksandr Maizlish, Lei Fu, Yonsheng Gui, Can-Ming Hu, and Stephen Pistorius:
    „Experimental feasibility of multistatic holography for breast microwave radar image reconstruction”,
    Medical Physics, 43, 4674 (2016).
     
  59. Lei Fu, Yong-Sheng Gui, and Can-Ming Hu:
    „Through-wall bio-radio location and characterization of human activities”,
    Measurement Science and Technology, 27, 065702 (2016).
     
  60. B.M. Yao, Y.S. Gui, Y. Xiao, H. Guo, X.S. Chen, W. Lu, C.L. Chien, C.-M. Hu:
    „Theory and experiment on cavity magnon polariton in the 1D configuration”,
    Phys. Rev. B, 92, 184407 (2015).
     
  61. Y. Huo, L. H. Bai, P. Hyde, Y. Z. Wu, and C.-M. Hu:
    „Spin rectification for collinear and non-collinear magnetization and external magnetic field configurations”,
    Phys. Rev. B, 91, 174430 (2015).
     
  62. Y. P. Zhao, S. Hemour, D. Houssameddine, L. H. Bai, Y. S. Gui, C. M. Hu, and K. Wu:
    „Interfacial properties and their impact on magnetic tunnel junction at microwave frequencies”,
    Appl. Phys. Lett., 106, 182404 (2015).
     
  63. Y.S. Gui, Y. Xiao, L.H. Bai, S. Hemour, Y.P. Zhao, D. Houssameddine, K. Wu, H. Guo, and C.-M. Hu:
    „High sensitivity microwave detection using a magnetic tunnel junction in the absence of an external applied magnetic field”,
    Appl. Phys. Lett., 106, 152403 (2015). (Featured by Pick of the Week.)
     
  64. B. M. Yao, Y. S. Gui, M. Worden, T. Hegmann, M. Xing, X.S. Chen, W. Lu, Y. Wroczynskyj, J. van Lierop, and C.-M. Hu:
    „Quantifying the complex permittivity and permeability of magnetic nanoparticles”,
    Appl. Phys. Lett., 106, 142406 (2015).
     
  65. Peng Gou, Fuchun Xi, Qinbai Qian, Jie Xu, Y. S. Gui, C.-M. Hu, and Zhenghua An:
    „Microwave meta-atom enhanced spintronic rectification”,
    Appl. Phys. Lett., 106, 142405 (2015).
     
  66. B. M. Yao, Y. S. Gui, X. S. Chen, W. Lu, and C.-M. Hu:
    „Experimental realization of negative refraction using one metasurface”,
    Appl. Phys. Lett., 106, 121903 (2015).
     
  67. C.-M. Hu, B.M. Yao, S. Kaur, Y.S. Gui, W. Lu:
    „Magnon polariton and pseudo-magnon-polariton”,
    IEEE Proceeding on IRMMW-THz, (2015).
     
  68. L. Fu, Y. S. Gui, L. H. Bai, H. Guo, H. Abou-Rachid, and C.-M. Hu:
    „Microwave holography using a magnetic tunnel junction based spintronic microwave sensor”,
    J. Appl. Phys., 117, 213902 (2015).
     
  69. Yichao Zhang, Xiaolong Fan, Xiaobing Zhao, Jinwei Rao, Hengan Zhou, Dangwei Guo, Y. S. Gui, C.-M. Hu, and Desheng Xue:
    „Angular dependent study on ferromagnetic resonance and spin excitations by spin rectification”,
    J. Appl. Phys., 117, 023905 (2015).
     
  70. Lei Fu, Y. S. Gui, Y. Xiao, M. Jaidann, H. Guo, H. Abou-Rachid, and C.-M. Hu:
    „Detection of concealed targets using spintronic microwave sensor”,
    Proc. SPIE 9454, Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XX, 945406 (May 14, 2015); doi:10.1117/12.2177689.
     
  71. Z. H. Zhang, Lihui Bai, C.-M. Hu, S. Hemour, K. Wu, X. L. Fan, D. S. Xue, and D. Houssameddine:
    „The tunneling magnetoresistance current dependence on cross sectional area, angle and temperature”,
    AIP Advances, 5, 037134 (2015).
     
