The Physics Colloquium has been arranged regularly since the fall semester of 2021. The detailed schedule and talk information of this semester are as follows.
For inquiries or suggestions of future speakers, please contact the colloquium working group (Prof. Jane Lixin Dai, Prof. Tran Trung Luu, Prof. Yanjun Tu, Prof. Chenjie Wang, and Prof. Shizhong Zhang).
Electron orbital dynamics in solids
Speaker: Prof. Hyun-Woo LEE
Affiliation: Department of Physics, POSTECH
Date: January 28, 2026 (Wednesday)
Time: 11:15 a.m.
Venue: CYCP1, LG1/F, Chong Yuet Ming Chemistry Building, Main Campus, HKU
Poster: Download
Abstract:
For a long time, it has been believed that electrons' orbital angular momentum is quenched in solids unless induced by the spin-orbit coupling in magnetic materials. Contrary to common belief, recent studies [1-3] have revealed that electron eigenstates may have finite orbital angular momentum even in the absence of spin-orbit coupling when inversion symmetry is broken. In centrosymmetric systems, on the other hand, electron eigenstates do not have orbital angular momentum unless the spin-orbit coupling is strong. Nevertheless, a flow of electrons with finite orbital angular momentum is generated in a transverse direction when an electric field is applied (orbital Hall effect) [4-9]. The first part of this talk aims to present basic ideas of a few key orbital dynamics [10-12], such as the orbital Rashba-Edelstein effect [3], the orbital Hall effect [4-9], and orbital torque [13-16]. The second part deals with more recent topics such as the differences between spin and orbital dynamics [17], and orbital relaxation dynamics [18,19].
Key Reference:
- S. R. Park, C. H. Kim, J. Yu, J. H. Han, and C. Kim, Orbital-angular-momentum based origin of Rashba-type surface band splitting, Phys. Rev. Lett. 107, 156803 (2011).
- V. Sunko et al., Maximal Rashba-like spin splitting via kinetic-energy-coupled inversion-symmetry breaking, Nature 549, 492 (2017).
- A. E. Hamdi et al., Observation of the orbital inverse Rashba–Edelstein effect, Nat. Phys. 19, 1855 (2023).
- B. A. Bernevig, T. L. Hughes, and S.-C. Zhang, Orbitronics: The intrinsic orbital current in 𝑝-Doped silicon, Phys. Rev. Lett. 95, 066601 (2005).
- H. Kontani, T. Tanaka, D. D. Hirashima, K. Yamada, and J. Inoue, Giant orbital Hall effect in transition metals: Origin of large spin and anomalous Hall effects, Phys. Rev. Lett. 102, 016601 (2009).
- T. Tanaka et al., Intrinsic spin Hall effect and orbital Hall effect in 4𝑑 and 5𝑑 transition metals, Phys. Rev. B 77. 165117 (2008).
- D. Go, D. Jo, C. Kim, and H.-W. Lee, Intrinsic spin and orbital Hall effects from orbital texture, Phys. Rev. Lett. 121, 086602 (2018).
- Y.-G. Choi et al., Observation of the orbital Hall effect in a light metal Ti, Nature 619, 52 (2023).
- I. Lyalin, S. Alikhah, M. Beritta, P. M. Oppeneer, and R. K. Kawakami, Magneto-optical detection of the orbital Hall effect in chromium, Phys. Rev. Lett. 131, 156702 (2023).
- D. Go, D. Jo, H.-W. Lee, M. Kläui, and Y. Mokrousov, Orbitronics: Orbital currents in solids, Europhys. Lett. 135, 37001 (2021).
- D. Jo, D. Go, G.-M. Choi, and H.-W. Lee, Spintronics meets orbitronics: Emergence of orbital angular momentum in solids, npj Spintronics 2, 19 (2024).
- R. B. Atencia, A. Agarwal, and D. Culcer, Orbital angular momentum of Bloch electrons: equilibrium formulation, magneto-electric phenomena, and the orbital Hall effect, Adv. Phys.: X, 9, 2371972 (2024).
- D. Go, and H.-W. Lee, Orbital torque: Torque generation by orbital current injection, Phys. Rev. Res. 2, 013177 (2020).
- J. Kim et al., Nontrivial torque generation by orbital angular momentum injection in ferromagnetic-metal/Cu/Al2O3 trilayers, Phys. Rev. B 103, L020407 (2021).
- D. Lee, et al., Orbital torque in magnetic bilayers, Nat. Commun. 12, 6710 (2021).
- R. Gupta et al., Harnessing Orbital Hall Effect in Spin-Orbit Torque MRAM, Nat. Commun. 16, 130 (2024).
- S. Han, H.-W. Lee, and K.-W. Kim, Orbital dynamics in centrosymmetric, Phys. Rev. Lett. 128, 176601 (2022).
- J. Sohn, J. M. Lee, and H.-W. Lee, Dyakonov-Perel-like orbital and spin relaxations in centrosymmetric systems, Phys. Rev. Lett. 132, 246301 (2024).
- S. Peng et al., Unconventional scaling of the orbital Hall effect, Nat. Mater. 24, 1749 (2025).
Speaker: Prof. Zdeněk SOFER
Affiliation: University of Chemistry and Technology Prague
Date: February 11, 2026 (Wed) (Cancelled)
Speaker: Dr. Stanislav KRUCHININ
Affiliation: Microsoft Austria
Date: March 4, 2026 (Wed)
Time: 11:15 a.m.
Venue: CYCP1, LG1/F, Chong Yuet Ming Chemistry Building, Main Campus, HKU
Poster: Download
Abstract:
Neural networks have progressed beyond their original role as computational tools for pattern recognition and data analysis. Contemporary large language models are reshaping the scientific workflow, transforming it from a linear sequence into an autonomous, data-driven cycle of discovery. This talk will examine this paradigmatic shift in the context of nanostructure physics and ultrafast photonics. Specifically, I will discuss how AI facilitates the research process, ranging from automated retrieval and summarization of scientific literature to accelerated hypothesis generation, design of materials, and real-time analysis of ultrafast spectroscopy data. By integrating AI across the entire research pipeline—from literature review to experimental implementation and theoretical analysis—it becomes possible to accelerate discovery and open new avenues for scientific workflow.
Key Reference:
- Wang, H., Fu, T., Du, Y. et al. Scientific discovery in the age of artificial intelligence. Nature 620, 47–60 (2023). https://doi.org/10.1038/s41586-023-06221-2
Speaker: Prof. Kohei Inayoshi INAYOSHI
Affiliation: Peking University
Date: March 18, 2026 (Wed)
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Speaker: Prof. Farhad ZADEH
Affiliation: Northwestern University
Date: April 1, 2026 (Wed)
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Date: April 15, 2026 (Wed)
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Date: April 29, 2026 (Wed)
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