Minimizing magnetic fields for precision experiments

I. Altarev; P. Fierlinger; T. Lins; M. G. Marino; B. Nießen; G. Petzoldt; M. Reisner; S. Stuiber; M. Sturm; J. Taggart Singh; B. Taubenheim; H. K. Rohrer; U. Schläpfer

doi:10.1063/1.4922671

Minimizing magnetic fields for precision experiments

I. Altarev, P. Fierlinger, T. Lins, M. G. Marino, B. Nießen, G. Petzoldt, M. Reisner, S. Stuiber, M. Sturm, J. Taggart Singh, B. Taubenheim, H. K. Rohrer, U. Schläpfer

Chair of Precision Measurements at Extreme Conditions

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

46 Scopus citations

Abstract

An increasing number of measurements in fundamental and applied physics rely on magnetically shielded environments with sub nano-Tesla residual magnetic fields. State of the art magnetically shielded rooms (MSRs) consist of up to seven layers of high permeability materials in combination with highly conductive shields. Proper magnetic equilibration is crucial to obtain such low magnetic fields with small gradients in any MSR. Here, we report on a scheme to magnetically equilibrate MSRs with a 10 times reduced duration of the magnetic equilibration sequence and a significantly lower magnetic field with improved homogeneity. For the search of the neutron's electric dipole moment, our finding corresponds to a 40% improvement of the statistical reach of the measurement. However, this versatile procedure can improve the performance of any MSR for any application.

Original language	English
Article number	233903
Journal	Journal of Applied Physics
Volume	117
Issue number	23
DOIs	https://doi.org/10.1063/1.4922671
State	Published - 21 Jun 2015

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abstract = "An increasing number of measurements in fundamental and applied physics rely on magnetically shielded environments with sub nano-Tesla residual magnetic fields. State of the art magnetically shielded rooms (MSRs) consist of up to seven layers of high permeability materials in combination with highly conductive shields. Proper magnetic equilibration is crucial to obtain such low magnetic fields with small gradients in any MSR. Here, we report on a scheme to magnetically equilibrate MSRs with a 10 times reduced duration of the magnetic equilibration sequence and a significantly lower magnetic field with improved homogeneity. For the search of the neutron's electric dipole moment, our finding corresponds to a 40% improvement of the statistical reach of the measurement. However, this versatile procedure can improve the performance of any MSR for any application.",

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AU - Altarev, I.

AU - Fierlinger, P.

AU - Lins, T.

AU - Marino, M. G.

AU - Nießen, B.

AU - Petzoldt, G.

AU - Reisner, M.

AU - Stuiber, S.

AU - Sturm, M.

AU - Taggart Singh, J.

AU - Taubenheim, B.

AU - Rohrer, H. K.

AU - Schläpfer, U.

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Minimizing magnetic fields for precision experiments

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