  72. P. Hyde, Lihui Bai, D. M. J. Kumar, B. W. Southern, C.-M. Hu, S. Y. Huang, B. F. Miao, and C. L. Chien:
    „Electrical detection of direct and alternating spin current injected from a ferromagnetic insulator into a ferromagnetic metal”,
    Phys. Rev. B, 89, 180404(R) (2014). (A Rapid Communication)
     
  73. Xiaolong Fan, Wei Wang, Yutian Wang, Hengan Zhou, Jinwei Rao, Xiaobing Zhao, Cunxu Gao, Y. S. Gui, C.-M. Hu, and Desheng Xue:
    „Rapid characterizing of ferromagnetic materials using spin rectification”,
    Appl. Phys. Lett., 105, 262404 (2014).
     
  74. H. J. Tang, S. Kaur, L. Fu, B. M. Yao, X. Li, H. M. Gong, Y. S. Gui, and C.-M. Hu:
    „Life signal detection using an on-chip split-ring based solid state microwave sensor”,
    Appl. Phys. Lett., 105, 133703 (2014).
     
  75. L. Fu, W. Lu, D.R. Herrera, D.F. Tapia, Y.S. Gui, S. Pistorius, C.-M. Hu:
    „Microwave radar imaging using a solid state spintronic microwave sensor”,
    Appl. Phys. Lett., 105, 122406 (2014).
     
  76. Hengan Zhou, Xiaolong Fan, Fenglong Wang, Changjun Jiang, Jinwei Rao, Xiaobing Zhao, Y. S. Gui, C.-M. Hu, and Desheng Xue:
    „Electric field controlled reversible magnetic anisotropy switching studied by spin rectification”,
    Appl. Phys. Lett., 104, 102401 (2014).
     
  77. B. M. Yao, L. Fu, X. S. Chen, W. Lu, L. H. Bai, Y. S. Gui, and C.-M. Hu:
    „Rapid microwave phase detection based on a solid state spintronic device”,
    Appl. Phys. Lett., 104, 062408 (2014).
     
  78. Simon Hemour, Yangping Zhao, Carlos Henrique Petzl Lorenz, Dimitri Houssameddine, Yongsheng Gui, C.-M. Hu, Ke Wu:
    „Towards Low-Power High-Efficiency RF and Microwave Energy Harvesting”,
    IEEE Trans. on Microwave Theory and Techniques, 62, 965 (2014).
    (cited 270+ times.)
     
  79. B. M. Yao, L. Fu, X. S. Chen, W. Lu, H. Guo, Y. S. Gui and C.-M. Hu:
    „Ground penetrating detection using miniaturized radar system based on solid state microwave sensor”,
    Rev. Sci. Instrum., 84, 124702 (2013).
     
  80. Fuchun Xi, Lijian Zhang, Jie Xu, Lei Fu, Yongsheng Gui, Can-Ming Hu, Lei Zhou, Shan Qiao, and Zhenghua An:
    „Electromagnetic Field Enhancement and Its Application in Spin Rectification”,
    Applied Physics Express, 6, 103002 (2013).
     
  81. Lihui Bai, Z. Feng, P. Hyde, H. F. Ding, and C.-M. Hu:
    „Distinguishing spin pumping from spin rectification in a Pt/Py bilayer through angle dependent line shape analysis”,
    Appl. Phys. Lett., 102, 242402 (2013).
     
  82. Hang Chen, Xiaolong Fan, Wenxi Wang, Hengan Zhou, Y. S. Gui, C.-M. Hu, and Desheng Xue:
    „Electric detection of the thickness dependent damping in Co90Zr10 thin films”,
    Appl. Phys. Lett., 102, 202410 (2013).
     
  83. N. H. G. Grenda, P. A. Hyde, Y. S. Gui, M. P.Wismayer, J. D. A. Jung, C.-M. Hu, B. W. Southern, and K.-W. Lin:
    „Angular Dependence of Ferromagnetic Resonance Measurements in Exchange Coupled Ni80Fe20/NiO Bilayers”,
    J. Phys. D: Appl. Phys., 46, 205002 (2013).
     
  84. Hang Chen, Xiaolong Fan, Hengan Zhou, Wenxi Wang, Y. S. Gui, C.-M. Hu, and Desheng Xue:
    „Spin rectification enabled by anomalous Hall effect”,
    J. Appl. Phys., 113, 17C732 (2013).
     
