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成果及论文

詹清峰教授:

69. J. Liu, J. N. Chen, Y. R. Zhang, S. J. Fu, G. Z. Chai, C. M. Cao, X. Y. Zhu, Y. B. Guo, W. J. Cheng, D. M. Jiang, Z. J. Zhao, and Q. F. Zhan, ACS Appl. Mater. Interfaces 13, 29975 (2021).

68. C. M. Cao, S. W. Chen, W. J. Song, X. Y. Zhu, S. Hu, X. P. Qiu, G. Z. Chai, L. Sun, W. J. Cheng, D. M. Jiang, and Q. F. Zhan, Appl. Phys. Lett. 118, 112402 (2021).

67. S. M. Liang, Y. Miao, X. Y. Zhu, J. Wei, Q. F. Zhan, X. H. Huang, and L. D. Zhang, ACS Appl. Mater. Interfaces 13, 11424 (2021).

66. Z. C. Li, J. P. Zhao, Q. X. Zhu, X. W. Lv, C. M. Cao, X. Y. Zhu, L. Sun, Y. Peng, W. J. Cheng, D. M. Jiang, and Q. F. Zhan, J. Alloys Compd. 868, 159220 (2021).

65. C. Y. Zhang, Y. L. Xie, Q. F. Zhan, and Y. Hu, Phys. Rev. B 103, 014445 (2021).

64. N. N. Song, B. Y. Lv, J. Meng, Z. Z. Gong, X. D. Zhang, Q. F. Zhan, J. Magn. Magn. Mater. 519, 167510 (2021).

63. J. P. Zhao, Q. H. Guo, H. Z. Yin, J. T. Zou, Z. J. Zhao, W. J. Cheng, D. M. Jiang, and Q. F. Zhan, Chin. Phys. B 29, 117501 (2020).

62. Y. L. Xie, Q. F. Zhan, Y. Hu, X. Hu, X. D. Chi, C. Y. Zhang, H. L. Yang, W. H. Xie, X. Y. Zhu, J. H. Gao, W. J. Cheng, D. M. Jiang, and R. W. Li, NPG Asia Mater. 12, 67 (2020).

61. Z. Wang, Z. Zhou, W. J. Cheng, D. M. Jiang, and Q. F. Zhan, J. Magn. Magn. Mater. 513, 167126 (2020).

60. R. Zhu, T. Shang, S. Hu, Y. Y. Zhang, X. P. Qiu, W. J. Cheng, D. M. Jiang, and Q. F. Zhan, J. Magn. Magn. Mater. 512, 167042 (2020).

59. H. Z. Yin, Z. Zhou, W. J. Cheng, D. M. Jiang, Z. J. Zhao, and Q. F. Zhan, J. Magn. Magn. Mater. 497, 165911 (2020).

58. Y. Li, Y. Li, Q. Liu, Z. Yuan, Q. F. Zhan, W. He, H. L. Liu, K. Xia, W. Yu, X. Q. Zhang, and Z. H. Cheng, New J. Phys. 21, 123001 (2019).

57. W. Zhang, Q. Liu, Z. Yuan, K. Xia, W. He, Q. F. Zhan, X. Q. Zhang, and Z. H. Cheng, Phys. Rev. B 100, 104412 (2019).

56. W. J. Cheng, Z. Zhou, M. J. Pan, H. L. Yang, Y. L. Xie, B. M. Wang, Q. F. Zhan, and R. W. Li, J. Phys. D: Appl. Phys. 52, 095003 (2019).

55. S. Hu, K. Pei, B. M. Wang, W. X. Xia, H. L. Yang, Q. F. Zhan, X. G. Li, X. C. Liu, and R. W. Li, Phys. Rev. B 97, 054422 (2018).

54. J. C. Li, Q. F. Zhan, S. L. Zhang, J. W. Wei, J. B. Wang, M. J. Pan, Y. L. Xie, H. L. Yang, Z. Zhou, S. H. Xie, B. M Wang, and R. W. Li, Sci. Rep. 7, 2837 (2017).

53. P. Dhanapal, S. S. Guo, B. M. Wang, H. L. Yang, S. Agarwal, Q. F. Zhan, and R. W. Li, Appl. Phys. Lett. 111, 162401 (2017).

52. X. C. Wen, B. M. Wang, P. Sheng, S. Hu, H. L. Yang, K. Pei, Q. F. Zhan, W. X. Xia, H. Xu, and R. W. Li, Appl. Phys. Lett. 111, 142403 (2017).

51. X. Y. Qiao, X. C. Wen, B. M. Wang, Y. H. Bai, Q. F. Zhan, X. H. Xu, and R. W. Li, Appl. Phys. Lett. 111, 132405 (2017).

50. J. Shang, W. H. Xue, Z. H. Ji, G. Liu, X. H. Niu, X. H. Yi, L. Pan, Q. F. Zhan, X. H. Xu, and R. W. Li, Nanoscale 9, 7037–7046 (2017).

49. T. Shang, H. L. Yang, Q. F. Zhan, Z. H. Zuo, Y. L. Xie, L. P. Liu, S. L. Zhang, Y. Zhang, H. H. Li, B. M. Wang, Y. H. Wu, S. Zhang, and R. W. Li, J. Appl. Phys. 120, 133901 (2016).

48. Y. Gao, B. You, X. Z. Ruan, M. Y. Liu, H. L. Yang, Q. F. Zhan, Z. Li, N. Lei, W. S. Zhao, D. F. Pan, J. G. Wan, J. Wu, H. Q. Tu, J. Wang, W. Zhang, Y. B. Xu, and J. Du, Sci. Rep. 6, 32617 (2016).

47. T. Shang, Q. F. Zhan, H. L. Yang, Z. H. Zuo, Y. L. Xie, L. P. Liu, S. L. Zhang, Y. Zhang, H. H. Li, B. M. Wang, Y. H. Wu, S. Zhang, and R. W. Li, Appl. Phys. Lett. 109, 032410 (2016).

46. H. H. Li, Q. F. Zhan, Y. W. Liu, L. P. Liu, H. L. Yang, Z. H. Zuo, T. Shang, B. M. Wang, and R. W. Li, ACS Nano 10, 4403 (2016).

45. S. L. Zhang, Q. F. Zhan, Y. Yu, L. P. Liu, H. H. Li, H. L. Yang, Y. L. Xie, B. M. Wang, S. H. Xie, and R. W. Li, Appl. Phys. Lett. 108, 102409 (2016).

44. T. Shang, Q. F. Zhan, L. Ma, H. L. Yang, Z. H. Zuo, Y. L. Xie, H. H. Li, L. P. Liu, B. M. Wang, Y. H. Wu, S. Zhang, and R. W. Li, Sci. Rep. 5, 17734 (2015).

43. Z. H. Zuo, B. Chen, B. M. Wang, H. L. Yang, Q. F. Zhan, Y. W. Liu, J. L. Wang, and R. W. Li, Sci. Rep. 5, 16164, (2015).

42. T. Shang, Q. F. Zhan, H. L. Yang, Z. H. Zuo, Y. L. Xie, Y. Zhang, L. P. Liu, B. M. Wang, Y. H. Wu, S. Zhang, and R. W. Li, Phys. Rev. B 92, 165114 (2015).

41. Y. Zhang, Q. F. Zhan, Z. H. Zuo, H. L. Yang, X. S. Zhang, G. H. Dai, Y. W. Liu, Y. Yu, J. Wang, B. M. Wang, and R. W. Li, Phys. Rev. B 91, 174411 (2015).

40. H. L. Yang, Y. W. Liu, J. D. Zhang, X. Q. Zhang, Z. H. Cheng, Y. L. Xie, B. M. Wang, Q. F. Zhan, B. G. Shen, E. W. Plummer, and R. W. Li, Phys. Rev. B 91, 174405 (2015).

39. Y. Yu, Q. F. Zhan, J. W. Wei, J. B. Wang, G. H. Dai, Z. H. Zuo, X. S. Zhang, Y. W. Liu, H. L. Yang, Y. Zhang, S. H. Xie, B. M. Wang, and R. W. Li, Appl. Phys. Lett. 106, 162405 (2015).

38. Y. W. Liu, Q. F. Zhan, G. H. Dai, X. S. Zhang, B. M. Wang, G. Liu, Z. H. Zuo, X. Rong, H. L. Yang, X. J. Zhu, Y. L. Xie, B. Chen, and R. W. Li, Sci. Rep. 4, 6925 (2014).

37. Y. W. Liu, B. M. Wang, Q. F. Zhan, Z. H. Tang, H. L. Yang, G. Liu, Z. H. Zuo, X. S. Zhang, Y. L. Xie, X. J. Zhu, B. Chen, J. L. Wang, and R. W. Li, Sci. Rep. 4, 6615 (2014).

