Open AccessDesign and performance of a superconducting neutron resonance spin flipper
Author(s) -
Ryan Dadisman,
David C. Wasilko,
H. Kaiser,
Stephen J. Kuhn,
Zachary Buck,
Joseph Schaeperkoetter,
Lowell Crow,
Richard A. Riedel,
Lee Robertson,
Chenyang Jiang,
Tianhao Wang,
Nicolas Silva,
Yoon Kang,
SungWoo Lee,
Kunlun Hong,
Fankang Li
Publication year - 2020
Publication title -
review of scientific instruments
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.605
H-Index - 165
eISSN - 1089-7623
pISSN - 0034-6748
DOI - 10.1063/1.5124681
Subject(s) - neutron spin echo , physics , spin echo , neutron , spin (aerodynamics) , resonance (particle physics) , adiabatic process , nuclear magnetic resonance , nuclear physics , condensed matter physics , neutron scattering , atomic physics , inelastic neutron scattering , magnetic resonance imaging , medicine , radiology , thermodynamics
Despite the challenges, neutron resonance spin echo still holds the promise to improve upon neutron spin echo for the measurement of slow dynamics in materials. We present a bootstrap, radio frequency neutron spin flipper using high temperature superconducting technology capable of flipping neutron spin with either nonadiabatic or adiabatic modes. A frequency of 2 MHz has been achieved, which would achieve an effective field integral of 0.35 T m for a meter of separation in a neutron resonance spin echo spectrometer at the current device specifications. In bootstrap mode, the self-cancellation of Larmor phase aberrations can be achieved with the appropriate selection of the polarity of the gradient coils.
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