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@inproceedings{stilin:ipac2021-mopab391,
author = {N.A. Stilin and A.T. Holic and M. Liepe and R.D. Porter and J. Sears and Z. Sun},
title = {{Conduction Cooling Methods for Nb₃Sn SRF Cavities and Cryomodules}},
booktitle = {Proc. IPAC'21},
pages = {1192--1195},
eid = {MOPAB391},
language = {english},
keywords = {cavity, SRF, controls, accelerating-gradient, simulation},
venue = {Campinas, SP, Brazil},
series = {International Particle Accelerator Conference},
number = {12},
publisher = {JACoW Publishing, Geneva, Switzerland},
month = {08},
year = {2021},
issn = {2673-5490},
isbn = {978-3-95450-214-1},
doi = {10.18429/JACoW-IPAC2021-MOPAB391},
url = {https://jacow.org/ipac2021/papers/mopab391.pdf},
note = {https://doi.org/10.18429/JACoW-IPAC2021-MOPAB391},
abstract = {{Rapid progress in the performance of Nb₃Sn SRF cavities during the last few years has made Nb₃Sn an energy efficient alternative to traditional Nb cavities, thereby initiating a fundamental shift in SRF technology. These Nb₃Sn cavities can operate at significantly higher temperatures than Nb cavities while simultaneously requiring less cooling power. This critical property enables the use of new, robust, turn-key style cryogenic cooling schemes based on conduction cooling with commercial cryocoolers. Cornell University has developed and tested a 2.6 GHz Nb₃Sn cavity assembly which utilizes such cooling methods. These tests have demonstrated stable RF operation at 10 MV/m and the measured thermal dynamics match what is found in numerical simulations.}},
}