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Autori principali: Pultinevicius, Einius, Rockenhäuser, Marian, Kogel, Felix, Groß, Phillip, Garg, Tatsam, Prochnow, Ole Einar, Langen, Tim
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2307.10217
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author Pultinevicius, Einius
Rockenhäuser, Marian
Kogel, Felix
Groß, Phillip
Garg, Tatsam
Prochnow, Ole Einar
Langen, Tim
author_facet Pultinevicius, Einius
Rockenhäuser, Marian
Kogel, Felix
Groß, Phillip
Garg, Tatsam
Prochnow, Ole Einar
Langen, Tim
contents Many experiments in atomic and molecular physics require simultaneous frequency stabilization of multiple lasers. We present a stabilization scheme based on a scanning transfer cavity lock that is simple, stable and easily scalable to many lasers at minimal cost. The scheme is based on the Red Pitaya STEMlab platform, with custom software developed and implemented to achieve up to 100 Hz bandwidth. As an example demonstration, we realize simultaneous stabilization of up to four lasers and a reduction of long-term drifts to well below 1 MHz per hour. This meets typical requirements, e.g. for experiments on laser cooling of molecules.
format Preprint
id arxiv_https___arxiv_org_abs_2307_10217
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A scalable scanning transfer cavity laser stabilization scheme based on the Red Pitaya STEMlab platform
Pultinevicius, Einius
Rockenhäuser, Marian
Kogel, Felix
Groß, Phillip
Garg, Tatsam
Prochnow, Ole Einar
Langen, Tim
Atomic Physics
Instrumentation and Detectors
Many experiments in atomic and molecular physics require simultaneous frequency stabilization of multiple lasers. We present a stabilization scheme based on a scanning transfer cavity lock that is simple, stable and easily scalable to many lasers at minimal cost. The scheme is based on the Red Pitaya STEMlab platform, with custom software developed and implemented to achieve up to 100 Hz bandwidth. As an example demonstration, we realize simultaneous stabilization of up to four lasers and a reduction of long-term drifts to well below 1 MHz per hour. This meets typical requirements, e.g. for experiments on laser cooling of molecules.
title A scalable scanning transfer cavity laser stabilization scheme based on the Red Pitaya STEMlab platform
topic Atomic Physics
Instrumentation and Detectors
url https://arxiv.org/abs/2307.10217