# A project of advanced solid-state neutron polarizer for PF1B instrument   at ILL

**Authors:** A.K. Petukhov, V.V. Nesvizhevsky, T. Bigault, P. Courtois, D. Jullien, and T. Soldner

arXiv: 1906.04690 · 2019-10-02

## TL;DR

This paper presents a novel solid-state neutron polarizer using sapphire substrates with optimized geometry and magnetic field, achieving record polarization levels for the PF1B instrument at ILL.

## Contribution

It introduces the use of sapphire substrates and V-bender geometry to enhance solid-state neutron polarizer performance, with experimental validation of record polarization levels.

## Key findings

- Record polarization >0.999 achieved in 0.3-1.2 nm wavelength range.
- Optimal magnetic field strength of 300 mT is crucial for best performance.
- Sapphire substrates with V-bender geometry outperform traditional designs.

## Abstract

Among Super-Mirror (SM) polarizers, solid-state devices have many advantages. The most relevant is 5-10 times smaller length compared to air-gap polarizers allowing to apply stronger magnetic fields. An important condition for a good SM polarizer is the matching of the substrate SLD (Scattering Length Density) with the SM coating SLD for spin-down neutrons. For traditional Fe/Si SM on Si substrate, this SLD step is positive when a neutron goes from the substrate to the SM, which leads to a significant loss of the polarizer performance at small Q. Instead, we use single-crystal Sapphire/Quartz substrates. The latter show a negative SLD step for spin-down neutrons at the interface with Fe and, therefore, avoid the total reflection regime at small Q. To optimize the polarizer performance, we formulate the concept of Sapphire V-bender, perform ray-tracing simulations of Sapphire V-bender, compare results with those for traditional C-bender on Si, and study experimentally V-bender prototypes with different substrates. Our results show that the choice of substrate material, polarizer geometry and the strength and quality of magnetizing field have dramatic effect. In particular, we compare the performance of polarizer for the applied magnetic field strength of $50 mT$ and $300 mT$. Only the large field strength provides an excellent agreement between the simulated and measured polarization values. For the double-collision configuration, a record polarization $>0.999$ was obtained in the neutron wavelength band of $0.3-1.2 nm$ with only $1\%$ decrease at $2 nm$. Without any collimation, the polarization averaged over the full outgoing capture spectrum, $0.997$, was found to be equal to the value obtained previously only using a double polarizer in the "crossed" (X-SM) geometry. These results are applied in a full-scale polarizer for the PF1B instrument.

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/1906.04690/full.md

## References

41 references — full list in the complete paper: https://tomesphere.com/paper/1906.04690/full.md

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Source: https://tomesphere.com/paper/1906.04690