Jonathan Kohler
University of California, Berkeley
9 Papers
42 Citations
Jonathan Kohler is an academic researcher from University of California, Berkeley. The author has contributed to research in topics: Quantum limit & Optical cavity. The author has an hindex of 5, co-authored 9 publications.
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Papers
Complex Squeezing and Force Measurement Beyond the Standard Quantum Limit.
L. F. Buchmann,L. F. Buchmann,Sydney Schreppler,Jonathan Kohler,Nicolas Spethmann,Nicolas Spethmann,Dan Stamper-Kurn,Dan Stamper-Kurn +7 more
TL;DR: In this paper, it was shown that complex squeezing is a component of ponderomotive squeezing of light through cavity optomechanics and proposed a detection scheme called synodyne detection, which reveals complex squeezing and allows the accounting of measurement backaction.
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Simultaneous retrodiction of multimode optomechanical systems using matched filters
TL;DR: In this article, the authors analyze and demonstrate state retrodiction for a system of optomechanical oscillators coupled to a single-mode optical cavity, which can be defined as a set of linear matched filters, derived from a detailed model for the detected homodyne signal.
9
Optodynamical Measurement and Coupling of Atomic Motion and Spin
Jonathan Kohler
- 01 Jan 2018
TL;DR: Kohler et al. as discussed by the authors presented experimental results and theoretical models for continuous measurement and control of the center of mass motion and collective spin precession of an atomic ensemble, mediated by coupling to a high-finesse optical cavity.
4
•Journal Article
Complex squeezing for force measurement beyond the standard quantum limit
TL;DR: It is found theoretically that complex squeezing is a component of ponderomotive squeezing of light through cavity optomechanics and proposed a detection scheme called synodyne detection, which reveals complex squeezing and allows the accounting of measurement backaction.
•Posted Content
Tracking evaporative cooling of a mesoscopic atomic quantum gas in real time.
TL;DR: In this article, the time evolution of the atom number in a quasi-two-dimensional atomic gas during evaporation from a tilted trapping potential is tracked using an optical cavity.