Dark matter effective field theory scattering in direct detection experiments

K. Schneck,B. Cabrera,D. G. Cerdeno,V. Mandic,H. E. Rogers,R. Agnese,A. J. Anderson,M. Asai,D. Balakishiyeva,D. Barker,R. Basu Thakur,D. A. Bauer,J. Billard,A. Borgland,D. Brandt,P. L. Brink,R. Bunker,David O. Caldwell,R. Calkins,H. Chagani,Yan Chen,J. Cooley,B. Cornell,C. H. Crewdson,P. Cushman,M. Daal,P. Di Stefano,T. Doughty,L. Esteban,S. Fallows,E. Figueroa-Feliciano,G. L. Godfrey,S. R. Golwala,J. Hall,H. R. Harris,T. Hofer,D. Holmgren,L. Hsu,M. 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,K. A. McCarthy,N. Mirabolfathi,R. A. Moffatt,J. D. Morales Mendoza,S. M. Oser,Kim L. Page,W. A. Page,R. Partridge,M. Pepin,A. Phipps,K. Prasad,M. Pyle,H. Qiu,W. Rau,P. Redl,A. Reisetter,Y. Ricci,A. Roberts,T. Saab,B. Sadoulet,J. Sander,R. W. Schnee,S. Scorza,B. Serfass,B. Shank,D. Speller,D. Toback,S. Upadhyayula,A. N. Villano,B. Welliver,J. S. Wilson,D. H. Wright,X. Yang,S. Yellin,J. J. Yen,B. A. Young,J Zhang

Dark matter effective field theory scattering in direct detection experiments

2015

K. Schneck
B. Cabrera
D. G. Cerdeno
V. Mandic
H. E. Rogers
R. Agnese
A. J. Anderson
M. Asai
D. Balakishiyeva
D. Barker
R. Basu Thakur
D. A. Bauer
J. Billard
A. Borgland
D. Brandt
P. L. Brink
R. Bunker
David O. Caldwell
R. Calkins
H. Chagani
Yan Chen
J. Cooley
B. Cornell
C. H. Crewdson
P. Cushman
M. Daal
P. Di Stefano
T. Doughty
L. Esteban
S. Fallows
E. Figueroa-Feliciano
G. L. Godfrey
S. R. Golwala
J. Hall
H. R. Harris
T. Hofer
D. Holmgren
L. Hsu
M. 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
K. A. McCarthy
N. Mirabolfathi
R. A. Moffatt
J. D. Morales Mendoza
S. M. Oser
Kim L. Page
W. A. Page
R. Partridge
M. Pepin
A. Phipps
K. Prasad
M. Pyle
H. Qiu
W. Rau
P. Redl
A. Reisetter
Y. Ricci
A. Roberts
T. Saab
B. Sadoulet
J. Sander
R. W. Schnee
S. Scorza
B. Serfass
B. Shank
D. Speller
D. Toback
S. Upadhyayula
A. N. Villano
B. Welliver
J. S. Wilson
D. H. Wright
X. Yang
S. Yellin
J. J. Yen
B. A. Young
J Zhang

We examine the consequences of the effective field theory (EFT) of dark matter–nucleon scattering for current and proposed direct detection experiments. Exclusion limits on EFT coupling constants computed using the optimum interval method are presented for SuperCDMS Soudan, CDMS II, and LUX, and the necessity of combining results from multiple experiments in order to determine dark matter parameters is discussed. We demonstrate that spectral differences between the standard dark matter model and a general EFT interaction can produce a bias when calculating exclusion limits and when developing signal models for likelihood and machine learning techniques. We also discuss the implications of the EFT for the next-generation (G2) direct detection experiments and point out regions of complementarity in the EFT parameter space.

Keywords:

Particle physics
Physics
Parameter space
Dark matter
Scalar field dark matter
Scattering
Weakly interacting massive particles
Coupling constant
Effective field theory
Quantum electrodynamics
interval method

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