Optomechanical measurement of photon spin angular momentum and optical torque in integrated photonic devices

Li He; Huan Li; Mo Li

doi:10.1126/sciadv.1600485

Optomechanical measurement of photon spin angular momentum and optical torque in integrated photonic devices

Li He, Huan Li, Mo Li

Electrical and Computer Engineering

Research output: Contribution to journal › Article › peer-review

29 Scopus citations

Abstract

Photons carry linear momentum and spin angular momentum when circularly or elliptically polarized. During light-matter interaction, transfer of linear momentum leads to optical forces, whereas transfer of angular momentum induces optical torque. Optical forces including radiation pressure and gradient forces have long been used in optical tweezers and laser cooling. In nanophotonic devices, optical forces can be significantly enhanced, leading to unprecedented optomechanical effects in both classical and quantum regimes. In contrast, to date, the angular momentum of light and the optical torque effect have only been used in optical tweezers but remain unexplored in integrated photonics. We demonstrate the measurement of the spin angular momentum of photons propagating in a birefringent waveguide and the use of optical torque to actuate rotational motion of an optomechanical device. We show that the sign and magnitude of the optical torque are determined by the photon polarization states that are synthesized on the chip. Our study reveals the mechanical effect of photon’s polarization degree of freedom and demonstrates its control in integrated photonic devices. Exploiting optical torque and optomechanical interaction with photon angular momentum can lead to torsional cavity optomechanics and optomechanical photon spin-orbit coupling, as well as applications such as optomechanical gyroscopes and torsional magnetometry.

Original language	English (US)
Article number	e1600485
Journal	Science Advances
Volume	2
Issue number	9
DOIs	https://doi.org/10.1126/sciadv.1600485
State	Published - Sep 2016

Bibliographical note

Funding Information:
We acknowledge the funding support provided by the Young Investigator Program of the Air Force Office of Scientific Research (award no. FA9550-12-1-0338). Parts of this work were carried out in the University of Minnesota Nanofabrication Center, which receives partial support from NSF through a National Nanotechnology Infrastructure Network program, and the Characterization Facility, which is a member of the NSF-funded Materials Research Facilities Network via a Materials Research Science and Engineering Centers program. H.L. acknowledges the support of the Doctoral Dissertation Fellowship provided by the Graduate School of the University of Minnesota

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© 2016 The Authors.

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title = "Optomechanical measurement of photon spin angular momentum and optical torque in integrated photonic devices",

abstract = "Photons carry linear momentum and spin angular momentum when circularly or elliptically polarized. During light-matter interaction, transfer of linear momentum leads to optical forces, whereas transfer of angular momentum induces optical torque. Optical forces including radiation pressure and gradient forces have long been used in optical tweezers and laser cooling. In nanophotonic devices, optical forces can be significantly enhanced, leading to unprecedented optomechanical effects in both classical and quantum regimes. In contrast, to date, the angular momentum of light and the optical torque effect have only been used in optical tweezers but remain unexplored in integrated photonics. We demonstrate the measurement of the spin angular momentum of photons propagating in a birefringent waveguide and the use of optical torque to actuate rotational motion of an optomechanical device. We show that the sign and magnitude of the optical torque are determined by the photon polarization states that are synthesized on the chip. Our study reveals the mechanical effect of photon{\textquoteright}s polarization degree of freedom and demonstrates its control in integrated photonic devices. Exploiting optical torque and optomechanical interaction with photon angular momentum can lead to torsional cavity optomechanics and optomechanical photon spin-orbit coupling, as well as applications such as optomechanical gyroscopes and torsional magnetometry.",

author = "Li He and Huan Li and Mo Li",

note = "Funding Information: We acknowledge the funding support provided by the Young Investigator Program of the Air Force Office of Scientific Research (award no. FA9550-12-1-0338). Parts of this work were carried out in the University of Minnesota Nanofabrication Center, which receives partial support from NSF through a National Nanotechnology Infrastructure Network program, and the Characterization Facility, which is a member of the NSF-funded Materials Research Facilities Network via a Materials Research Science and Engineering Centers program. H.L. acknowledges the support of the Doctoral Dissertation Fellowship provided by the Graduate School of the University of Minnesota Publisher Copyright: {\textcopyright} 2016 The Authors.",

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N2 - Photons carry linear momentum and spin angular momentum when circularly or elliptically polarized. During light-matter interaction, transfer of linear momentum leads to optical forces, whereas transfer of angular momentum induces optical torque. Optical forces including radiation pressure and gradient forces have long been used in optical tweezers and laser cooling. In nanophotonic devices, optical forces can be significantly enhanced, leading to unprecedented optomechanical effects in both classical and quantum regimes. In contrast, to date, the angular momentum of light and the optical torque effect have only been used in optical tweezers but remain unexplored in integrated photonics. We demonstrate the measurement of the spin angular momentum of photons propagating in a birefringent waveguide and the use of optical torque to actuate rotational motion of an optomechanical device. We show that the sign and magnitude of the optical torque are determined by the photon polarization states that are synthesized on the chip. Our study reveals the mechanical effect of photon’s polarization degree of freedom and demonstrates its control in integrated photonic devices. Exploiting optical torque and optomechanical interaction with photon angular momentum can lead to torsional cavity optomechanics and optomechanical photon spin-orbit coupling, as well as applications such as optomechanical gyroscopes and torsional magnetometry.

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Optomechanical measurement of photon spin angular momentum and optical torque in integrated photonic devices

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