  85. L. Fu, Z. X. Cao, S. Hemour, K. Wu, D. Houssameddine, W. Lu, S. Pistorius, Y. S. Gui and C.-M. Hu:
    „Microwave reflection imaging using a magnetic tunnel junction based spintronic microwave sensor”,
    Appl. Phys. Lett., 101, 232406 (2012).
     
  86. Z. X. Cao, M. Harder, L. Fu, B. Zhang, W. Lu, G. E. Bridges, Y. S. Gui, and C.-M. Hu:
    „Nondestructive two-dimensional phase imaging of embedded defects via on-chip spintronic sensor”,
    Appl. Phys. Lett., 100, 252406 (2012).
     
  87. M. P. Wismayer, B.W. Southern, X. L. Fan, Y. S. Gui, C.-M. Hu, and R. E. Camley:
    „Nonlinear behavior for the uniform mode and horizontal standing spin-wave modes in metallic ferromagnetic microstrips: Experiment and theory”,
    Phys. Rev. B, 85, 064411 (2012).
     
  88. Simon Hemour, Dimitri Houssameddine, Renu Whig, Jon M. Slaughter, Kerry Nagel, Sanjeev Aggarwal, Yongsheng Gui, Can-Ming Hu, and Ke Wu:
    „Spintronics-Based Devices for Microwave Power Harvesting”,
    Microwave Symposium Digest (MTT), IEEE MTT-S International, 1-3 (2012).
     
  89. M. Harder, Z. X. Cao, Y. S. Gui, X. L. Fan, and C.-M. Hu:
    „Analysis of the line shape of electrically detected ferromagnetic resonance”,
    Phys. Rev. B, 84, 054423 (2011).
    (A 12-paged comprehensive review. Selected as an Editor's Suggestion.)
    (cited 250+ times)
     
  90. Lihui Bai, Y. S. Gui, Z. H. Chen, S. C. Shen, Junsaku Nitta, C.-M. Hu, L. E. Hayward, M. P. Wismayer, and B. W. Southern:
    „Spin wave hybridization via direct mapping of spin wave evolution in ferromagnetic microstructures”,
    J. Appl. Phys., 109, 093902 (2011).
     
  91. X. F. Zhu, M. Harder, J. Tayler, A. Wirthmann, B. Zhang, W. Lu, Y. S. Gui, and C.-M. Hu:
    „Nonresonant spin rectification in the absence of an external applied magnetic field”,
    Phys. Rev. B, 83, 140402(R) (2011). (A Rapid Communication)
     
  92. X. F. Zhu, M. Harder, A. Wirthmann, B. Zhang, W. Lu, Y. S. Gui, and C.-M. Hu:
    „Dielectric measurements via a phase-resolved spintronic technique”,
    Phys. Rev. B, 83, 104407 (2011).
     
  93. Xiaolong Fan, E. Himbeault, Y. S. Gui, A. Wirthmann, G. Williams, Desheng Xue, and C.-M. Hu:
    „Electrical detection of large cone angle spin precession from the linear to the nonlinear regime”,
    J. Appl. Phys., 108, 046102 (2010).
     
  94. Wanjun Jiang, André Wirthmann, Y. S. Gui, X. Z. Zhou, M. Reinwald, W. Wegscheider, C.-M. Hu, and Gwyn Williams:
    „Critical behavior from the anomalous Hall effect in (GaMn)As”,
    Phys. Rev. B, 80, 214409 (2009).
     
  95. Y. S. Gui, A. Wirthmann, and C.-M. Hu:
    „Foldover ferromagnetic resonance and damping in permalloy microstrips”,
    Phys. Rev. B, 80, 184422 (2009). (A 13-paged comprehensive review.)
     
  96. Y. S. Gui, A. Wirthmann, N. Mecking, and C.-M. Hu:
    „Direct measurement of nonlinear ferromagnetic damping via the intrinsic foldover effect”,
    Phys. Rev. B, 80, 060402(R) (2009). (A Rapid Communication)
     
  97. Xiaolong Fan, Y. S. Gui, A. Wirthmann, G. Williams, Desheng Xue, and C.-M. Hu:
    „Electrical detection of microwave assisted magnetization switching in a Permalloy microstrip”,
    Appl. Phys. Lett. 95, 062511 (2009).
     
