Magnetic Field Devices for Neutron Spin Transport and Manipulation in Precise Neutron Spin Rotation Mesurements

TL;DR

This paper details the design and implementation of magnetic field devices for precise neutron spin transport and manipulation, crucial for high-sensitivity neutron spin rotation measurements in fundamental physics experiments.

Contribution

It introduces novel input and output coil designs based on the magnetic scalar potential method for effective neutron spin control in NSR experiments.

Findings

Achieved neutron spin rotation sensitivity of 10^{-7} rad/m.

Developed self-contained coils minimizing fringe magnetic fields.

Enabled adiabatic and nonadiabatic spin transitions with high precision.

Abstract

The neutron spin is a critical degree of freedom for many precision measurements using low-energy neutrons. Fundamental symmetries and interactions can be studied using polarized neutrons. Parity-violation (PV) in the hadronic weak interaction and the search for exotic forces that depend on the relative spin and velocity, are two questions of fundamental physics that can be studied via the neutron spin rotations that arise from the interaction of polarized cold neutrons and unpolarized matter. The Neutron Spin Rotation (NSR) collaboration developed a neutron polarimeter, capable of determining neutron spin rotations of the order of $10^{-7}$ rad per meter of traversed material. This paper describes two key components of the NSR apparatus, responsible for the transport and manipulation of the spin of the neutrons before and after the target region, which is surrounded by magnetic shielding and where residual magnetic fields need to be below 100 \textmu G. These magnetic field devices, called input and output coils, provide the magnetic field for adiabatic transport of the neutron spin in the regions outside the magnetic shielding while producing a sharp nonadiabatic transition of the neutron spin when entering/exiting the low-magnetic-field region. In addition, the coils are self contained, forcing the return magnetic flux into a compact region of space to minimize fringe fields outside. The design of the input and output coil is based on the magnetic scalar potential method.