36. Z. H. Yang, Q. F. Zhan, X. J. Zhu, Y. W. Liu, H. L. Yang, B. L. Hu, J. Shang, L. Pan, B. Chen, and R. W. Li, EPL 108, 58004 (2014).

35. B. F. Miao, L. Sun, Y. W. Wu, X. D. Tao, X. Xiong, Y. Wen, R. X. Cao, P. Wang, D. Wu, Q. F. Zhan, B. You, J. Du, R. W. Li, and H. F. Ding, Phys. Rev. B 90, 174411 (2014).

34. Z. H. Tang, B. M. Wang, H. L. Yang, X. Y. Xu, Y. W. Liu, D. D. Sun, L. X. Xia, Q. F. Zhan, B. Chen, M. H. Tang, Y. C. Zhou, J. L. Wang, and R. W. Li, Appl. Phys. Lett. 105, 103504 (2014).

33. W. He, B. Hu, Q. F. Zhan, X. Q. Zhang, and Z. H. Cheng, Appl. Phys. Lett. 104, 142405 (2014).

32. H. L. Yang, B. M. Wang, Y. W. Liu, Z. H. Yang, X. J. Zhu, Y. L. Xie, Z. H. Zuo, B. Chen, Q. F. Zhan, J. L. Wang, and R. W. Li, J. Appl. Phys. 116, 34505 (2014).

31. G. H. Dai, Q. F. Zhan, H. L. Yang, Y. W. Liu, X. S. Zhang, Z. H. Zuo, B. Chen, and R. W. Li, J. Appl. Phys. 114, 173913 (2013).

30. Y. W. Liu, Z. H. Yang, H. L. Yang, Y. L. Xie, S. Katlakunta, B. Chen, Q. F. Zhan, and R. W. Li, J. Appl. Phys. 113, 17C722 (2013).

29. X. S. Zhang, Q. F. Zhan, G. H. Dai, Y. W. Liu, Z. H. Zuo, H. L. Yang, B. Chen, and R. W. Li, J. Appl. Phys. 113, 17A901 (2013).

28. Z. H. Zuo, Q. F. Zhan, G. H. Dai, B. Chen, X. S. Zhang, H. L. Yang, Y. W. Liu, and R. W. Li, J. Appl. Phys. 113, 17C705 (2013).

27. Y. L. Xie, H. L. Yang, Y. W. Liu, Z. H. Yang, B. Chen, Z. H. Zuo, S. Katlakunta, Q. F. Zhan, and R. W. Li, J. Appl. Phys. 113, 17C716 (2013).

26. K. Sadhana, S. R. Murthy, S. Jie, Y. L. Xie, Y. W. Liu, Q. F. Zhan, and R. W. Li, J. Appl. Phys. 113, 17C731 (2013).

25. X. S. Zhang, Q. F. Zhan, G. H. Dai, Y. W. Liu, Z. H. Zuo, H. L. Yang, B. Chen, and R. W. Li, Appl. Phys. Lett. 102, 022412 (2013).

24. G. H. Dai, Q. F. Zhan, Y. W. Liu, H. L. Yang, X. S. Zhang, B. Chen, and R. W. Li, Appl. Phys. Lett. 100, 122407 (2012).

23. B. Chen, Z. H. Zuo, Y. W. Liu, Q. F. Zhan, Y. L. Xie, H. L. Yang, G. H. Dai, Z. X. Li, G. J. Xu, and R. W. Li, Appl. Phys. Lett. 100, 173903 (2012).

22. Y. W. Liu, Z. H. Yang, H. L. Yang, T. Zou, Y. L. Xie, B. Chen, Y. Sun, Q. F. Zhan, and R. W. Li, J. Phys. D: Appl. Phys. 45, 245001 (2012).

21. Z. H. Zuo, B. Chen, Q. F. Zhan, Y. W. Liu, H. L. Yang, Z. X. Li, G. J. Xu, and R. W. Li, J. Phys. D: Appl. Phys. 45, 185302 (2012).

20. Q. F. Zhan, W. Zhang, and K. M. Krishnan,Phys. Rev. B 83, 094404 (2011).[选入Physical Review B杂志20113月的kaleidoscope 图片论文.]

19. Y. F. Hou, Q. F. Zhan, and K. M. Krishnan,Appl. Phys. Lett. 98, 042510 (2011).

18. B. Chen, M. Li, Y. W. Liu, Z. H. Zuo, F. Zhuge, Q. F. Zhan, and R. W. Li, Nanotechnology 22, 195201 (2011). [选入英国纳米科技网Nanotechweb.org研究亮点文章.]

17. Q. F. Zhan and K. M. Krishnan,Appl. Phys. Lett. 96, 112506 (2010).

16. Y. P. Fang, W. He, H. L. Liu, Q. F. Zhan, H. F. Du, Q. Wu, H. T. Yang, X. Q. Zhang, and Z. H. Cheng, Appl. Phys. Lett. 97, 022507 (2010).

15. Q. F. Zhan and K. M. Krishnan,J. Appl. Phys. 107 09D703 (2010).

14. S. Brück, S. Macke, E. Goering, X. S. Ji, Q. F. Zhan, and K. M. Krishnan, Phys. Rev. B 81, 134414 (2010).

13. Q. F. Zhan, S. Vandezande, C. Van Haesendonck, and K. Temst, Phys. Rev. B 80, 094416 (2009).

12. Q. F. Zhan, S. Vandezande, C. Van Haesendonck, and K. Temst, New J. Phys. 11 063003 (2009).

11. Q. F. Zhan, C. Van Haesendonck, S. Vandezande, and K. Temst, Appl. Phys. Lett. 94, 042504 (2009).

10. J. H. Gao, D. L. Sun, X. Q. Zhang, Q. F. Zhan, W. He, Y. Sun, and Z. H. Cheng, Appl. Phys. Lett. 92, 102501 (2008).

9. Q. F. Zhan, S. Vandezande, C. Van Haesendonck, and K. Temst, Appl. Phys. Lett. 91, 122510 (2007). [选入Virtual Journal of Nanoscale Science & Technology, October 1, 2007.]

8. J. H. Gao, D. L. Sun, Q. F. Zhan, W. He, and Z. H. Cheng, Phys. Rev. B 75, 064421 (2007). [选入Virtual Journal of Nanoscale Science & Technology, March 12, 2007.]

7. D. Y. Wang, H. Y. Wu, L. J. Chen, W. He, Q. F. Zhan, and Z. H. Cheng, J. Phys.: Condens. Matter 18, 6357 (2006).

6. D. Y. Wang, L. J. Chen, W. He, Q. F. Zhan, and Z. H. Cheng, J. Phys. D: Appl. Phys. 39, 347 (2006).

5. Q. F. Zhan, J. H. Gao, Y. Q. Liang, N. L. Di, and Z. H. Cheng, Phys. Rev. B 72, 024428 (2005).

4. J. H. Gao, Q. F. Zhan, W. He, D. L. Sun, and Z. H. Cheng, Appl. Phys. Lett. 86, 232506 (2005).

3. Q. F. Zhan, W. He, X. Ma, Y. Q. Liang, Z. Q. Kou, N. L. Di, and Z. H. Cheng, Appl. Phys. Lett. 85, 4690 (2004).

2. Q. F. Zhan, Z. Y. Chen, D. S. Xue, F. S. Li, H. Kunkel, X. Z. Zhou, R. Roshko, and G. Williams, Phys. Rev. B 66, 134436 (2002).

1. Z. Y. Chen, Q. F. Zhan, D. S. Xue, F. S. Li, X. Z. Zhou, H. Kunkel, and G. Williams, J. Phys.: Condens. Matter 14, 613 (2002).

 

商恬研究员:

2022

1. H. Zhang, X. Y. Zhu, Y. Xu*, D. J. Gawryluk, W. Xie, S. L. Ju, M. Shi, T. Shiroka, Q. F. Zhan, E. Pomjakushina*, T. Shang*, Giant magnetoresistance and topological Hall effect in the EuGa4 antiferromagnet, J. Phys.: Condens. Matt. 34, 034005 (2022).

2. X. Y. Zhu, H. Zhang, D. J. Gawryluk, Z. X. Zhen, B. C. Yu, S. L. Ju, W. Xie, D. M. Jiang, W. J. Cheng, Y. Xu, M. Shi, E. Pomjakushina, Q. F. Zhan, T. Shiroka*, and T. Shang*, Spin order and fluctuations in the EuAl4 and EuGa4 topological antiferromagnets: A muSR study, Phys. Rev. B 105, 0144213 (2022). 

