Imaging of dynamic magnetic fields with spin-polarized neutron beams

Tremsin, A. S.; Kardjilov, N.; Strobl, Markus; Manke, I.; Dawson, M.; McPhate, J. B.; Vallerga, J. V.; Siegmund, O. H. W.; Feller, W. B.

Imaging of dynamic magnetic fields with spin-polarized neutron beams

Mark

Tremsin, A. S. ; Kardjilov, N. ; Strobl, Markus ^LU ; Manke, I. ; Dawson, M. ; McPhate, J. B. ; Vallerga, J. V. ; Siegmund, O. H. W. and Feller, W. B. (2015) In New Journal of Physics 17.

Abstract: Precession of neutron spin in a magnetic field can be used for mapping of a magnetic field distribution, as demonstrated previously for static magnetic fields at neutron beamline facilities. The fringing in the observed neutron images depends on both the magnetic field strength and the neutron energy. In this paper we demonstrate the feasibility of imaging periodic dynamic magnetic fields using a spin-polarized cold neutron beam. Our position-sensitive neutron counting detector, providing with high precision both the arrival time and position for each detected neutron, enables simultaneous imaging of multiple phases of a periodic dynamic process with microsecond timing resolution. The magnetic fields produced by 5- and 15-loop solenoid... (More); Precession of neutron spin in a magnetic field can be used for mapping of a magnetic field distribution, as demonstrated previously for static magnetic fields at neutron beamline facilities. The fringing in the observed neutron images depends on both the magnetic field strength and the neutron energy. In this paper we demonstrate the feasibility of imaging periodic dynamic magnetic fields using a spin-polarized cold neutron beam. Our position-sensitive neutron counting detector, providing with high precision both the arrival time and position for each detected neutron, enables simultaneous imaging of multiple phases of a periodic dynamic process with microsecond timing resolution. The magnetic fields produced by 5- and 15-loop solenoid coils of 1 cm diameter, are imaged in our experiments with similar to 100 mu m resolution for both dc and 3 kHz ac currents. Our measurements agree well with theoretical predictions of fringe patterns formed by neutron spin precession. We also discuss the wavelength dependence and magnetic field quantification options using a pulsed neutron beamline. The ability to remotely map dynamic magnetic fields combined with the unique capability of neutrons to penetrate various materials (e.g., metals), enables studies of fast periodically changing magnetic processes, such as formation of magnetic domains within metals due to the presence of ac magnetic fields. (Less)

Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/7438995

author

Tremsin, A. S. ; Kardjilov, N. ; Strobl, Markus ^LU ; Manke, I. ; Dawson, M. ; McPhate, J. B. ; Vallerga, J. V. ; Siegmund, O. H. W. and Feller, W. B.

organization

European Spallation Source ESS AB

publishing date

2015

type

Contribution to journal

publication status

published

subject

Accelerator Physics and Instrumentation

keywords

neutron imaging, magnetic fields, non-destructive testing

in

New Journal of Physics

volume

17

article number

043047

publisher

IOP Publishing

external identifiers

wos:000353940300005
scopus:84930645993

ISSN

1367-2630

DOI

10.1088/1367-2630/17/4/043047

language

English

LU publication?

yes

id

4f4543f9-4ba2-4666-bdba-ff5c269697aa (old id 7438995)

date added to LUP

2016-04-01 13:02:22

date last changed

2022-03-29 05:12:04

@article{4f4543f9-4ba2-4666-bdba-ff5c269697aa,
  abstract     = {{Precession of neutron spin in a magnetic field can be used for mapping of a magnetic field distribution, as demonstrated previously for static magnetic fields at neutron beamline facilities. The fringing in the observed neutron images depends on both the magnetic field strength and the neutron energy. In this paper we demonstrate the feasibility of imaging periodic dynamic magnetic fields using a spin-polarized cold neutron beam. Our position-sensitive neutron counting detector, providing with high precision both the arrival time and position for each detected neutron, enables simultaneous imaging of multiple phases of a periodic dynamic process with microsecond timing resolution. The magnetic fields produced by 5- and 15-loop solenoid coils of 1 cm diameter, are imaged in our experiments with similar to 100 mu m resolution for both dc and 3 kHz ac currents. Our measurements agree well with theoretical predictions of fringe patterns formed by neutron spin precession. We also discuss the wavelength dependence and magnetic field quantification options using a pulsed neutron beamline. The ability to remotely map dynamic magnetic fields combined with the unique capability of neutrons to penetrate various materials (e.g., metals), enables studies of fast periodically changing magnetic processes, such as formation of magnetic domains within metals due to the presence of ac magnetic fields.}},
  author       = {{Tremsin, A. S. and Kardjilov, N. and Strobl, Markus and Manke, I. and Dawson, M. and McPhate, J. B. and Vallerga, J. V. and Siegmund, O. H. W. and Feller, W. B.}},
  issn         = {{1367-2630}},
  keywords     = {{neutron imaging; magnetic fields; non-destructive testing}},
  language     = {{eng}},
  publisher    = {{IOP Publishing}},
  series       = {{New Journal of Physics}},
  title        = {{Imaging of dynamic magnetic fields with spin-polarized neutron beams}},
  url          = {{http://dx.doi.org/10.1088/1367-2630/17/4/043047}},
  doi          = {{10.1088/1367-2630/17/4/043047}},
  volume       = {{17}},
  year         = {{2015}},
}

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Imaging of dynamic magnetic fields with spin-polarized neutron beams