  98. Xiong Hui, A. Wirthmann, Y. S. Gui, Y. Tian, X. F. Jin, Z. H. Chen, S. C. Shen, and C.-M. Hu:
    „Electric detection of ferromagnetic resonance in single crystal iron film”,
    Appl. Phys. Lett. 93, 232502 (2008).
     
  99. André Wirthmann, Xiong Hui, N. Mecking, Y. S. Gui, T. Chakraborty, C.-M. Hu, M. Reinwald, C. Schüller, and W. Wegscheider:
    „Broadband electrical detection of spin excitations in Ga0.98Mn0.02As using a photovoltage technique”,
    Appl. Phys. Lett. 92, 232106 (2008).
     
  100. L.H. Bai, Y.S. Gui, A. Wirthmann, E. Recksiedler, N. Mecking, C.-M. Hu, Z.H. Chen, and S.C. Shen:
    „The rf magnetic-field vector detector based on the spin rectification effect”,
    Appl. Phys. Lett. 92, 032504 (2008).
     
  101. N. Mecking, Y.S. Gui, and C.-M. Hu:
    „Microwave photovoltage and photoresistance effects in ferromagnetic microstrips”,
    Phys. Rev. B, 76, 224430 (2007). (cited 230+ times)
     
  102. André Wirthmann, Bruce D. McCombe, Detlef Heitmann, Steffen Holland, Klaus-Jürgen Friedland, and Can-Ming Hu:
    „Far-infrared-induced magnetoresistance oscillations in GaAs/AlxGa1-xAs-based two-dimensional electron systems”,
    Phys. Rev. B, 76, 195315 (2007).
     
  103. Y. S. Gui, N. Mecking, A. Wirthmann, L. H. Bai, and C.-M. Hu:
    „Electrical detection of the ferromagnetic resonance: Spin-rectification versus bolometric effect”,
    Appl. Phys. Lett. 91, 082503 (2007).
     
  104. M. Califano, T. Chakraborty, P. Pietiläinen, and C.-M. Hu:
    „Breaking of Larmor's theorem in quantum Hall states with spin-orbit coupling”,
    Phys. Rev. B, 73, 113315 (2006).
     
  105. S. Holland, Y. S. Gui, J. Kruse, D. Heitmann, C.-M. Hu, Y. F. Chen, Z. Cui, and G. Pan:
    „Hybrid devices with high-density nanometallic and nanomagnet dots embedded in the semiconductor”,
    Appl. Phys. Lett. 89, 052106 (2006).
     
  106. A. Wirthmann, Y.S. Gui, C. Zehnder, D. Heitmann, C.-M. Hu, and S. Kettemann:
    „Weak antilocalization in InAs quantum wires”,
    Physica E 34, 493 (2006).
     
  107. K. Bittkau, N. Mecking, Y.S. Gui, Ch. Heyn, D. Heitmann, and C. -M. Hu:
    „Photoconductivity spectroscopy on InxAl1-xAs parabolic quantum wells in the optical phonon regime”,
    Phys. Rev. B, 71, 035337 (2005).
     
  108. K. Bittkau, C. Zehnder, Ch. Heyn, D. Heitmann, and C. -M. Hu:
    „Intrasubband magnetoplasmon LO-phonon coupling in an InAs antidot array”,
    Phys. Rev. B, 70, 125314 (2004).
     
  109. S. Holland, C. -M. Hu, Ch. Heyn and D. Heitmann:
    „Bernstein modes in tunneling-coupled quantum wells”,
    Superlattices and Microstructures 33, 301 (2004).
     
  110. K. Bittkau, Ch. Menk, Ch. Heyn, D. Heitmann, and C.-M. Hu:
    „Far-infrared photoconductivity of electrons in an array of nanostructured antidots”,
    Phys. Rev. B, 68, 195303 (2003).
     
  111. C.-M. Hu, C. Zehnder, Ch. Heyn, D. Heitmann:
    „THz collective spin-flip excitation of a two-dimensional electron system”,
    Phys. Rev. B, 67, 201302(R) (2003). (A Rapid Communication)
     
  112. C. Zehnder, A. Wirthmann, Ch. Heyn, D. Heitmann and C.-M. Hu:
    „Bolometric spin effect due to internal spin injection in a two-dimensional electron system”,
    Europhys. Lett., 63, 576 (2003).
     