3. Soohyeon Shin, Vladimir Pomjakushin, Marek Bartkowiak, Marisa Medarde, Tian Shang, Dariusz J. Gawryluk, Ekaterina Pomjakushina, Cu-doping effects on the ferromagnetic semimetal CeAuGe, J. Magn. Magn. Mater. 551, 169174 (2022). 

4. G. Lamura, D. Das, T. Shang, J. Peng, Y. Wang, Z.Q. Mao, T. Shiroka, muSR investigation of the Fe-doped Ca3Ru2O7 polar metal, J. Magn. Magn. Mater. 551, 169138 (2022).

5. Xiaoyan Zhu, Yang Xu, Cuimei Cao, Tian Shang, Yali Xie, and Qingfeng Zhan, Recent developments on the magnetic and electrical transport properties of FeRh- and Rh-based heterostructures, J. Phys.: Condens. Matt. 34, 144004 (2022).

6. Junzhang Ma, Simin Nie, Xin Gui, Muntaser Naamneh, Jasmin Jandke, Chuanying Xi, Jinglei Zhang, Tian Shang, Yimin Xiong, Itzik Kapon, Neeraj Kumar, Yona Soh, Daniel Gosálbez-Martínez, Oleg V. Yazyev, Wenhui Fan, Hannes Hübener, Umberto De Giovannini, Nicholas Clark Plumb, Milan Radovic, Michael Andreas Sentef, Weiwei Xie, Zhijun Wang, Christopher Mudry, Markus Müller, Ming Shi,Multiple mobile excitons manifested as sidebands in quasi-one-dimensional metallic TaSe3, Nature Materials 21, 423-429 (2022).

7. D. Tay, T. Shang*, Y. P. Qi, T. P. Ying, H. Hosono, H-R. Ott, T. Shiroka*, s-wave superconductivity in the noncentrosymmetric W3Al2C superconductor: An NMR study, , J. Phys.: Condens. Matt. 34, 194005 (2022).

8. Tian Shang, Sudeep K. Ghosh, Michael Smidman, Dariusz Jakub Gawryluk, Christopher Baines, An Wang, Wu Xie, Ye Chen, Mukkattu O. Ajeesh, Michael Nicklas, Ekaterina Pomjakushina, Marisa Medarde, Ming Shi, James F. Annett, Huiqiu Yuan*, Jorge Quintanilla*, and Toni Shiroka*, Spin-triplet superconductivity in Weyl nodal-line semimetals, npj Quantum Materials 7, 35 (2022).

9.  J. Lyu, M. Morin, T. Shang, M. T. Fernández-Díaz, and M. Medarde,Weak ferromagnetism linked to the high-temperature spiral phase of YBaCuFeO5, Phys. Rev. Research 4, 023008 (2022).

10. T. Shang*, D. Tay, H. Su, H. Q. Yuan, and T. Shiroka, Evidence of fully gapped superconductivity in NbReSi: A combined muSR and NMR study, Phys. Rev. B 105, 144506 (2022). 

11.  Xiaoyan Zhu, Yang Li, Yali Xie , Qian Qiu, Cuimei Cao, Xiao Hu, Wenhui Xie*, Tian Shang, Yang Xu, Lin Sun, Wenjuan Cheng, Dongmei Jiang, Qingfeng Zhan*, Magnetocrystalline anisotropy of epitaxially grown FeRh/MgO(001) films, Journal of Alloys and Compounds 917, 165566 (2022).

12. T. Shiroka*, T. Shang*, M. Juckel, M. Krnel, M. König, U. Burkhardt, P. Koželj, R. Gupta, Yu. Prots, and E. Svanidze*, Superconductivity of MoBe22 and WBe22 at ambient- and under applied-pressure conditions, Phys. Rev. Materials, 6, 064804 (2022). 

13. Jonas A. Krieger, Daniel Tay, Igor P. Rusinov, Sourabh Barua, Pabitra K. Biswas, Lukas Korosec, Thomas Prokscha, Thorsten Schmitt, Niels B. M. Schröter, Tian Shang, Toni Shiroka, Andreas Suter, Geetha Balakrishnan, Evgueni V. Chulkov, Vladimir N. Strocov, Zaher Salman, Hydrogen-impurity induced unconventional magnetism in semiconducting molybdenum ditelluride, arXiv: 2206.03051.

14.   T. Shang*, #, J. Philippe#, X. Y. Zhu, H. Zhang, B. C. Yu, Z. X. Zhen, H.-R. Ott, J. Kitagawa, and T. Shiroka*, Fully gapped superconducting state in interstitial-carbon-doped Zr5Pt3, Phys. Rev. B. 106, 014507 (2022). 


2021

1.   T. Shang*, W. Xie, J. Z. Zhao,Y. Chen, D. J. Gawryluk, M. Medarde, M. Shi, H. Q. Yuan, E. Pomjakushina, and T. Shiroka, Multigap superconductivity in centro- and noncentrosymmetric rhenium-boron superconductors, Phys. Rev. B 103, 184517 (2021) .

2.  Tian Shang* and Toni Shiroka*, Time-Reversal Symmetry Breaking in Re-Based Superconductors: Recent Develoopments, Front. Phys. 9, 651163 (2021) (review article).

3. Y. Xu*, L. Das, J. Z. Ma, C. J. Yi, Y. G. Shi, A. Tiwari, S. S. Tsirkin, T. Neupert, M. Medarde, M. Shi, J. Chang*, T. Shang*, Unconventional Transverse Transport above and below the Magnetic Transition Temperature in Weyl Semimetal EuCd2As2, Phys. Rev. Lett. 126, 076602 (2021).

4. T. Shang*,Y. Xu*, D. J. Gawryluk,J. Z. Ma,T. Shiroka,M. Shi,and E. Pomjakushina*, Anomalous Hall resistivity and possible topological Hall effect in the EuAl4 antiferromagnet, Phys. Rev. B 103, L020405 (2021).

5.  Lun-Hui Hu*, Xuepeng Wang*, T. Shang*, Spontaneous magnetization in time-reversal symmetry breaking unitary superconductors, Phys. Rev. B 104, 054520 (2021).

6. Lakshmi Das, Yang Xu, Tian Shang, Alexander Steppke, Masafumi Horio, Jaewon Choi, Simon Johr, Karin Von Arx, Jasmin Mueller, Dominik Biscette, Xiaofu Zhang, Andreas Schilling, Veronica Granata, Rosalba Fittipaldi, Antonio Vecchione, Johan Chang, Two-carrier Magnetoresistance: Applications to Ca3Ru2O7, J. Phys. Soc. Jpn. 90, 054702 (2021).

7.  H. Su, T. Shang*, F. Du, C. F. Chen, H. Q. Ye, X. Lu, C. Cao, M. Smidman, H. Q. Yuan*,  NbReSi: A Noncentrosymetric Superconductor with Large Upper Critical Field, Phys. Rev. Materials 5, 114802 (2021).


2020

1. Tian Shang*, Christopher Baines, Lieh-Jeng Chang, Dariusz Jakub Gawryluk, Ekaterina Pomjakushina, Ming Shi, Marisa Medarde, and Toni Shiroka*, Re1-xMox as an ideal test case of time-reversal symmetry breaking in unconventional superconductors, npj Quantum Materials 5, 76 (2020).

2. T. Shang*, W. Xie, D. J. Gawryluk, R. Khasanov, J. Z. Zhao, M. Medarde, M. Shi, H. Q. Yuan, E. Pomjakushina, and T. Shiroka, Multigap superconductivity in the Mo5PB2 boron-phosphorus compound, New J. Phys. 22, 093016 (2020).

3. T. Shang*, S. K. Ghosh*, J. Z. Zhao, L.-J. Chang, C. Baines, M. K. Lee, D. J. Gawryluk, M. Shi, M. Medarde, J. Quintanilla, and T. Shiroka, Time-reversal symmetry breaking in the noncentrosymmetric superconductor Zr3Ir, Phys. Rev. B 102, 020503(R) (2020) (Editors’ suggestion).

4. T. Shang*, J. Z. Zhao*, D. J. Gawryluk, M. Shi, M. Medarde, E. Pomjakushina, T. Shiroka, Superconductivity and topological aspects of the rock-salt carbides NbC and TaC, Phys. Rev. B 101, 214518 (2020)(Editors' Suggestion).

