Modified Sagnac interferometer for high-sensitivity magneto-optic measurements atcryogenic temperatures

TL;DR

This paper presents a modified Sagnac interferometer design capable of high-sensitivity magneto-optic Kerr effect measurements at cryogenic temperatures, using a zero-area loop and fiber optics to achieve low noise and stability.

Contribution

The authors introduce a zero-area Sagnac interferometer with fiber optics for cryogenic MOKE measurements, enabling absolute Kerr rotation detection without magnetic modulation.

Findings

Achieved shot-noise limited sensitivity of 1×10⁻⁷ rad/√Hz at 2K

Demonstrated stable measurements with minimal bias drift over time

Operated effectively at 1550 nm wavelength with low optical power

Abstract

We describe a geometry for a Sagnac interferometer with a zero-area Sagnac loop for measuring magneto-optic Kerr effect (MOKE) at cryogenic temperatures. The apparatus is capable of measuring absolute polar Kerr rotation at 1550 nm wavelength without any modulation of the magnetic state of the sample, and is intrinsically immune to reciprocal effects such as linear birefringence and thermal fluctuation. A single strand of polarization-maintaining (PM) fiber is fed into a liquid helium probe, eliminating the need for optical viewports. This configuration makes it possible to conduct MOKE measurements at much lower temperatures than before. With an optical power of only 10 $\mu$W, we demonstrate static Kerr measurements with a shot-noise limited sensitivity of $1\times 10^{-7}$ rad/$\sqrt{\rm Hz}$ from room temperature down to 2K. Typical bias drift was measured to be $3\times 10^{-7}$ rad/hour.