A high-flux atomic strontium oven with light-driven flux modulation

TL;DR

This paper introduces a micro-machined, high-flux strontium oven with light-driven flux modulation, enhancing atomic flux control and operational lifetime for cold atom quantum technologies.

Contribution

The paper presents a novel re-entrant oven design with laser-based flux modulation, enabling high atomic flux and improved longevity without vacuum feed-throughs.

Findings

Achieved a flux of 8×10^{14} atoms/s at 475°C

Laser illumination increased flux by up to 16 times

Demonstrated long-term stable operation over months

Abstract

A high-flux source of strontium atoms is required for cold atom quantum technology applications. We present a re-entrant oven design that avoids the need for any vacuum feed-throughs and has an inherent temperature gradient to guard against clogging of the nozzle. The nozzle is fabricated by micro-machining of fused silica using selective laser etching; this specialised technique is capable of making many thousands of fine microchannels and is suitable for batch production. Operating with only electrical heating, using <20W of electrical power, a total flux of $8(1)\times 10^{14}$ atoms/s is achieved at an oven temperature of 475{\deg}C, of which we estimate $1.8(2)\times 10^{13}$ atoms/s could be captured. A heated in-vacuum sapphire window grants optical access directly opposite the oven, and can be cleared of metallization without breaking vacuum. We used this optical access to modulate the flux of the atomic beam by direct illumination of the nozzle and the strontium metal with high-power laser light. Heating by laser light increased the useful flux by a factor of up to 16(3) on a timescale of 40s, and a factor of 2.5(5) on a timescale of 1s. This flux modulation serves to increase the operating lifetime of the oven. We report experimental measurements of the performance of the oven in long-term operation over many months.