5. T. Shang*, M. Smidman, A. Wang, L. -J. Chang, C. Baines, M. K. Lee, Z. Y. Nie, G. M. Pang, W. Xie, W. B. Jiang, M. Shi, M. Medarde, T. Shiroka, and H. Q. Yuan*, Simultaneous Nodal Superconductivity and Time-Reversal Symmetry Breaking in the Noncentrosymmetric Superconductor CaPtAs, Phys. Rev. Lett. 124, 207001 (2020) (Editors' Suggestion).

6. Y. Xu*, S. Jöhr, L. Das, J. Kitagawa, M. Medarde, T. Shiroka, J. Chang, and T. Shang*, Multiple- to single-gap superconductivity crossover in Nb5Ir3-xPtxO alloys, Phys. Rev. B 101, 134513 (2020).

7. T. Shang*, D. J. Gawryluk*, M. Naamneh, Z. Salman, Z. Guguchia, M. Medarde, M. Shi, N. C. Plumb, and T. Shiroka, Strong- to weak-coupling superconductivity in high-Tc bismuthates: revisiting the phase diagram via MuSR, Phys. Rev. B 101, 014508 (2020).

8. D. Tay, T. Shang, P. Puphal, E. Pomjakushina, H.-R. Ott, and T. Shiroka, Temperature-dependent 27Al NMR shift in the Weyl-fermion systems LaAlGe and PrAlGe, Phys. Rev. B 102, 241109 (2020).

9. Sudeep Kumar Ghosh, Michael Smidman, Tian Shang, James F. Annett, Adrian Hillier, Jorge Quintanilla, Huiqiu Yuan, Recent progress on superconductors with time-reversal symmetry breaking, J. Phys.: Condens. Matt. 33 033001 (2020)(review article).

10. Rui Zhu, Tian Shang, Shuai Hu, Yuanyuan Zhang, Xuepeng Qiu, Wenjuan Cheng, Dongmei Jiang*, Qingfeng Zhan, Spin-Hall magnetoresistance in Ta/Cr/YIG trilayers with different Cr thicknesses, J. Magn. Magn. Mater. 512, 167042 (2020).

11. Shangxiong Huangfu, Zurab Guguchia, Denis Cheptiakov, Xiaofu Zhang, Hubertus Luetkens, Dariusz Jakub Gawryluk, Tian Shang, Fabian O. von Rohr, Andreas Schilling, Short-range magnetic interactions and spin-glass behavior in the quasi-2D nickelate Pr4Ni3O8, Phys. Rev. B 102, 054423 (2020).

12. S. Shin, V. Pomjakushin, L. Keller, P. F. S. Rosa, U. Stuhr, C. Niedermayer, R. Sibille, S. Toth, J. Kim, H. Jang, S.-K. Son, H.-O. Lee, T. Shang, M. Medarde, E. D. Bauer, M. Kenzelmann, and T. Park, Magnetic structure and crystalline electric field effects in the triangular antiferromagnet CePtAl4Ge2, Phys. Rev. B 101, 224421 (2020).

13. Pascal Puphal, Sarah Krebber, Emmanuelle Suard, Robert Cubitt, Chennan Wang, Tian Shang, Victor Ukleev, Jonathan S. White, Ekaterina Pomjakushina, Development of the magnetism in the solid solution of the candidate Weyl semimetals CexPr1−xAlGe, Phys. Rev. B 101, 214416 (2020).

14. W. Xie, P. R. Zhang, B. Shen, W. B. Jiang, G. M. Pang, T. Shang, C. Cao, M. Smidman, H. Q. Yuan, CaPtAs: a new noncentrosymmetric superconductor, Sci. China-Phys. Mech. Astron. 63, 237412 (2020).


2019

1. T. Shang*, A. Amon, D. Kasinathan, W. Xie, M. Bobnar, Y. Chen, A. Wang, M. Shi, M. Medarde, H. Q. Yuan, and T. Shiroka*, Enhanced Tc and multiband superconductivity in the fully-gapped ReBe22 superconductor, New J. Phys. 21, 073034 (2019).

2. T. Shang*, J. Philippe, J. A. T. Verezhak, Z. Guguchia, J. Z. Zhao, L.-J. Chang, M. K. Lee, D. J. Gawryluk, E. Pomjakushina, M. Shi, M. Medarde, H.-R. Ott, and T. Shiroka, Nodeless superconductivity and preserved time-reversal symmetry in the noncentrosymmetric Mo3P superconductor, Phys. Rev. B 99, 184513 (2019);

3. T. Shang*, D. J. Gawryluk*, J. A. Verezhak, E. Pomjakushina, M. Shi, M. Medarde, J. Mesot, and T. Shiroka, Structure and superconductivity in the binary Re1−xMox alloys, Phys. Rev. Materials 3, 024801 (2019).

4. D. J. Gawryluk, Y. M. Klein, T. Shang, D. Sheptyakov, L. Keller, N. Casati, Ph. Lacorre, M. T. Fernández-Díaz, J. Rodríguez-Carvajal, and M. Medarde, Distortion mode anomalies in bulk PrNiO3: Illustrating the potential of symmetry-adapted distortion mode analysis for the study of phase transitions, Phys. Rev. B 100, 205137 (2019).

5. Natalija van Well, Claudio Eisele, Sitaram Ramakrishnan, Tian Shang, Marisa Medarde, Antonio Cervellino, Markos Skoulatos, Robert Georgii, Sander van Smaalen, Tetragonal Mixed System Cs2CuCl4–xBrComplemented by the Tetragonal Phase Realization of Cs2CuCl4, Cryst. Growth Des. 19, 19, 6627 (2019).

6. K. Guratinder, Jeffrey G. Rau, V. Tsurkan, C. Ritter, J. Embs, T. Fennell, H. C. Walker, M. Medarde, T. Shang, A. Cervellino, Ch. Rüegg, and O. Zaharko, Multiphase competition in the quantum XY pyrochlore antiferromagnet CdYb2Se4: zero and applied magnetic field study, Phys. Rev. B 100, 094420 (2019).

7. Sumit Ranjan Maity, Monica Ceretti, Lukas Keller, Jürg Schefer, Tian Shang, Ekaterina Pomjakushina, Martin Meven, Denis Sheptyakov, Antonio Cervellino, and Werner Paulus, Structural disorder and magnetic correlations driven by oxygen doping in Nd2NiO4+δ (δ0.11), Phys. Rev. Materials 3, 083604 (2019).

8. J.-Z. Ma, S. M. Nie, C. J. Yi, J. Jandke, T. Shang, M. Y. Yao, M. Naamneh, L. Q. Yan, Y. Sun, A. Chikina, V. N. Strocov, M. Medarde, M. Song, Y.-M. Xiong, G. Xu, W. Wulfhekel, J. Mesot, M. Reticcioli, C. Franchini, C. Mudry, M. Müller, Y. G. Shi, T. Qian, H. Ding, M. Shi, Spin fluctuation induced Weyl semimetal state in the paramagnetic phase of EuCd2As2, Science Advances 5, eaaw4718 (2019).

9. A. Zorko, M. Pregelj, M. Klanjšek, M. Gomilšek, Z. Jagličić, J. S. Lord, J. A. T. Verezhak, T. Shang, W. Sun, and J.-X. Mi, Coexistence of magnetic order and persistent spin dynamics in a quantum kagome antiferromagnet with no intersite mixing, Phys. Rev. B 99, 214441 (2019).

10. N. Barbero, M. Medarde, T. Shang, D. Sheptyakov, C. P. Landee, J. Mesot, H.-R. Ott, and T. Shiroka, Room-temperature structural phase transition in the quasi-2D spin-1/2 Heisenberg antiferromagnet Cu(pz)2(ClO4)2, Phys. Rev. Materials 3, 053602 (2019).

11. Marc Raventós, Michael Tovar, Marisa Medarde, Tian Shang, Markus Strobl, Stavros Samothrakitis, Ekaterina Pomjakushina, Christian Grünzweig, and Søren Schmidt, Laue three dimensional neutron diffraction,Scientific Reports 9, 4798 (2019).

12. Pascal Puphal, Charles Mielke, Neeraj Kumar, Y. Soh, Tian Shang, Marisa Medarde, Jonathan S. White, and Ekaterina Pomjakushina, Bulk single-crystal growth of the theoretically predicted magnetic Weyl semimetals RAlGe (R = Pr, Ce), Phys. Rev. Materials 3, 024801 (2019).

13. Daniel E. McNally, Xingye Lu, Jonathan Pelliciari, Sophie Beck, Marcus Dantz, Muntaser Naamneh, Tian Shang, Marisa Medarde, Christof W. Schneider, Vladimir N. Strocov, Ekaterina V. Pomjakushina, Claude Ederer, Milan Radovic and Thorsten Schmitt, Electronic localization in CaVO3 films via bandwidth control, npj Quantum Materials 4, 6 (2019).


