Vedika Khemani: Non-unitary dynamics via spacetime duality

Event Date:
2021-10-21T10:00:00
2021-10-21T11:00:00
Event Location:
https://ubc.zoom.us/j/66879995529?pwd=dHpQb25LSGVZK3ozY243em5tenRWQT09
Meeting ID: 668 7999 5529
Passcode: 113399
Speaker:
Prof. Vedika Khemani, Stanford University
Related Upcoming Events:
Intended Audience:
Graduate
Event Information:

Abstract: The addition of non-unitary ingredients to many-body quantum dynamics has led to a series of exciting developments in recent years, including new out-of-equilibrium entanglement phases and phase transitions enabled by quantum measurements. I will present recent work [1] in which we show that a duality transformation between space and time on one hand, and unitarity and non-unitarity on the other, can be used to realize non-unitary evolutions whose steady states exhibit a rich variety of behavior in the scaling of their entanglement with subsystem size — from logarithmic to extensive to fractal. These fractally entangled states add a qualitatively new entry to the families of many-body quantum states that have been studied as energy eigenstates or dynamical steady states, whose entropy almost always displays either area-law, volume-law or logarithmic scaling. The range of steady-state entanglement scalings for the non-unitary evolution are closely related to the question of entanglement growth in time under different kinds of unitary dynamics, from localized to chaotic. This connection is sharpened by an exact mapping to unitary evolution with edge decoherence, in which  information is irreversibly “radiated  away” from one edge of the system. Finally, I will discuss how these ideas could be experimentally realized with present-day or near-term quantum technologies, and how spacetime duality allows us to mitigate (or eliminate altogether) the overhead from “postselection” of random measurement outcomes [2].

[1] Matteo Ippoliti, Tibor Rakovszky, Vedika Khemani, arxiv:2103.06873
[2] Matteo Ippoliti, Vedika Khemani, PRL 126, 060501 (2021)

Bio: Vedika Khemani is an assistant professor of physics at Stanford University. After completing her Ph.D. at Princeton University in 2016, she did her postdoctoral work as a Junior Fellow at Harvard. She is a recipient of an Alfred P. Sloan Fellowship, a DOE Early Career Award, the William L. McMillan Award, an APS George E. Valley Jr. Prize, the Breakthrough New Horizons in Physics Prize and the Packard Fellowship in Science and Engineering.

Add to Calendar 2021-10-21T10:00:00 2021-10-21T11:00:00 Vedika Khemani: Non-unitary dynamics via spacetime duality Event Information: Abstract: The addition of non-unitary ingredients to many-body quantum dynamics has led to a series of exciting developments in recent years, including new out-of-equilibrium entanglement phases and phase transitions enabled by quantum measurements. I will present recent work [1] in which we show that a duality transformation between space and time on one hand, and unitarity and non-unitarity on the other, can be used to realize non-unitary evolutions whose steady states exhibit a rich variety of behavior in the scaling of their entanglement with subsystem size — from logarithmic to extensive to fractal. These fractally entangled states add a qualitatively new entry to the families of many-body quantum states that have been studied as energy eigenstates or dynamical steady states, whose entropy almost always displays either area-law, volume-law or logarithmic scaling. The range of steady-state entanglement scalings for the non-unitary evolution are closely related to the question of entanglement growth in time under different kinds of unitary dynamics, from localized to chaotic. This connection is sharpened by an exact mapping to unitary evolution with edge decoherence, in which  information is irreversibly “radiated  away” from one edge of the system. Finally, I will discuss how these ideas could be experimentally realized with present-day or near-term quantum technologies, and how spacetime duality allows us to mitigate (or eliminate altogether) the overhead from “postselection” of random measurement outcomes [2]. [1] Matteo Ippoliti, Tibor Rakovszky, Vedika Khemani, arxiv:2103.06873 [2] Matteo Ippoliti, Vedika Khemani, PRL 126, 060501 (2021) Bio: Vedika Khemani is an assistant professor of physics at Stanford University. After completing her Ph.D. at Princeton University in 2016, she did her postdoctoral work as a Junior Fellow at Harvard. She is a recipient of an Alfred P. Sloan Fellowship, a DOE Early Career Award, the William L. McMillan Award, an APS George E. Valley Jr. Prize, the Breakthrough New Horizons in Physics Prize and the Packard Fellowship in Science and Engineering. Event Location: https://ubc.zoom.us/j/66879995529?pwd=dHpQb25LSGVZK3ozY243em5tenRWQT09 Meeting ID: 668 7999 5529 Passcode: 113399