Development of a high-field pulsed magnet and optical fiber coupled cryostat system for magneto-photoluminescence measurements

TL;DR

This paper details the development of a high-field pulsed magnet system integrated with an optical fiber cryostat for magneto-photoluminescence, achieving 35 Tesla fields and stable low temperatures for advanced optical measurements.

Contribution

It introduces a novel high-field pulsed magnet system with electrolyte capacitor banks and an integrated cryostat for magneto-optical experiments at low temperatures.

Findings

Achieved maximum magnetic field of 35 Tesla.

Enabled stable low-temperature environment down to 5 K.

Demonstrated system suitability for magneto-photoluminescence measurements.

Abstract

This paper presents the development of a high field pulsed magnet system combined with an optical fiber-coupled low temperature cryostat for magneto-photoluminescence measurements. A novel aspect of our system is the use of electrolyte capacitors in a 75 kJ capacitor bank to drive the pulsed magnet, enabling the generation of high magnetic fields at a relatively low charging voltage (400 V). The zylon reinforced wire wound magnet coil achieves a maximum field strength of 35 tesla with a magnetic field rise time of 10 ms. The integrated cryostat was developed to meet the specific requirements of magneto-photoluminescence experiments using a 4 K helium closed-cycle cryocooler to provide a stable low-temperature environment down to 5 K.