A. Borgland
Fermilab
2 Papers
A. Borgland is an academic researcher from Fermilab. The author has contributed to research in topics: Weakly interacting massive particles & Dark matter. The author has an hindex of 2, co-authored 2 publications.
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Papers
New Results from the Search for Low-Mass Weakly Interacting Massive Particles with the CDMS Low Ionization Threshold Experiment
R. Agnese,Adam Anderson,Tsuguo Aramaki,M. Asai,W. Baker,D. Balakishiyeva,D. Barker,R. Basu Thakur,D. A. Bauer,J. Billard,A. Borgland,M. A. Bowles,P. L. Brink,R. Bunker,Blas Cabrera,David O. Caldwell,R. Calkins,David G. Cerdeño,H. Chagani,Yi Chen,Jodi Cooley,B. Cornell,P. Cushman,Miguel Daal,P. Di Stefano,T. Doughty,L. Esteban,S. Fallows,Enectali Figueroa-Feliciano,M. Ghaith,G. L. Godfrey,Sunil Golwala,J. Hall,H. R. Harris,T. Hofer,Donald J. Holmgren,L. Hsu,Martin E. Huber,D. Jardin,A. Jastram,O. Kamaev,B. Kara,M. H. Kelsey,A. Kennedy,A. Leder,B. Loer,E. Lopez Asamar,P. Lukens,R. Mahapatra,Vuk Mandic,N. Mast,N. Mirabolfathi,Robert A. Moffatt,J. D. Morales Mendoza,S. M. Oser,K. L. Page,W. A. Page,R. Partridge,M. Pepin,A. Phipps,K. Prasad,Matt Pyle,H. Qiu,W. Rau,P. Redl,A. Reisetter,Y. Ricci,Amy Roberts,H. E. Rogers,Tarek Saab,Bernard Sadoulet,J. Sander,K. Schneck,R. W. Schnee,S. Scorza,B. Serfass,B. Shank,Danielle Speller,D. Toback,R. Underwood,S. Upadhyayula,A. N. Villano,B. Welliver,John Wilson,D. H. Wright,S. J. Yellin,J. J. Yen,Betty A. Young,J. Zhang +88 more
TL;DR: The CDMS low ionization threshold experiment (CDMSlite) uses cryogenic germanium detectors operated at a relatively high bias voltage to amplify the phonon signal in the search for weakly interacting massive particles (WIMPs).
Dark matter effective field theory scattering in direct detection experiments
K. Schneck,Blas Cabrera,David G. Cerdeño,Vuk Mandic,H. E. Rogers,R. Agnese,Adam Anderson,M. Asai,D. Balakishiyeva,D. Barker,R. Basu Thakur,D. A. Bauer,J. Billard,A. Borgland,D. Brandt,P. L. Brink,R. Bunker,D. O. Caldwell,R. Calkins,H. Chagani,Yan Chen,Jodi Cooley,B. Cornell,C. H. Crewdson,P. Cushman,Miguel Daal,P. Di Stefano,T. Doughty,L. Esteban,S. Fallows,Enectali Figueroa-Feliciano,G. L. Godfrey,Sunil Golwala,J. Hall,H. R. Harris,T. Hofer,Donald J. Holmgren,L. Hsu,Martin E. Huber,D. Jardin,A. Jastram,O. Kamaev,B. Kara,M. H. Kelsey,A. Kennedy,A. Leder,B. Loer,E. Lopez Asamar,P. Lukens,R. Mahapatra,Kevin A. McCarthy,N. Mirabolfathi,Robert A. Moffatt,J. D. Morales Mendoza,S. M. Oser,K. L. Page,W. A. Page,R. Partridge,M. Pepin,A. Phipps,K. Prasad,Matt Pyle,H. Qiu,W. Rau,P. Redl,A. Reisetter,Y. Ricci,Amy Roberts,Tarek Saab,Bernard Sadoulet,J. Sander,R. W. Schnee,S. Scorza,B. Serfass,B. Shank,Danielle Speller,D. Toback,S. Upadhyayula,A. N. Villano,B. Welliver,John Wilson,D. H. Wright,X. Yang,S. J. Yellin,J. J. Yen,Betty A. Young,J. Zhang +86 more
TL;DR: In this article, the authors examined the consequences of the effective field theory (EFT) of dark matter-nucleon scattering for current and proposed direct detection experiments and showed that spectral differences between the standard dark matter model and a general EFT interaction can produce bias when calculating exclusion limits and when developing signal models for likelihood and machine learning techniques.