Colloquium-Chen-Ting Liao (JILA, University of Colorado Boulder & NIST STROBE, NSF Science & Technology Center) -Probing topological states of spin and light: hedgehogs, skyrmions, optical vortices, and beyond.

March 23, 2023

2:00PM - 3:00PM

1080 Physics Research Building

Add to Calendar 2023-03-23 14:00:00 2023-03-23 15:00:00 Colloquium-Chen-Ting Liao (JILA, University of Colorado Boulder & NIST STROBE, NSF Science & Technology Center) -Probing topological states of spin and light: hedgehogs, skyrmions, optical vortices, and beyond. Dr. Chen-Ting Liao JILA, University of Colorado Boulder & NIST STROBE, NSF Science & Technology Center Probing topological states of spin and light: hedgehogs, skyrmions, optical vortices, and beyond. Location: 1080 Physics Research Building, Smith Seminar Room Faculty Host: Louis DiMauro Abstract: Broken symmetries are ubiquitous in physics and are associated with ferromagnetism, nonreciprocal effects, optical activity, molecular chirality, and vortex beams of photons and electrons. In some cases, symmetry breaking also leads to the formation of various topological states, excitations, or defects of a continuous field. In the first part of the talk, I will show how we developed state-of-the-art x-ray nanoscale microscopic [1] and femtosecond time-resolved scattering methods to probe topological spin textures. Our new x-ray imaging method provides world-record 3D vector imaging at 10nm resolution [2]. We then used it to study emergent topological magnetic monopoles (i.e., magnetic hedgehogs) and magnetic skyrmion lattice. In the second part of the talk, I will introduce the topological states of light carrying orbital angular momentum (OAM). The OAM of light can be static, dynamic, or spatiotemporal. Static OAM of light has been known for three decades and has found numerous applications. On the contrary, ultrafast time-varying and spatiotemporal OAM of light are new properties discovered over the past few years [3, 4]. Lastly, the potential pathways to generate quantum x-rays will be introduced, which could serve as a new quantum sensing tool for probing quantum materials in the future. References: [1] Science Advances 5, eaax3009 (2019); [2] Nature Nanotechnology (2023), DOI: 10.1038/s41565-022-01311-0; [3] Science 364, eaaw9486 (2019); [4] Nature Photonics 15, 608 (2021). Bio: Dr. Chen-Ting Liao is a research scientist at JILA, a joint research institute at the University of Colorado Boulder and NIST (National Institute of Standards and Technology). He also serves as Assistant Director of Research and Knowledge Transfer of STROBE, the NSF Science and Technology Center on Real-Tim Functional Imaging. Originally from Taiwan, Dr. Liao received his B.S. degree in space science and MSc in physics. After working in the semiconductor industry for two years, he came to the US to study optics. He received his PhD in optical sciences from the University of Arizona in 2017. Dr. Liao became a postdoc in JILA, working on ultrafast lasers, x-rays, and their application to probe materials. He is the Finalist of two PhD thesis awards, including the 2018 WAGS-ProQuest Innovation in Technology Award and the 2019 American Physical Society (APS) Carl E. Anderson Division of Laser Science Dissertation Award. Also, he is selected as the 2022-2023 APS Career Mentoring Fellow. Recently, Dr. Liao received the 2023 Air Force Young Investigator Award (AFOSR YIP) to explore potential pathways to generate quantum x-rays. 1080 Physics Research Building OSU ASC Drupal 8 ascwebservices@osu.edu America/New_York public

