Saved in:
Bibliographic Details
Main Authors: McBride, Sterling E., Gentry, Cale M., Holland, Christopher, Bellew, Colby, Moore, Kaitlin R., Braun, Alan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.05254
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912018937675776
author McBride, Sterling E.
Gentry, Cale M.
Holland, Christopher
Bellew, Colby
Moore, Kaitlin R.
Braun, Alan
author_facet McBride, Sterling E.
Gentry, Cale M.
Holland, Christopher
Bellew, Colby
Moore, Kaitlin R.
Braun, Alan
contents Reliable integration of photonic integrated circuits (PICs) into quantum sensors has the potential to drastically reduce sensor size, ease manufacturing scalability, and improve performance in applications where the sensor is subject to high accelerations, vibrations, and temperature changes. In a traditional quantum sensor assembly, free-space optics are subject to pointing inaccuracies and temperature-dependent misalignment. Moreover, the use of epoxy or sealants for affixing either free-space optics or PICs within a sensor vacuum envelope leads to sensor vacuum degradation and is difficult to scale. In this paper, we describe the hermetic integration of a PIC with a vacuum envelope via anodic bonding. We demonstrate utility of this assembly with two proof-of-concept atom-interrogation experiments: (1) spectroscopy of a cold-atom sample using a grating-emitted probe; (2) spectroscopy of alkali atoms using an evanescent field from an exposed ridge waveguide. This work shows a key process step on a path to quantum sensor manufacturing scalability
format Preprint
id arxiv_https___arxiv_org_abs_2409_05254
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Demonstration of atom interrogation using photonic integrated circuits anodically bonded to ultra-high vacuum envelopes for epoxy-free scalable quantum sensors
McBride, Sterling E.
Gentry, Cale M.
Holland, Christopher
Bellew, Colby
Moore, Kaitlin R.
Braun, Alan
Quantum Physics
Applied Physics
Reliable integration of photonic integrated circuits (PICs) into quantum sensors has the potential to drastically reduce sensor size, ease manufacturing scalability, and improve performance in applications where the sensor is subject to high accelerations, vibrations, and temperature changes. In a traditional quantum sensor assembly, free-space optics are subject to pointing inaccuracies and temperature-dependent misalignment. Moreover, the use of epoxy or sealants for affixing either free-space optics or PICs within a sensor vacuum envelope leads to sensor vacuum degradation and is difficult to scale. In this paper, we describe the hermetic integration of a PIC with a vacuum envelope via anodic bonding. We demonstrate utility of this assembly with two proof-of-concept atom-interrogation experiments: (1) spectroscopy of a cold-atom sample using a grating-emitted probe; (2) spectroscopy of alkali atoms using an evanescent field from an exposed ridge waveguide. This work shows a key process step on a path to quantum sensor manufacturing scalability
title Demonstration of atom interrogation using photonic integrated circuits anodically bonded to ultra-high vacuum envelopes for epoxy-free scalable quantum sensors
topic Quantum Physics
Applied Physics
url https://arxiv.org/abs/2409.05254