2018

1. T. Shang*, M. Smidman*, S. K. Ghosh, C. Baines, L. J. Chang, D. J. Gawryluk, J. A. T. Barker, R. P. Singh, D. Mck. Paul, G. Balakrishnan, E. Pomjakushina, M. Shi, M. Medarde, A. D. Hillier, H. Q. Yuan, J. Quintanilla*, J. Mesot, T. Shiroka*, Time-reversal symmetry breaking in Re-based superconductors, Phys. Rev. Lett., 121, 257002 (2018).

2. T Shang*, Wensen Wei, C. Baines, J. L. Zhang, H. F. Du, M. Medarde, M. Shi, J. Mesot, T. Shiroka, Nodeless superconductivity in noncentrosymmetric Mo3Rh2N: A µSR study, Phys. Rev. B 98, 180504(R) (2018).

3. T. Shang*, E. Canévet, M. Morin,D. Sheptyakov, M. T. Fernández-Díaz, E. Pomjakushina, and M. Medarde*, Design of magnetic spirals in layered perovskites: Extending the stability range far beyond room temperature, Science Advances 4, eaau6386 (2018).

4. T. Shang*, G. M. Pang, C. Baines, W. B. Jiang, W. Xie, A. Wang, M. Medarde, E. Pomjakushina, M. Shi, J. Mesot, H. Q. Yuan, and T. Shiroka, Nodeless superconductivity and time-reversal symmetry breaking in the noncentrosymmetric superconductor Re24Ti5, Phys. Rev. B 97, 020502(R) (2018).

5. S. Mukherjee, K. Shimamoto, Y. W. Windsor, M. Ramakrishnan, S. Parchenko, U. Staub, L.Chapon, B. Ouladdiaf, M. Medarde, T. Shang, E. A. Müller, M. Kenzelmann, T. Lippert, C. W. Schneider, and C. Niedermayer, Multiferroic phase diagram of E-type RMnO3 films studied by neutron and x-ray diffraction, Phys. Rev. B 98, 174416 (2018).

6. D. Kumar, C. N. Kuo, F. Astuti, T. Shang, M. K. Lee, C. S. Lue, I. Watanabe, J. A. T. Barker, T. Shiroka, and L. J. Chang, Nodeless superconductivity in the cage-type superconductor Sc5Ru6Sn18 with preserved time-reversal symmetry, J. Phys.: Condens. Matt. 30, 315803 (2018).

7. N. Barbero, S. Holenstein, T. Shang, Z. Shermadini, F. Lochner, I. Eremin, C. Wang, G.-H. Cao, R. Khasanov, H.-R. Ott, J. Mesot, and T. ShirokaPressure effects on the electronic properties of the undoped superconductor ThFeAsN, Phys. Rev. B 97, 140506 (R) (2018).

8. L. M. Tran, M. Babij, L. Korosec, T. Shang, Z. Bukowski, and T. Shiroka, Magnetic phase diagram of Ca-substituted EuFe2As2, Phys. Rev. B 98, 104412 (2018).

9. Yali Xie, Qingfeng Zhan, Tian Shang, Huali Yang, Yiwei Liu, Baomin Wang, and Run-Wei Li, Electric field control of magnetic properties in FeRh/PMN-PT heterostructures, AIP Advances 8, 055816 (2018).


2017

1. T. Shiroka*, T. Shang*, C. Wang, G.-H. Cao, I. Eremin, H.-R. Ott, and J. Mesot, High Tc superconductivity 

       in undoped  ThFeAsN, Nat. Commun. 8, 156 (2017).

2. M. O. Ajeesh, T. Shang, W. B. Jiang, W. Xie, R. D. dos Reis , M. Smidman, C. Geibel, H. Q. Yuan, and M. NicklasIsing-type Magnetic Anisotropy in CePd2As2, Scientific Reports 7, 7738 (2017).

3.Yali Xie, Qingfeng Zhan, Tian Shang, Huali Yang, Baomin Wang, and Run-Wei Li, Effect of epitaxial strain and lattice mismatch on magnetic and transport behaviors in metamagnetic FeRh thin films, AIP Advances 7, 056314 (2017).


2016

1. T. Shang, Q. F. Zhan, H. L. Yang, Z. H. Zuo, Y. L. Xie, L. P. Liu, S. L. Zhang, Y. Zhang, H. H. Li, B. M. Wang, Y. H. Wu, S. Zhang, Run-Wei Li, Effect of NiO inserted layer on spin-Hall magnetoresistance in Pt/NiO/YIG heterostructures, Appl. Phys. Lett. 109, 032410 (2016).

2. T. Shang, H. L. Yang, Q. F. Zhan, Z. H. Zuo, Y. L. Xie, L. P. Liu, S. L. Zhang, Y. Zhang, H. H. Li, B. M. Wang, Y. H. Wu, S. Zhang, Run-Wei Li, Effect of IrMn inserted layer on anomalous-Hall resistance and spin-Hall magnetoresistance in Pt/IrMn/YIG heterostructures, J. Appl. Phys. 120, 133901 (2016).

3. C. E. Matt, N. Xu, Baiqing Lv, Junzhang Ma, F. Bisti, J. Park, T. Shang, Chongde Cao, A.H. Nevidomskyy, Pengcheng Dai, L. Patthey, N.C. Plumb, M. Radovic, J. Mesot, and M. Shi, NaFe0.56Cu0.44As: A pnictide insulating phase induced by on-site Coulomb interaction, Phys. Rev. Lett. 117. 097001 (2016).

4. Z. F. Weng, J. L. Zhang, M. Smidman, T. Shang, J. Quintanilla, J. F. Annett, M. Nicklas, G. M. Pang, L. Jiao, W. B. Jiang, Y. Chen, F. Steglich, and H. Q. Yuan, Two-gap superconductivity in LaNiGa2 with non-unitary triplet pairing and even parity gap symmetry, Phys. Rev. Lett., 117. 027001 (2016) (editor suggested).

5. Huihui Li, Qingfeng Zhan, Yiwei Liu, Luping Liu, Huali Yang, Zhenghu Zuo, Tian Shang, Baomin Wang, and Run-Wei Li, Stretchable Spin Valve with Stable Magnetic Field Sensitivity by Ribbon-Patterned Periodic Wrinkles, ACS Nano 10, 4403 (2016).

6. N. C. Plumb, D. J. Gawryluk, Y. Wang, Z. Ristić, J. Park, B. Q. Lv, Z. Wang, C. E. Matt, N. Xu, T. Shang, K. Conder, J. Mesot, S. Johnston, M. Shi, M. Radović, Momentum-resolved electronic structure of the high-Tsuperconductor parent compound BaBiO3, Phys. Rev. Lett. 117, 037002 (2016).


2015

1. T. Shang, Q. F. Zhan, H. L. Yang, Z. H. Zuo, Y. L. Xie, Y. Zhang, L. P. Liu, B. M. Wang, Y. H. Wu, S. Zhang, and Run-Wei Li, Pure spin-Hall magnetoresistance in Rh/Y3Fe5O12 hybrid, Scientific Reports 5, 17734 (2015).

2. T. Shang, Q. F. Zhan, H. L. Yang, Z. H. Zuo, Y. L. Xie, Y. Zhang, L. P. Liu, B. M. Wang, Y. H. Wu, S. Zhang, and Run-Wei Li, Extraordinary Hall resistance and unconventional magnetoresistance in Pt/LaCoO3 hybrids, Phys. Rev. B 92, 165114 (2015).

3. T. Shang, Y. H. Chen, F. Ronning, N. Cornell, A. Zakhidov, J. D. Thompson, M. B. Salamon and H. Q. Yuan, Magnetocrystalline anisotropic effect in GdCo1-xFexAsO (x= 0,0.05),Phys. Rev. B 91, 125106 (2015).

4. W. B. Jiang, L. Yang, C. Y. Guo, Z. Hu, J. M. Lee, M. Smidman, Y. F. Wang, T. Shang, Z. W. Cheng, F. Gao, H. Ishii, K. D. Tsuei, Y. F. Liao, X. Lu, L. H. Tjeng, J. M. Chen, H. Q. Yuan, Crossover from a heavy fermion to intermediate valence state in noncentrosymmetric Yb2Ni12(P,As)7, Scientific Reports 5, 17608 (2015).

5. O. Janka, T. Shang, R. Baumbach, E. Bauer, J. D.Thompson, S. Kauzlarich, Structure and Magnetic Properties of Ce3(Ni/Al/Ga)11 – A New Member of the La3Al11 Type Structural Family, Crystals 5, 1-8 (2015).