Add to Calendar 2023-03-23 14:00:00 2023-03-23 15:00:00 Colloquium-Chen-Ting Liao (JILA, University of Colorado Boulder & NIST STROBE, NSF Science & Technology Center) -Probing topological states of spin and light: hedgehogs, skyrmions, optical vortices, and beyond. Dr. Chen-Ting Liao JILA, University of Colorado Boulder & NIST STROBE, NSF Science & Technology Center Probing topological states of spin and light: hedgehogs, skyrmions, optical vortices, and beyond. Location: 1080 Physics Research Building, Smith Seminar Room Faculty Host: Louis DiMauro Abstract:  Broken symmetries are ubiquitous in physics and are associated with ferromagnetism, nonreciprocal effects, optical activity, molecular chirality, and vortex beams of photons and electrons. In some cases, symmetry breaking also leads to the formation of various topological states, excitations, or defects of a continuous field. In the first part of the talk, I will show how we developed state-of-the-art x-ray nanoscale microscopic [1] and femtosecond time-resolved scattering methods to probe topological spin textures. Our new x-ray imaging method provides world-record 3D vector imaging at 10nm resolution [2]. We then used it to study emergent topological magnetic monopoles (i.e., magnetic hedgehogs) and magnetic skyrmion lattice. In the second part of the talk, I will introduce the topological states of light carrying orbital angular momentum (OAM). The OAM of light can be static, dynamic, or spatiotemporal. Static OAM of light has been known for three decades and has found numerous applications. On the contrary, ultrafast time-varying and spatiotemporal OAM of light are new properties discovered over the past few years [3, 4]. Lastly, the potential pathways to generate quantum x-rays will be introduced, which could serve as a new quantum sensing tool for probing quantum materials in the future. References: [1] Science Advances 5, eaax3009 (2019); [2] Nature Nanotechnology (2023), DOI: 10.1038/s41565-022-01311-0; [3] Science 364, eaaw9486 (2019); [4] Nature Photonics 15, 608 (2021). Bio: Dr. Chen-Ting Liao is a research scientist at JILA, a joint research institute at the University of Colorado Boulder and NIST (National Institute of Standards and Technology). He also serves as Assistant Director of Research and Knowledge Transfer of STROBE, the NSF Science and Technology Center on Real-Tim Functional Imaging. Originally from Taiwan, Dr. Liao received his B.S. degree in space science and MSc in physics. After working in the semiconductor industry for two years, he came to the US to study optics. He received his PhD in optical sciences from the University of Arizona in 2017. Dr. Liao became a postdoc in JILA, working on ultrafast lasers, x-rays, and their application to probe materials. He is the Finalist of two PhD thesis awards, including the 2018 WAGS-ProQuest Innovation in Technology Award and the 2019 American Physical Society (APS) Carl E. Anderson Division of Laser Science Dissertation Award. Also, he is selected as the 2022-2023 APS Career Mentoring Fellow. Recently, Dr. Liao received the 2023 Air Force Young Investigator Award (AFOSR YIP) to explore potential pathways to generate quantum x-rays.     1080 Physics Research Building Department of Physics physics@osu.edu America/New_York public

Dr. Chen-Ting Liao

JILA, University of Colorado Boulder & NIST STROBE, NSF Science & Technology Center

Probing topological states of spin and light: hedgehogs, skyrmions, optical vortices, and beyond.

Location: 1080 Physics Research Building, Smith Seminar Room

Faculty Host: Louis DiMauro

Abstract:

Broken symmetries are ubiquitous in physics and are associated with ferromagnetism, nonreciprocal effects, optical activity, molecular chirality, and vortex beams of photons and electrons. In some cases, symmetry breaking also leads to the formation of various topological states, excitations, or defects of a continuous field. In the first part of the talk, I will show how we developed state-of-the-art x-ray nanoscale microscopic [1] and femtosecond time-resolved scattering methods to probe topological spin textures. Our new x-ray imaging method provides world-record 3D vector imaging at 10nm resolution [2]. We then used it to study emergent topological magnetic monopoles (i.e., magnetic hedgehogs) and magnetic skyrmion lattice. In the second part of the talk, I will introduce the topological states of light carrying orbital angular momentum (OAM). The OAM of light can be static, dynamic, or spatiotemporal. Static OAM of light has been known for three decades and has found numerous applications. On the contrary, ultrafast time-varying and spatiotemporal OAM of light are new properties discovered over the past few years [3, 4]. Lastly, the potential pathways to generate quantum x-rays will be introduced, which could serve as a new quantum sensing tool for probing quantum materials in the future.

References: [1] Science Advances 5, eaax3009 (2019); [2] Nature Nanotechnology (2023), DOI: 10.1038/s41565-022-01311-0; [3] Science 364, eaaw9486 (2019); [4] Nature Photonics 15, 608 (2021).

Bio: Dr. Chen-Ting Liao is a research scientist at JILA, a joint research institute at the University of Colorado Boulder and NIST (National Institute of Standards and Technology). He also serves as Assistant Director of Research and Knowledge Transfer of STROBE, the NSF Science and Technology Center on Real-Tim Functional Imaging. Originally from Taiwan, Dr. Liao received his B.S. degree in space science and MSc in physics. After working in the semiconductor industry for two years, he came to the US to study optics. He received his PhD in optical sciences from the University of Arizona in 2017. Dr. Liao became a postdoc in JILA, working on ultrafast lasers, x-rays, and their application to probe materials. He is the Finalist of two PhD thesis awards, including the 2018 WAGS-ProQuest Innovation in Technology Award and the 2019 American Physical Society (APS) Carl E. Anderson Division of Laser Science Dissertation Award. Also, he is selected as the 2022-2023 APS Career Mentoring Fellow. Recently, Dr. Liao received the 2023 Air Force Young Investigator Award (AFOSR YIP) to explore potential pathways to generate quantum x-rays.