  113. M.T. Bootsmann, C.-M. Hu, Ch. Heyn, D. Heitmann, and C. Schüller:
    „Acoustic plasmons and indirect intersubband excitations in tunneling-coupled GaAs-AlGaAs double quantum wells”,
    Phys. Rev. B, 67, 121309(R) (2003). (A Rapid Communication)
     
  114. S. Holland, K. Bittkau, C.-M. Hu, Ch. Heyn, and D. Heitmann:
    „Filling factor dependent oscillations of the coupled intersubband plasmon-LO phonon mode in tunneling coupled bilayer system”,
    Phys. Rev. B 66, 233302 (2002).
     
  115. S. Holland, C.-M. Hu, Ch. Heyn, and D. Heitmann:
    „Plasmons in tunneling coupled bilayer systems with tunable space symmetry studied by far-infrared spectroscopy ”,
    Phys. Rev. B 66, 073305 (2002).
     
  116. T. Matsuyama, C.-M. Hu, D. Grundler, G. Meier, and U. Merkt:
    „Ballistic spin transport and spin interference in ferromagnet/InAs(2DES)/ferromagnet devices”,
    Phys. Rev. B 65, 155322 (2002). (cited 200+ times)
     
  117. Z.-F. Li, W. Lu, S.C. Shen, S. Holland, C.-M. Hu, D. Heitmann, B. Shen, Y.D. Zheng, T. Someya, and Y. Arakawa:
    „Cyclotron resonance and magnetotransport measurements in AlGaN/GaN heterostructures for x = 0.15-0.30”,
    Appl. Phys. Lett. 80, 431 (2002).
     
  118. S. Mendach, C.-M. Hu, Ch. Hyen, S. Schnüll, H.P. Oepen, R. Anton, W. Hansen:
    „Stain relaxation in high mobility InAs inserted-channel heterostructures with metamorphic buffer”,
    Physica E 13, 1204 (2002).
     
  119. T. Matsuyama, C.-M. Hu, D. Grundler, G. Meier, D. Heitmann, and U. Merkt:
    „Spin interference and Fabry-Perot resonances in ferromagnet-semiconductor-ferromagnet devices”,
    Physica E 13, 577 (2002).
     
  120. C.-M. Hu, D. Heitmann, R. Winkler, C.R. Becker, Y.S. Gui, B. Zhang, E. Batke, G. Landwehr, and L. Molenkamp:
    „Far-Infrared Magnetoabsorption Studies of HgMnTe Quantum Wells Grown on CdZnTe Substrate”,
    in Towards The Controllable Quantum States: Mesoscopic Superconductivity and Spintronics, Editors: H. Takayanagi and J. Nitta, World Scientific, p. 155 (2002).
     
  121. C.-M. Hu, C. Schüller, and D. Heitmann:
    „Space asymmetry induced plasmon mode-mixing and anti-crossing in coupled bilayer structures”,
    Phys. Rev. B 64, 073303 (2001).
     
  122. C.-M. Hu, J. Nitta, A. Jensen, J. B. Hansen, and H. Takayanagi:
    „Spin polarised transport in a two dimensional electron gas with inter-digital-ferromagnetic contacts”,
    Phys. Rev. B 63, 125333 (2001). (cited 220+ times)
     
  123. J. Nitta, C.-M. Hu, A. Jensen, J. B. Hansen, and H. Takayanagi:
    „Spin injectionand detection experiment in a two dimensional electron gas with inter-digital-ferromagnetic contacts”,
    Physica E 10, 467 (2001).
     
  124. J. Nitta, C.-M. Hu, A. Jensen, J. B. Hansen, and H. Takayanagi:
    „Spin injection experiment with multiple NiFe/InAs-2DEG/NiFe junctions”,
    Physica C 352, 215 (2001).
     
  125. Y. S. Gui, C.-M. Hu, Z.H. Chen, G.Z. Chen, S.L. Guo, J.H. Chu, J.X. Chen, and A.Z. Li:
    „Spin splitting in pseudomorphic InGaAs/InAlAs graded heterostructures”,
    Phys. Rev. B 61, 7237 (2000).
     
  126. C.-M. Hu, and D. Heitmann:
    „Bilayer quantum transistor”,
    Appl. Phys. Lett. 77, 1475 (2000).
     
  127. C.-M. Hu, J. Nitta, T. Akazaki, and H. Takayanagi:
    „Evidence of the Coulomb gap observed in an InAs inserted InGaAs/InAlAs heterostructure”,
    Physica E 7. 795 (2000).
     