6. Lin Jiao, Ye Chen, Yoshimitsu Kohama, David Graf, E. D. Bauer, John Singleton, Jian-Xin Zhu, Zongfa Weng, Guiming Pang, Tian Shang, Jinglei Zhang, Han-Oh Lee, Tuson Park, Marcelo Jaime, J. D. Thompson, Frank Steglich, Qimiao Si, and H. Q. Yuan, Fermi surface reconstruction and multiple quantum phase transitions in the antiferromagnet CeRhIn5, Proc. Nat. Acad. Sci. (PNAS) 112, 673 (2015).

7. W. B. Jiang, C. Y. Guo, Z. F. Weng, Y. F. Wang, Y. H. Chen, Y. Chen, G. M. Pang, T. Shang, X. Lu and H. Q. Yuan, Superconductivity and structural distortion in BaPt2As2,J. Phys.: Condens. Matt. 27, 022202 (2015).


2014

1. T. Shang, Y. H. Chen, W. B. Jiang, Y. Chen, L. Jiao, J.L. Zhang, Z. F. Weng, X. Lu, and H. Q. Yuan, Tunable magnetic orders in CePd2As2-xPx, J. Phys.: Condens. Matt. 26, 045601 (2014).

2. T. Shang, E. D. Bauer, R. E. Baumbach, F. Ronning, K. Gofryk, Z. F. Weng, J. L. Zhang, X. Lu, J. D. Thompson, and H. Q. Yuan, CeIrIn5: Superconductivity on a Magnetic Instability, Phys. Rev. B 89, 041101(R) (2014) (Editors' Suggestion).

3. Soohyeon Shin, T. Shang, H. Q. Yuan, Tuson Park, Synthesis and pressure effects on the La doped CaFe2As2, Progress in Superconductivity and Cryogenics 16, 1-5 (2014).


2013

1. T. Shang, L. Yang, Y. Chen, N. Cornell, F. Ronning, J. L. Zhang, L. Jiao, Y. H. Chen, J. Chen, A. Howard, J. Dai, J. D. Thompson, A. Zakhidov, M. B. Salamon, and H. Q. Yuan,Tunable interplay between 3d and 4 f electrons in Co-doped iron pnictides, Phys. Rev. B87, 075148 (2013).

2. T. Shang, L. Jiao, J. Dai, H.Q.Yuan, F. F. Balakirev, W. Z. Hu, and N. L. Wang, Robust Magnetic Order of Ce 4f-electrons Coexisting with Superconductivity in CeFeAsO1−xFx, Journal of the Korean Physical Society 62, 2001 (2013).

3. L. Jiao, Z. F. Weng, X. Y. Tang, L. K. Guo, T. Shang, L. Yang, H. Q. Yuan, Y. Y. Wu, Z. C. Xia, Anisotropic in-plane resistivity and magnetoresistance of the detwinned BaFe2As2, Journal of the Korean Physical Society 63, 453 (2013).


2012

1. R. E. Baumbach, T. Shang, M. Torrez, F. Ronning, J. D. Thompson and E. D. Bauer, Local Moment ferromagnetism in CeRu2Ga2B, J. Phys.: Condens. Matt. 24, 185702 (2012).

2. L. Jiao, Y. Kohama, J. L. Zhang, H. D. Wang, B. Maiorov, F. F. Balakirev, Y. Chen, L. N. Wang, T. Shang, M. H. Fang, and H. Q. Yuan, Upper critical field and thermally activated flux flow in single-crystalline Tl0.58Rb0.42Fe1.72Se2, Phys. Rev. B 85, 064513 (2012).



徐杨研究员:


第一或通讯作者:


20. Anomalous spin current anisotropy in a noncollinear antiferromagnet.

Nature Communications 14, 5873 (2023).

Cuimei Cao#, Shiwei Chen#, Rui-Chun Xiao, Zengtai Zhu, Guoqiang Yu, Yangping Wang, Xuepeng Qiu, Liang Liu, Tieyang Zhao, Ding-Fu Shao*, Yang Xu*, Jingsheng Chen*, and Qingfeng Zhan*.

19. Unambiguous experimental verification of linear-in-temperature spinon thermal conductivity in an antiferromagnetic Heisenberg chain.

Physical Review Letters 129, 167201 (2022).

B. Y. Pan#, Y. Xu# *. J. M. Ni. S. Y. Zhou, X. C. Hong, X. Qiu, and S. Y. Li*.

18. Critical topology and pressure-induced superconductivity in the van der Waals compound AuTe2Br

npj Quantum Materials 7, 93 (2022).

Erjian Cheng#, Xianbiao Shi# *, Limin Yan#, Tianheng Huang, Fengliang Liu, Wenlong Ma, Zeji Wang, Shuang Jia, Jian Sun, Weiwei Zhao, Wenge Yang*, Yang Xu*, and Shiyan Li*.

17. Efficient tuning of the spin-orbit torque via the magnetic phase transition of FeRh.

ACS Nano 16, 12727 (2022).

Cuimei Cao# , Shiwei Chen#, Baoshan Cui, Guoqiang Yu, Changhuan Jian, Zhenzhong Yang, Xuepeng Qiu, Tian Shang, Yang Xu*, and Qingfeng Zhan*.

16. Quantum critical magnetic excitations in spin-1/2 and spin-1 chain systems.

Physical Review X 12, 021020 (2022).

Y. Xu# *, L. S. Wang#, Y. Y. Huang, J. M. Ni, C. C. Zhao, Y. F. Dai, B. Y. Pan, X. C. Hong, P. Chauhan, S. M. Koohpayeh, N. P. Armitage, and S. Y. Li*.

15. Recent developments on the magnetic and electrical transport properties of FeRh- and Rh-based heterostructures.

Journal of Physics: Condensed Matter 34, 144004 (2022).

Xiaoyan Zhu, Yang Xu*, Cuimei Cao, Tian Shang , Yali Xie and Qingfeng Zhan*.

14. Heat transport in herbertsmithite: Can a quantum spin liquid survive disorder?

Physical Review Letters 127, 267202 (2021).

Y. Y. Huang#, Y. Xu# *, Le Wang#, C. C. Zhao, C. P. Tu, J. M. Ni, L. S. Wang, B. L. Pan, Ying Fu, Zhanyang Hao , Cai Liu, Jia-Wei Mei*, and S. Y. Li*.

13. Unconventional transverse transport above and below the magnetic transition temperature in Weyl semimetal EuCd2As2.

Physical Review Letters 126, 076602 (2021).

Y. Xu*, L. Das, J. Z. Ma, C. J. Yi, S. M. Nie, Y. G. Shi, A. Tiwari, S. S. Tsirkin, T. Neupert, M. Medarde, M. Shi, J. Chang*, and T. Shang*.

12. Magnetotransport of dirty-limit van Hove singularity quasiparticles.

Communications Physics 4, 1 (2021).

Y. Xu, F. Herman, V. Granata, D. Destraz, L. Das, J. Vonka, S. Gerber, J. Spring, M. Gibert, A. Schilling, X. Zhang, S. Y. Li, R. Fittipaldi, Mark H. Fischer, A. Vecchione, and J. Chang*.

11. Anomalous Hall resistivity and possible topological Hall effect in the EuAl4 antiferromagnet.

Physical Review B 103, L020405 (2021).

T. Shang*, Y. Xu*, D. J. Gawryluk, J. Z. Ma, T. Shiroka, M. Shi, and E. Pomjakushina*.

10. Specific heat and thermal conductivity of the triangular-lattice rare-earth material KBaYb(BO3)2 at ultralow temperature.

Physical Review B 103, 104412 (2021).

B. L. Pan, J. M. Ni, L. P. He, Y. J. Yu, Y. Xu*, and S. Y. Li*.

9.  Giant magnetoresistance and topological Hall effect in the EuGa4 antiferromagnet.

Journal of Physics: Condensed Matter 34, 034005 (2021).

H. Zhang#, X. Y. Zhu#, Y. Xu*, D. J. Gawryluk, W. Xie, S. L. Ju, M. Shi, T. Shiroka, Q. F. Zhan, E. Pomjakushina*, and T. Shang*.

8. Crossover from multiple- to single-gap superconductivity in Nb5Ir3−xPtxO alloys.

Physical Review B 101, 134513 (2020).

Y. Xu*, S. Jöhr, L. Das, J. Kitagawa, M. Medarde, T. Shiroka, J. Chang, and T. Shang*.

7. Nodeless superconducting gap in topological superconductor candidate 2M-WS2.

Physical Review B 102, 024523 (2020).

