SuperCDMS status from Soudan and plans for SNOLab | Zendy

J. Sander | Zendy; Zeeshan Ahmed | Zendy; A. J. Anderson | Zendy; S. Arrenberg | Zendy; D. Balakishiyeva | Zendy; R. Basu Thakur | Zendy; D. Bauer | Zendy; D. Brandt | Zendy; P. L. Brink | Zendy; R. Bunker | Zendy; B. Cabrera | Zendy; D. O. Caldwell | Zendy; D. G. Cerdeño | Zendy; H. Chagani | Zendy; J. Cooley | Zendy; Bruce Cornell | Zendy; C. H. Crewdson | Zendy; P. Cushman | Zendy; M. Daal | Zendy; P. C. F. Di Stefano | Zendy; E. Do Couto E Silva | Zendy; T. Doughty | Zendy; Luis Esteban | Zendy; S. Fallows | Zendy; E. FigueroaFeliciano | Zendy; J. Fox | Zendy; M. Fritts | Zendy; G. L. Godfrey | Zendy; S. R. Golwala | Zendy; J. Hall | Zendy; J. Hasi | Zendy; S. A. Hertel | Zendy; T. Höfer | Zendy; D. Holmgren | Zendy; L. Hsu | Zendy; M. E. Huber | Zendy; A. Jastram | Zendy; O. Kamaev | Zendy; Burhan Kara | Zendy; M. H. Kelsey | Zendy; P. Kim | Zendy; M. Kiveni | Zendy; K. Koch | Zendy; M. Kos | Zendy; S. W. Leman | Zendy; S. Liu | Zendy; B. Loer | Zendy; R. Mahapatra | Zendy; V. Mandic | Zendy; C. Moreno Martinez | Zendy; K. A. McCarthy | Zendy; N. Mirabolfathi | Zendy; R. Moffat | Zendy; D. Moore | Zendy; Philippe Nadeau | Zendy; R. Nelson | Zendy; K. Page | Zendy; R. Partridge | Zendy; M. Pepin | Zendy; A. Phipps | Zendy; K. Prasad | Zendy; M. Pyle | Zendy; H. Qiu | Zendy; Xiaoxue Qiu | Zendy; Roxanne Radpour | Zendy; W. Rau | Zendy; A. Reisetter | Zendy; R. Resch | Zendy; Y. Ricci | Zendy; T. Saab | Zendy; B. Sadoulet | Zendy; R. W. Schnee | Zendy; S. Scorza | Zendy; B. Serfass | Zendy; B. Shank | Zendy; K. Shneck | Zendy; D. Speller | Zendy; K. M. Sundqvist | Zendy; A. N. Villano | Zendy; B. Welliver | Zendy; S. Yellin | Zendy; J. J. Yen | Zendy; Jaiyul Yoo | Zendy; Betty Young | Zendy; J. Zhang | Zendy

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SuperCDMS status from Soudan and plans for SNOLab

Author(s) -

J. Sander,

Zeeshan Ahmed,

A. J. Anderson,

S. Arrenberg,

D. Balakishiyeva,

R. Basu Thakur,

D. Bauer,

D. Brandt,

P. L. Brink,

R. Bunker,

B. Cabrera,

D. O. Caldwell,

D. G. Cerdeño,

H. Chagani,

J. Cooley,

Bruce Cornell,

C. H. Crewdson,

P. Cushman,

M. Daal,

P. C. F. Di Stefano,

E. Do Couto E Silva,

T. Doughty,

Luis Esteban,

S. Fallows,

E. FigueroaFeliciano,

J. Fox,

M. Fritts,

G. L. Godfrey,

S. R. Golwala,

J. Hall,

J. Hasi,

S. A. Hertel,

T. Höfer,

D. Holmgren,

L. Hsu,

M. E. Huber,

A. Jastram,

O. Kamaev,

Burhan Kara,

M. H. Kelsey,

P. Kim,

M. Kiveni,

K. Koch,

M. Kos,

S. W. Leman,

S. Liu,

B. Loer,

R. Mahapatra,

V. Mandic,

C. Moreno Martinez,

K. A. McCarthy,

N. Mirabolfathi,

R. Moffat,

D. Moore,

Philippe Nadeau,

R. Nelson,

K. Page,

R. Partridge,

M. Pepin,

A. Phipps,

K. Prasad,

M. Pyle,

H. Qiu,

Xiaoxue Qiu,

Roxanne Radpour,

W. Rau,

A. Reisetter,

R. Resch,

Y. Ricci,

T. Saab,

B. Sadoulet,

R. W. Schnee,

S. Scorza,

B. Serfass,

B. Shank,

K. Shneck,

D. Speller,

K. M. Sundqvist,

A. N. Villano,

B. Welliver,

S. Yellin,

J. J. Yen,

Jaiyul Yoo,

Betty Young,

J. Zhang

Publication year - 2013

Publication title -

aip conference proceedings

Language(s) - English

Resource type - Conference proceedings

SCImago Journal Rank - 0.177

H-Index - 75

eISSN - 1551-7616

pISSN - 0094-243X

DOI - 10.1063/1.4807350

Subject(s) - wimp , physics , dark matter , weakly interacting massive particles , universe , massive particle , particle physics , galaxy , astroparticle physics , astrophysics , astronomy , scalar field dark matter , cosmic ray , cosmology , dark energy

Matter, as we know it, makes up less than 5% of the Universe. Various astrophysical observations have confirmed that one quarter of the Universe and most of the matter content in the Universe is made up of Dark Matter. The nature of Dark Matter is yet to be discovered and is one of the biggest questions in Physics. Particle Physics combined with astrophysical measurements of the abundance gives rise to a Dark Matter candidate called Weakly Interacting Massive Particle (WIMP). The low density of WIMPs in the galaxies and the extremely weak nature of the interaction with ordinary matter make detection of the WIMP an extraordinarily challenging task, with abundant fakes from various radioactive and cosmogenic backgrounds with much stronger electromagnetic interaction. The extremely weak nature of the WIMP interaction dictates detectors that have extremely low naturally occurring radioactive background, a large active volume (mass) of sensitive detector material to maximize statistics, a highly efficient detector based rejection mechanism for the dominant electromagnetic background and sophisticated analysis techniques to reject any residual background. This paper describes the status of the SuperCDMS experiment

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