  128. C.-M Hu, J. Nitta, T. Akazaki, H. Takayanagi, J. Osaka, P. Pfeffer, and W. Zawadzki:
    „Observation of the zero-field spin splitting of the second subband in an inverted InGaAs/InAlAs heterostructure ”,
    Physica E 6, 767 (2000).
     
  129. C.-M Hu, J. Nitta, T. Akazaki, H. Takayanagi, J. Osaka, P. Pfeffer, and W. Zawadzki:
    „Zero-field spin splitting in an inverted InGaAs/InAlAs heterostructure: band nonparabolicity influence and the subband dependence”,
    Phys. Rev. B 60, 7736 (1999). (cited 270+ times)
     
  130. X. H. Shi, P. L. Liu, G. L.Shi, C.-M. Hu, Z. H. Chen, S. C. Shen, J. X. Chen, H. P. Xin, and A.Z. Li:
    „Magnetospectroscopy of high-purity InP grown by gas source molecular beam epitaxy”,
    Appl. Phys. Lett. 72, 1487 (1998).
     
  131. C.-M. Hu, E. Batke, S.C. Shen, K. Köhler, P. Ganser:
    „Coupled cyclotron resonance transitions of bilayer 2DEG systems in GaAs”,
    Physica B 256-258, 494 (1998).
     
  132. C.-M. Hu, E. Batke, K. Köhler, P. Ganser:
    „Interaction ruled temperature dependence of the electron cyclotron mass in GaAs heterojunction”,
    Physica B 249-251, 749 (1998).
     
  133. Zhanghai Chen, C.-M. Hu, P. L. Liu, G. L. Shi, and S. C. Shen:
    „High-lying thermally excited subbands of two-dimensional electron gases in GaAs/AlGaAs heterojunction for modulation-doped field-effect transistor”,
    J. Appl. Phys. 82, 3900 (1997).
     
  134. Zhanghai Chen, Zhonghui Chen, P. L. Liu, G. L. Shi, C.-M. Hu, X. H. Shi, and S. C. Shen:
    „High-lying metastable states of Si donors in GaAs under magnetic field”,
    J. Appl. Phys. 81, 6183 (1997).
     
  135. C.-M. Hu, E. Batke, K. Köhler and P. Ganser:
    „Influence of the electron-electron and electron-phonon interaction on cyclotron resonance of 2DEG in GaAs ”,
    Surf. Sci. 361/362, 456 (1996).
     
  136. C.-M. Hu, T. Friedrich, E. Batke, K. Köhler and P. Ganser:
    „Spin split cyclotron resonance and spatial distribution of interacting electrons”,
    Phys. Rev. B 52, 12090 (1995).
     
  137. E. Batke, K. Bollweg, U. Merkt, C.-M. Hu, K. Köhler and P. Ganser:
    „Temperature-dependent cyclotron resonances in n-type GaAs”,
    Phys. Rev. B 48, 8761 (1993).
     
  138. H. J. Ye, C.-M. Hu, Y. X. Huang, Z. Y. Ran, S. Y. Tian, J. Q. Liu, and Z. X. Zhao:
    „Infrared properties of Y1-xPrxBa2Cu3O7+d”,
    Phys. Rev. B 46, 6630 (1992).
     
  139. H. J. Ye, C.-M. Hu, Y. X. Huang, F. X. Lu, Z. T. Wang, W. S. Zeng, G. Y. Zhang, and S. L. Yan:
    „Far-infrared and infrared reflections of Tl2Ba2Ca2Cu3O10 film”,
    Acta Physica Sinica 1, 51 (1992).
     
  140. C.S. Chen, F.Q. Zeng, Y.X. Huang, H.J. Ye, C.-M. Hu, and D.K. Schroder:
    „Thermal configurations of oxygen in Silicon”,
    Appl. Phys. A 55, 317 (1992).
     
  141. C.-M. Hu, Y. X. Huang, H. J. Ye, M. W. Qi and S. C. Shen:
    „Nitrogen-Oxygen complexes in Si Studied by photothermal ionization spectroscopy”,
    Appl. Phys. Lett. 59, 2260 (1991).