L. S. Wang, Y. Q. Fang, Y. Y. Huang, E. J. Cheng, J. M. Ni, B. L. Pan, Y. Xu*, F. Q. Huang*, and S. Y. Li*.

6. Ultralow-temperature thermal conductivity of the Kitaev honeycomb magnet α-RuCl3 across the field-induced phase transition.

Physical Review Letters 120, 067202 (2018).

Y. J. Yu#, Y. Xu#, K. J. Ran#, J. M. Ni, Y. Y. Huang, J. H. Wang, J. S. Wen*, and S. Y. Li*.

5. Heat transport study of the spin liquid candidate 1T-TaS2.

Physical Review B 96, 081111 (R) (2017).

Y. J. Yu#, Y. Xu#, L. P. He, M. Kratochvilova, Y. Y. Huang, J. M. Ni, L. H. Wang, Sang Wook Cheong, Je-Geun Park, and S. Y. Li*.

4. Absence of magnetic thermal conductivity in the quantum spin liquid candidate YbMgGaO4.

Physical Review Letters 117, 267202 (2016).

Y. Xu, J. Zhang, Y. S. Li, J. Yu, X. C. Hong, Q. M. Zhang, and S. Y. Li*.

3. Bulk Fermi surface of charge-neutral excitations in SmB6 or not: A heat-transport study.

Physical Review Letters 116, 246403 (2016). 

Y. Xu, S. Cui, J. K. Dong, D. Zhao, T. Wu, X. H. Chen, K. Sun, H. Yao, and S. Y. Li*.

2. Universal heat conduction in Ce1−xYbxCoIn5: Evidence for robust nodal d-wave superconducting gap.

Physical Review B 93, 064502 (2016).

Y. Xu, J. K. Dong*, I. K. Lum, J. Zhang, X. C. Hong, L. P. He, K. F. Wang, Y. C. Ma, C. Petrovic, M. B. Maple, L. Shu*, and S. Y. Li*.

1. Experiment to measure the performance parameters of radio-frequency cavities used in synchrotron radiation.

Physics Experimentation 32, 11001 (2012).

H. Zhou#, Y. Xu#, and X. Y. Zhang*.


其他:


38. The discovery of three-dimensional Van Hove singularity.

Nature Communications 15, 2313 (2024).

Wenbin Wu#, Zeping Shi#, Mykhaylo Ozerov, Yuhan Du, Yuxiang Wang, Xiao-Sheng Ni, Xianghao Meng, Xiangyu Jiang, Guangyi Wang, Congming Hao, Xinyi Wang, Pengcheng Zhang, Chunhui Pan, Haifeng Pan, Zhenrong Sun, Run Yang, Yang Xu, Yusheng Hou, Zhongbo Yan, Cheng Zhang, Hai-Zhou Lu, Junhao Chu, Xiang Yuan*.

37. Tunable positions of Weyl nodes via magnetism and pressure in the ferromagnetic Weyl semimetal CeAlSi.

Nature Communications 15, 1467 (2024).

Erjian Cheng# *, Limin Yan#, Xianbiao Shi#, Rui Lou# *, Alexander Fedorov, Mahdi Behnami, Jian Yuan, Pengtao Yang, Bosen Wang, Jin-Guang Cheng, Yuanji Xu, Yang Xu, Wei Xia, Nikolai Pavlovskii, Darren C. Peets, Weiwei Zhao, Yimin Wan, Ulrich Burkhardt, Yanfeng Guo, Shiyan Li, Claudia Felser, Wenge Yang*, Bernd Büchner*.

36. A Co-doped Ag3PO4 photocatalyst: Efficient degradation of organic pollutants and enhancement mechanism.

Molecular Catalysis 558, 114033 (2024).

Rui Lu, Jiaying Luo, Xuening Wang, An Chen, Yiwen Xie, Yang Xu, Tian Shang, Ruyan Li, Dongmei Jiang*, Qingfeng Zhan.

35. Antiferromagnetic magnetostriction of IrMn detected by angular dependent exchange bias.

Applied Physics Letters 124, 112412 (2024).

Haoyu Lin, Kun Zheng, Jing Meng, Jiang Liu, Zhenjie Zhao, Dongmei Jiang, Yang Xu, Tian Shang, Qingfeng Zhan*.

34. Epitaxial growth and electric control of magnetic behaviors in exchange biased IrMn/FeGa/MgO/PMN-PT heterostructures.

Journal of Alloys and Compounds 970, 172604 (2024).

J. Meng, X. W. Feng, C. M. Cao, Y. L. Xie, D. M. Jiang, Y. Xu, T. Shang, and Q. F. Zhan*.

33. Enhanced photocatalytic performance of Fe-doped AgBr for organic contaminants degradation: The role of doping and mechanism insights.

Materials Research Bulletin 170, 112567 (2024).

Rui Lu, Lingxi Qiu, Yiwen Xie, Jiaying Luo, An Chen, Yang Xu, Tian Shang, Dongmei Jiang*, and Qingfeng Zhan.

32. Absence of topological Hall effect in FexRh100−x epitaxial films: Revisiting their phase diagram.

Physical Review B 108, 144437 (2023).

X. Y. Zhu, H. Li, J. Meng, X. W. Feng, Z. X. Zhen, H. Y. Lin, B. C. Yu, W. J. Cheng, D. M. Jiang, Y. Xu, T. Shang*, and Q. F. Zhan*.

31. Z-scheme Bi2SiO5/Ni-doped Ag6Si2O7 heterojunction with remarkable photocatalytic performance for MO degradation with enhanced light absorption ability: Adjustment of electron transfer path and energy band structure.

Applied Surface Science 642, 158465 (2024).

An Chen, Yiwen Xie, Rui Lu, Jiaying Luo, Tian Shang, Yang Xu, Dongmei Jiang*, and Qingfeng Zhan.

30. Fourfold magnetic anisotropy varied by interfacial exchange coupling in epitaxial Fe/IrMn bilayers.

Applied Physics Letters 123, 122402 (2023).

Xinwei Feng, Yangping Wang, Jing Meng, Haoyu Lin, Xiaoyan Zhu, Yali Xie*, Dongmei Jiang, Yang Xu, Tian Shang, and Qingfeng Zhan*

29. Neutron scattering and muon-spin spectroscopy studies of the magnetic triangular-lattice compounds A2La2NiW2O12 (A = Sr,Ba).

Physical Review Materials 7, 074403 (2023).

B. C. Yu#, J. Y. Yang#, D. J. Gawryluk, Y. Xu, Q. F. Zhan, T. Shiroka, and T. Shang*.

28. Nonlinear phonon Hall effects in ferroelectrics: Existence and nonvolatile electrical control.

Physical Review B 107, L241107 (2023).

Wei Luo#, Junyi Ji#, Peng Chen, Yang Xu, Lifa Zhang*, Hongjun Xiang*, and Laurent Bellaiche.

27. Fully gapped superconductivity with preserved time-reversal symmetry in NiBi3 single crystals.

Physical Review B 107, 174513 (2023).

T. Shang*, J. Meng, X. Y. Zhu, H. Zhang, B. C. Yu, Z. X. Zhen, Y. H. Wang, Y. Xu, Q. F. Zhan, D. J. Gawryluk, and T. Shiroka.

26. Stabilizing high-frequency magnetic properties of stretchable CoFeB films by ribbon-patterned periodic wrinkles.

ACS Applied Materials & Interfaces 15, 15014 (2023).

Kelei Xue, Zheng Zhou*, Huali Yang, Anyang Cui, Wenjuan Cheng*, Dongmei Jiang, Yang Xu, Tian Shang, and Qingfeng Zhan*.

25. Fourfold magnetic anisotropy induced in CoFeB/IrMn bilayers by interfacial exchange coupling. 

New Journal of Physics 25 023005 (2023). 

Xinwei Feng, Jing Meng, Xiaoyan Zhu, Kelei Xue, Yali Xie, Dongmei Jiang, Yang Xu, Tian Shang, Yong Hu, and Qingfeng Zhan*.

24. Evidence of unconventional pairing in the quasi-two-dimensional CuIr2−xRuxTe4 superconductor.

Physical Review B 106, 144505 (2022).

T. Shang# *, Y. Chen#, W. Xie, D. J. Gawryluk, R. Gupta, R. Khasanov, X. Y. Zhu, H. Zhang, Z. X. Zhen, B. C. Yu, Z. Zhou, Y. Xu, Q. F. Zhan, E. Pomjakushina, H. Q. Yuan, and T. Shiroka.

23. Unconventional superconductivity in topological Kramers nodal-line semimetals.

Science Advances 8, eabq6589 (2022).

