[1] Li Yue, Shangjie Xue, Jiarui Li, Wen Hu, Andi Barbour, Feipeng Zheng, Lichen Wang, Ji Feng, Stuart B. Wilkins, Claudio Mazzoli, Riccardo Comin, and Yuan Li, “Distinction between pristine and disorder-perturbed charge density waves in ZrTe3.” Nature Communications 11, 98 (2020).
[2] Lichen Wang, Biqiong Yu, Ran Jing, Xiangpeng Luo, Junbang Zeng, Jiarui Li, Izabela Bialo, Martin Bluschke, Yang Tang, Jacob Freyermuth, Guichuan Yu, Ronny Sutarto, Feizhou He, Eugen Weschke, Wojciech Tabis, Martin Greven, and Yuan Li, “Doping-dependent phonon anomaly and charge-order phenomena in the HgBa2CuO4+d and HgBa2CaCu2O6+d superconductors.” Preprint at arXiv:1910.08254.
[3] Jianqing Guo, Li Yue, Kazuki Iida, Kazuya Kamazawa, Lei Chen, Tingting Han, Yan Zhang, and Yuan Li, “Preferred magnetic excitations in the iron-based Sr1-xNaxFe2As2 superconductor.” Physical Review Letters 122, 017001 (2019).
[4] Weiliang Yao, Chenyuan Li, Lichen Wang, Shangjie Xue, Yang Dan, Kazuki Iida, Kazuya Kamazawa, Kangkang Li, Chen Fang, and Yuan Li, “Topological spin excitations in a three-dimensional antiferromagnet.” Nature Physics 14, 1011 (2018).
[5] Kangkang Li, Chenyuan Li, Jiangping Hu, Yuan Li, and Chen Fang, “Dirac and nodal line magnons in three-dimensional antiferromagnets.” Physical Review Letters 119, 247202 (2017).
[6] Mingwei Ma, Philippe Bourges, Yvan Sidis, Yang Xu, Shiyan Li, Biaoyan Hu, Jiarui Li, Fa Wang, and Yuan Li, “Prominent role of spin-orbit coupling in FeSe revealed by inelastic neutron scattering.” Physical Review X 7, 021025 (2017).
[7] Xiao Ren, Lian Duan, Yuwen Hu, Jiarui Li, Rui Zhang, Huiqian Luo, Pengcheng Dai, and Yuan Li, “Nematic crossover in BaFe2As2 under uniaxial stress.” Physical Review Letters 115, 197002 (2015).
[8] W. Tabis, Y. Li, M. Le Tacon, L. Braicovich, A. Kreyssig, M. Minola, G. Dellea, E. Weschke, M.J. Veit, M. Ramazanoglu, A.I. Goldman, T. Schmitt, G. Ghiringhelli, N. Barisic, M.K. Chan, C.J. Dorow, G. Yu, X. Zhao, B. Keimer, and M. Greven, “Charge order and its connection with Fermi-liquid charge transport in a pristine high-Tc cuprate.” Nature Communications 5, 5875 (2014).
[9] Chong Wang, Rui Zhang, Fa Wang, Huiqian Luo, L.P. Regnault, Pengcheng Dai, and Yuan Li, “Longitudinal spin excitations and magnetic anisotropy in antiferromagnetically ordered BaFe2As2.” Physical Review X 3, 041036 (2013).
[10] Yuan Li, M. Le Tacon, Y. Matiks, A.V. Boris, T. Loew, C.T. Lin, Lu Chen, M.K. Chan, C. Dorow, L. Ji, N. Barisic, X. Zhao, M. Greven, and B. Keimer, “Doping-dependent photon scattering resonance in the model high-temperature superconductor HgBa2CuO4+d revealed by Raman scattering and optical ellipsometry.” Physical Review Letters 111, 187001 (2013).
[11] Yuan Li, M. Le Tacon, M. Bakr, D. Terrade, D. Manske, R. Hackl, L. Ji, M. K. Chan, N. Barisic, X. Zhao, M. Greven, and B. Keimer, “Feedback effect on high-energy magnetic fluctuations in the model high-temperature superconductor HgBa2CuO4+d observed by electronic Raman scattering.” Physical Review Letters 108, 227003 (2012).
[12] Yuan Li, G. Yu, M. K. Chan, V. Baledent, Yangmu Li, N. Barisic, X. Zhao, K. Hradil, R. A. Mole, Y. Sidis, P. Steffens, P. Bourges, and M. Greven, “Two Ising-like magnetic excitations in a single-layer cuprate superconductor.” Nature Physics 8, 404 (2012).
[13] Yuan Li, N. Egetenmeyer, J.L. Gavilano, N. Barisic, and M. Greven, “Magnetic vortex lattice in HgBa2CuO4+d observed by small-angle neutron scattering.” Physical Review B 83, 054507 (2011).
[14] Yuan Li, V. Baledent, G. Yu, N. Barisic, K. Hradil, R.A. Mole, Y. Sidis, P. Steffens, X. Zhao, P. Bourges, and M. Greven, “Hidden magnetic excitation in the pseudogap phase of a high-Tc superconductor.” Nature 468, 283 (2010).
[15] G. Yu, Yuan Li, E.M. Motoyama, and M. Greven, “A universal relationship between magnetic resonance and superconducting gap in unconventional superconductors.” Nature Physics 5, 873 (2009).
[16] Yuan Li, V. Baledent, N. Barisic, Y. Cho, B. Fauque, Y. Sidis, G. Yu, X. Zhao, P. Bourges, and M. Greven, “Unusual magnetic order in the pseudogap region of the superconductor HgBa2CuO4+d.” Nature 455, 372 (2008).