Electron beam characterization via quantum coherent optical magnetometry

Nicolas DeStefano; Saeed Pegahan; Aneesh Ramaswamy; Seth Aubin; T. Averett; Alexandre Camsonne; Svetlana Malinovskaya; Eugeniy E. Mikhailov; Gunn Park; Shukui Zhang; Irina Novikova

doi:10.1063/5.0234219

Electron beam characterization via quantum coherent optical magnetometry

Nicolas DeStefano, Saeed Pegahan, Aneesh Ramaswamy, Seth Aubin, T. Averett, Alexandre Camsonne, Svetlana Malinovskaya, Eugeniy E. Mikhailov, Gunn Park, Shukui Zhang, Irina Novikova

Department of Physics

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

Abstract

We present a quantum optics-based detection method for determining the position and current of an electron beam. As electrons pass through a dilute vapor of rubidium atoms, their magnetic field perturbs the atomic spin's quantum state and causes polarization rotation of a laser resonant with an optical transition of the atoms. By measuring the polarization rotation angle across the laser beam, we recreate a 2D projection of the magnetic field and use it to determine the e-beam position, size, and total current. We tested this method for an e-beam with currents ranging from 30 to 110 μ A. Our approach is insensitive to electron kinetic energy, and we confirmed that experimentally between 10 and 20 keV. This technique offers a unique platform for noninvasive characterization of charged particle beams used in accelerators for particle and nuclear physics research.

Original language	English
Article number	264001
Journal	Applied Physics Letters
Volume	125
Issue number	26
DOIs	https://doi.org/10.1063/5.0234219
State	Published - 23 Dec 2024

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10.1063/5.0234219

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title = "Electron beam characterization via quantum coherent optical magnetometry",

abstract = "We present a quantum optics-based detection method for determining the position and current of an electron beam. As electrons pass through a dilute vapor of rubidium atoms, their magnetic field perturbs the atomic spin's quantum state and causes polarization rotation of a laser resonant with an optical transition of the atoms. By measuring the polarization rotation angle across the laser beam, we recreate a 2D projection of the magnetic field and use it to determine the e-beam position, size, and total current. We tested this method for an e-beam with currents ranging from 30 to 110 μ A. Our approach is insensitive to electron kinetic energy, and we confirmed that experimentally between 10 and 20 keV. This technique offers a unique platform for noninvasive characterization of charged particle beams used in accelerators for particle and nuclear physics research.",

author = "Nicolas DeStefano and Saeed Pegahan and Aneesh Ramaswamy and Seth Aubin and T. Averett and Alexandre Camsonne and Svetlana Malinovskaya and Mikhailov, {Eugeniy E.} and Gunn Park and Shukui Zhang and Irina Novikova",

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TY - JOUR

T1 - Electron beam characterization via quantum coherent optical magnetometry

AU - DeStefano, Nicolas

AU - Pegahan, Saeed

AU - Ramaswamy, Aneesh

AU - Aubin, Seth

AU - Averett, T.

AU - Camsonne, Alexandre

AU - Malinovskaya, Svetlana

AU - Mikhailov, Eugeniy E.

AU - Park, Gunn

AU - Zhang, Shukui

AU - Novikova, Irina

PY - 2024/12/23

Y1 - 2024/12/23

N2 - We present a quantum optics-based detection method for determining the position and current of an electron beam. As electrons pass through a dilute vapor of rubidium atoms, their magnetic field perturbs the atomic spin's quantum state and causes polarization rotation of a laser resonant with an optical transition of the atoms. By measuring the polarization rotation angle across the laser beam, we recreate a 2D projection of the magnetic field and use it to determine the e-beam position, size, and total current. We tested this method for an e-beam with currents ranging from 30 to 110 μ A. Our approach is insensitive to electron kinetic energy, and we confirmed that experimentally between 10 and 20 keV. This technique offers a unique platform for noninvasive characterization of charged particle beams used in accelerators for particle and nuclear physics research.

AB - We present a quantum optics-based detection method for determining the position and current of an electron beam. As electrons pass through a dilute vapor of rubidium atoms, their magnetic field perturbs the atomic spin's quantum state and causes polarization rotation of a laser resonant with an optical transition of the atoms. By measuring the polarization rotation angle across the laser beam, we recreate a 2D projection of the magnetic field and use it to determine the e-beam position, size, and total current. We tested this method for an e-beam with currents ranging from 30 to 110 μ A. Our approach is insensitive to electron kinetic energy, and we confirmed that experimentally between 10 and 20 keV. This technique offers a unique platform for noninvasive characterization of charged particle beams used in accelerators for particle and nuclear physics research.

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DO - 10.1063/5.0234219

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VL - 125

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 26

M1 - 264001

ER -

Electron beam characterization via quantum coherent optical magnetometry

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