Tian Shang# *, Jianzhou Zhao#, Lun-Hui Hu#, Junzhang Ma, Dariusz Jakub Gawryluk, Xiaoyan Zhu, Hui Zhang, Zhixuan Zhen, Bocheng Yu, Yang Xu, Qingfeng Zhan, Ekaterina Pomjakushina, Ming Shi, Toni Shiroka*.

22. Effects of manganese-doping on the enhanced solar photocatalytic properties of AgBr catalyst: Mechanism and DFT modeling.

Applied Surface Science 607,154993 (2023).

Yiwen Xie, Wenjie Ding, Jianquan Zhao, Jiaying Luo, Rui Lu, Tian Shang, Yang Xu, Dongmei Jiang*, and Qingfeng Zhan.

21. Positive stretching dependence of resonance frequency in CoFeB films modulated by lateral growth pre-strain.

Journal of Alloys and Compounds 926, 166955 (2022).

Shangjie Fu, Kelei Xue, Guozhi Chai, Yang Xu, Tian Shang, Wenjuan Cheng*, Dongmei Jiang, Qingfeng Zhan*.

20. Surface modified Bi2SiO5 microflowers with Fe3+ doping for efficient degradation of organic contaminants.

Journal of Alloys and Compounds 926, 166866 (2022).

Jiaying Luo, Jianquan Zhao, Yiwen Xie, Rui Lu, Tian Shang, Yang Xu, Dongmei Jiang*, and Qingfeng Zhan.

19. Exchange-coupling-induced fourfold magnetic anisotropy in CoFeB/FeRh bilayer grown on SrTiO3(001).

Chinese Physics B 31, 087503 (2022).

Qingrong Shao, Jing Meng, Xiaoyan Zhu, Yali, Xie, Wenjuan Cheng, Dongmei Jiang, Yang Xu, Tian Shang, and Qingfeng Zhan*.

18. Magnetocrystalline anisotropy of epitaxially grown FeRh/MgO(001) films.

Journal of Alloys and Compounds 917, 165566 (2022).

Xiaoyan Zhu, Yang Li, Yali Xie, Qian Qiu, Cuimei Cao, Xiao Hu, Wenhui Xie, Tian Shang, Yang Xu, Lin Sun, Wenjuan Cheng, Dongmei Jiang, Qingfeng Zhan*.

17. Spin order and fluctuations in the EuAl4 and EuGa4 topological antiferromagnets: A μSR study.

Physical Review B 105, 014423 (2022).

X. Y. Zhu#, H. Zhang#, D. J. Gawryluk, Z. X. Zhen, B. C. Yu, S. L. Ju, W. Xie, D. M. Jiang, W. J. Cheng, Y. Xu, M. Shi, E. Pomjakushina, Q. F. Zhan, T. Shiroka*, and T. Shang*.

16.  Facile synthesis of δ-Bi2O3 particles/ rod-like Bi4O7 composite with enhanced visible light driven photocatalytic performance.

Journal of Materials Science: Materials in Electronics (2022).

Jiaying Luo, Shicheng Jia, Jianquan Zhao, Dongmei Jiang*, Qingfeng Zhan, Tian Shang, and Yang Xu.

15. Electronic Reconstruction Forming a C2-symmetric Dirac Semimetal in Ca3Ru2O7.

npj Quantum Materials 6 29 (2021).

M. Horio*, Q. Wang, V. Granata, K. P. Kramer, Y. Sassa, S. Jöhr, D. Sutter, A. Bold, L. Das, Y. Xu, R. Frison, R. Fittipaldi, T. K. Kim, C. Cacho, J. E. Rault, P. Le Fèvre, F. Bertran, N. C. Plumb, M. Shi, A. Vecchione, M. H. Fischer, and J. Chang*.

14. Two-carrier Magnetoresistance: Applications to Ca3Ru2O7.

Journal of the Physical Society of Japan 90, 054702 (2021).

L. Das, Y. Xu, T. Shang, A. Steppke, M. Horio, J. Choi, S. Jöhr, K. von Arx, J. Mueller, D. Biscette, X. Zhang, A. Schilling, V. Granata, R. Fittipaldi, A. Vecchione, and J. Chang*.

13. Magnetism and anomalous transport in the Weyl semimetal PrAlGe: possible route to axial gauge fields.

npj Quantum Mater. 5, 5 (2020).

D. Destraz*, L. Das, S. Tsirkin, Y. Xu, Titus Neupert, J. Chang*, A. Schilling, Adolfo G. Grushin, Joachim Kohlbrecher, Lukas Keller, Pascal Puphal, Ekaterina Pomjakushina and Jonathan S. White*.

12. Prominent role of spin-orbit coupling in FeSe revealed by inelastic neutron scattering.

Physical Review X 7, 021025 (2017).

M. W. Ma, P. Bourges, Y. Sidis, Y. Xu, S. Y. Li, B. Y. Hu, J. R. Li, F. Wang, and Y. Li*.

11. Observation of two superconducting domes under pressure in tetragonal FeS.

npj Quantum Materials 2, 49 (2017).

J. Zhang, F. L. Liu, T. P. Ying, N. N. Li, Y. Xu, L. P. He, X. C. Hong, Y. J. Yu, M. X. Wang, W. G. Yang*, and S. Y. Li*.

10. Nodeless superconducting gaps in noncentrosymmetric superconductor PbTaSe2 with topological bulk nodal lines.

Physical Review B 93, 020503(R) (2016).

M. X. Wang, Y. Xu, L. P. He, J. Zhang, X. C. Hong, P. L. Cai, Z. B. Wang, J. K. Dong, and S. Y. Li*.

9. Fully gapped superconducting state in Au2Pb: a natural candidate for topological superconductor.

Europhysics Letters 116, 67002 (2016).

Y. J. Yu, Y. Xu, Y. Xing, J. Zhang, T. P. Ying, X. C. Hong, M. X. Wang, X. Zhang, S. Jia, J. Wang*, and S. Y. Li*.

8. Nodeless superconductivity in the noncentrosymmetric superconductor BiPd.

Superconductor Science and Technology 29, 065001 (2016).

X. B. Yan, Y. Xu, L. P. He, J. K. Dong, Hwanbeom Cho, D. C. Peets, Je Geun Park, and S. Y. Li*.

7. Nodal superconductivity in FeS: Evidence from quasiparticle heat transport.

Physical Review B 94, 100504(R) (2016).

T. P. Ying, X. F. Lai, X. C. Hong, Y. Xu, L. P. He, J. Zhang, M. X. Wang, Y. J. Yu, F. Q. Huang*, S. Y. Li*.

6. Electric-field control of magnetism in Co40Fe40B20/(1-x)Pb(Mg1/3Nb2/3)O3-xPbTiO3 multiferroic heterostructures with different ferroelectric phases.

ACS Applied Materials & Interfaces 8, 3784 (2016).

Yan Liu, Yonggang Zhao*, Peisen Li, Sen Zhang, D. Li, Hao Wu, Aitian Chen, Y. Xu, X. F. Han, S. Y. Li, Di Lin, and Haosu Luo.

5. Nodeless superconducting gap in the caged-type superconductors Y5Rh6Sn18 and Lu5Rh6Sn18.

Superconductor Science and Technology 28, 105008 (2015).

Z. Zhang, Y. Xu, C. N. Kuo, X. C. Hong, M. X. Wang, P. L. Cai, J. K. Dong, C. S. Lue, and S. Y. Li*.

4. Superconductivity at 2.5K in the new transition-metal chalcogenide Ta2PdSe5.

Superconductor Science and Technology 28, 11150015 (2015).

J. Zhang, J. K. Dong, Y. Xu, J. Pan, L. P. He, L. J. Zhang, and S. Y. Li*.

3. Structural and transport properties of the Weyl semimetal NbAs at high pressure.

Chinese Physics Letters 32, 097102 (2015).

J. Zhang, F. L. Liu, J. K. Dong, Y. Xu, N. N. W. G. Yang, and S. Y. Li*.

2. Heat transport in RbFe2As2 single crystals: Evidence for nodal superconducting gap.

Physical Review B 91, 024502 (2015).

Z. Zhang, A. F. Wang, X. C. Hong, J. Zhang, B. Y. Pan, J. Pan, Y. Xu, X. G. Luo, X. H. Chen, and S. Y. Li*.

1. Multigap nodeless superconductivity in nickel chalcogenide TlNi2Se2.

Physical Review B 90, 060504(R) (2014).

X. C. Hong, Z. Zhang, S. Y. Zhou, J. Pan, Y. Xu, Hangdong Wang, Qianhui Mao, Minghu Fang, J. K. Dong, and S. Y. Li*.