Colloquium- Tony Heinz (Stanford University)- Seeing Electrons in Two Dimensions using Light

Tony Heinz smiling with trees behind him

August 27, 2024

3:45PM - 4:45PM

1080 Physics Research Building

Add to Calendar 2024-08-27 14:45:00 2024-08-27 15:45:00 Colloquium- Tony Heinz (Stanford University)- Seeing Electrons in Two Dimensions using Light Professor Tony HeinzStanford UniversitySeeing Electrons in Two Dimensions using LightLocation: 1080 Physics Research BuildingFaculty Host: Lou DiMauro Abstract: Layered van-der-Waals crystals can be thinned down to produce stable two-dimensional monolayers. The first widely studied material in this class was graphene, a single layer of carbon atoms, with its semi-metallic character. Subsequently monolayers with insulating and semiconducting 2D materials have been identified, as have been materials with ferromagnetic, ferroelectric, and even superconducting properties. These monolayers can, moreover, be stacked in an arbitrary manner, thus allowing for the combination different classes of materials in precisely controlled heterostructures that exhibit new properties not present in the individual layers.In this lecture, we will describe the how light interacts with such 2D layers and how optical spectroscopy can be used to reveal the properties of electrons in 2D materials. In the 2D semiconductors, optically excited electrons and holes bind together as atom-like excitonic excited states. These states exhibit features that differ both from the excited states of isolated atoms and from excited states of three-dimensional crystals. The possibility to tune and modify the excited states by electric fields, strain, dielectric environment, and adjacent 2D materials will be discussed. Such studies provide fundamental understanding of physics in reduced dimensional systems and also reveal potential applications of 2D semiconductors in optoelectronics and quantum information science. Bio: Tony Heinz received a BS degree in Physics from Stanford University and a PhD degree, also in Physics, from UC Berkeley. He joined the IBM Research Division in Yorktown Heights, NY as a research staff member. In 1995, he became a professor of Physics and Electrical Engineering at Columbia University. He joined Stanford University as a Professor of Applied Physics, with a concurrent appointment at SLAC National Accelerator Laboratory as a Professor of Photon Science in 2015. He has served in various leadership positions, including as President of the Optical Society of America (Optica) and as the Associate Laboratory Director for Energy Sciences at SLAC. Heinz’s research on surfaces, interfaces, and 2D materials has exploited laser spectroscopic techniques to elucidate the fascinating properties of the world of reduced-dimensional systems. His research has been recognized by the Isakson and Schawlow Prizes of the APS, among other distinctions. 1080 Physics Research Building OSU ASC Drupal 8 ascwebservices@osu.edu America/New_York public

2024-08-27 15:45:00 2024-08-27 16:45:00 Colloquium- Tony Heinz (Stanford University)- Seeing Electrons in Two Dimensions using Light Professor Tony HeinzStanford UniversitySeeing Electrons in Two Dimensions using LightLocation: 1080 Physics Research BuildingFaculty Host: Lou DiMauro Abstract: Layered van-der-Waals crystals can be thinned down to produce stable two-dimensional monolayers. The first widely studied material in this class was graphene, a single layer of carbon atoms, with its semi-metallic character. Subsequently monolayers with insulating and semiconducting 2D materials have been identified, as have been materials with ferromagnetic, ferroelectric, and even superconducting properties. These monolayers can, moreover, be stacked in an arbitrary manner, thus allowing for the combination different classes of materials in precisely controlled heterostructures that exhibit new properties not present in the individual layers.In this lecture, we will describe the how light interacts with such 2D layers and how optical spectroscopy can be used to reveal the properties of electrons in 2D materials. In the 2D semiconductors, optically excited electrons and holes bind together as atom-like excitonic excited states. These states exhibit features that differ both from the excited states of isolated atoms and from excited states of three-dimensional crystals. The possibility to tune and modify the excited states by electric fields, strain, dielectric environment, and adjacent 2D materials will be discussed. Such studies provide fundamental understanding of physics in reduced dimensional systems and also reveal potential applications of 2D semiconductors in optoelectronics and quantum information science. Bio: Tony Heinz received a BS degree in Physics from Stanford University and a PhD degree, also in Physics, from UC Berkeley. He joined the IBM Research Division in Yorktown Heights, NY as a research staff member. In 1995, he became a professor of Physics and Electrical Engineering at Columbia University. He joined Stanford University as a Professor of Applied Physics, with a concurrent appointment at SLAC National Accelerator Laboratory as a Professor of Photon Science in 2015. He has served in various leadership positions, including as President of the Optical Society of America (Optica) and as the Associate Laboratory Director for Energy Sciences at SLAC. Heinz’s research on surfaces, interfaces, and 2D materials has exploited laser spectroscopic techniques to elucidate the fascinating properties of the world of reduced-dimensional systems. His research has been recognized by the Isakson and Schawlow Prizes of the APS, among other distinctions. 1080 Physics Research Building America/New_York public

Professor Tony Heinz

Stanford University

Seeing Electrons in Two Dimensions using Light

Location: 1080 Physics Research Building

Faculty Host: Lou DiMauro

Abstract: Layered van-der-Waals crystals can be thinned down to produce stable two-dimensional monolayers. The first widely studied material in this class was graphene, a single layer of carbon atoms, with its semi-metallic character. Subsequently monolayers with insulating and semiconducting 2D materials have been identified, as have been materials with ferromagnetic, ferroelectric, and even superconducting properties. These monolayers can, moreover, be stacked in an arbitrary manner, thus allowing for the combination different classes of materials in precisely controlled heterostructures that exhibit new properties not present in the individual layers.

In this lecture, we will describe the how light interacts with such 2D layers and how optical spectroscopy can be used to reveal the properties of electrons in 2D materials. In the 2D semiconductors, optically excited electrons and holes bind together as atom-like excitonic excited states. These states exhibit features that differ both from the excited states of isolated atoms and from excited states of three-dimensional crystals. The possibility to tune and modify the excited states by electric fields, strain, dielectric environment, and adjacent 2D materials will be discussed. Such studies provide fundamental understanding of physics in reduced dimensional systems and also reveal potential applications of 2D semiconductors in optoelectronics and quantum information science.

Bio: Tony Heinz received a BS degree in Physics from Stanford University and a PhD degree, also in Physics, from UC Berkeley. He joined the IBM Research Division in Yorktown Heights, NY as a research staff member. In 1995, he became a professor of Physics and Electrical Engineering at Columbia University. He joined Stanford University as a Professor of Applied Physics, with a concurrent appointment at SLAC National Accelerator Laboratory as a Professor of Photon Science in 2015. He has served in various leadership positions, including as President of the Optical Society of America (Optica) and as the Associate Laboratory Director for Energy Sciences at SLAC. Heinz’s research on surfaces, interfaces, and 2D materials has exploited laser spectroscopic techniques to elucidate the fascinating properties of the world of reduced-dimensional systems. His research has been recognized by the Isakson and Schawlow Prizes of the APS, among other distinctions.