Cryogenic and hermetically sealed packaging of photonic chips for optomechanics
Abstract
We demonstrate a hermetically sealed packaging system for integrated photonic devices at cryogenic temperatures with plug-and-play functionality. This approach provides the ability to encapsulate a controlled amount of gas into the optical package allowing helium to be used as a heat-exchange gas to thermalize photonic devices, or condensed into a superfluid covering the device. This packaging system was tested using a silicon-on-insulator slot waveguide resonator which fills with superfluid 4He below the transition temperature. To optimize the fiber-to-chip optical integration 690 tests were performed by thermally cycling optical fibers bonded to various common photonic chip substrates (silicon, silicon oxide and HSQ) with a range of glues (NOA 61, NOA 68, NOA 88, NOA 86H and superglue). This showed that NOA 86H (a UV curing optical adhesive with a latent heat catalyst) provided the best performance under cryogenic conditions for all the substrates tested. The technique is relevant to superfluid optomechanics experiments, as well as quantum photonics and quantum optomechanics applications.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Aug 08, 2022
- Source ID
- 10.1364/oe.463752
Entities
People
- A. Sawadsky
- Christopher Baker
- Glen I Harris
- Raymond A. Harrison
- W. P. Bowen
- Walter W. Wasserman
- Y. L. Sfendla
Organizations
- Army Research Office
- Australian Research Council
- University of Queensland