Effective field theory search for high-energy nuclear recoils using the XENON100 dark matter detector

E. Aprile,J. Aalbers,F. Agostini,M. Alfonsi,F. D. Amaro,M. Anthony,F. Arneodo,P. Barrow,L. Baudis,B. Bauermeister,M. L. Benabderrahmane,T. Berger,P. A. Breur,Abbe Brown,E. Brown,S. Bruenner,G. Bruno,R. Budnik,L. Buetikofer,J. Calven,J. M. R. Cardoso,M. Cervantes,D. Cichon,D. Coderre,A. P. Colijn,J. Conrad,J. P. Cussonneau,M. P. Decowski,P. de Perio,P. Di Gangi,A. Di Giovanni,S. Diglio,G. Eurin,J. Fei,A. D. Ferella,A. Fieguth,W. Fulgione,A. Gallo Rosso,A. Di Galloway,F. Gao,M. Garbini,C. Geis,L. W. Goetzke,Z. Greene,C. Grignon,C. Hasterok,E. Hogenbirk,R. Itay,B. Kaminsky,S. Kazama,G. Kessler,A. Kish,H. Landsman,R. F. Lang,D. Lellouch,L. J. Levinson,Q. Lin,S. Lindemann,Manfred Lindner,F. Lombardi,J. A. M. Lopes,A. Manfredini,I. C. Mariş,Teresa Marrodán Undagoitia,J. Masbou,F. V. Massoli,D. Masson,D. Mayani,M. Messina,K. Micheneau,A. Molinario,K. Morå,M. Murra,J. Naganoma,K. Ni,U. Oberlack,P. Pakarha,B. Pelssers,R. Persiani,F. Piastra,J. Pienaar,V. Pizzella,M. C. Piro,G. Plante,N. Priel,L. Rauch,S. Reichard,C. Reuter,A. Rizzo,S. Rosendahl,N. Rupp,J.M.F. dos Santos,G. Sartorelli,M. Scheibelhut,S. Schindler,J. Schreiner,M. Schumann,L. Scotto Lavina,M. Selvi,P. Shagin,M. Silva,H. Simgen,M. V. Sivers,A. Stein,D. Thers,A. Tiseni,G. Trinchero,C. Tunnell,M. Vargas,H Wang,Z. Wang,Y. Wei,C. Weinheimer,J. Wulf,J. Ye,Y. Zhang,B Farmer

Effective field theory search for high-energy nuclear recoils using the XENON100 dark matter detector

2017

E. Aprile
J. Aalbers
F. Agostini
M. Alfonsi
F. D. Amaro
M. Anthony
F. Arneodo
P. Barrow
L. Baudis
B. Bauermeister
M. L. Benabderrahmane
T. Berger
P. A. Breur
Abbe Brown
E. Brown
S. Bruenner
G. Bruno
R. Budnik
L. Buetikofer
J. Calven
J. M. R. Cardoso
M. Cervantes
D. Cichon
D. Coderre
A. P. Colijn
J. Conrad
J. P. Cussonneau
M. P. Decowski
P. de Perio
P. Di Gangi
A. Di Giovanni
S. Diglio
G. Eurin
J. Fei
A. D. Ferella
A. Fieguth
W. Fulgione
A. Gallo Rosso
A. Di Galloway
F. Gao
M. Garbini
C. Geis
L. W. Goetzke
Z. Greene
C. Grignon
C. Hasterok
E. Hogenbirk
R. Itay
B. Kaminsky
S. Kazama
G. Kessler
A. Kish
H. Landsman
R. F. Lang
D. Lellouch
L. J. Levinson
Q. Lin
S. Lindemann
Manfred Lindner
F. Lombardi
J. A. M. Lopes
A. Manfredini
I. C. Mariş
Teresa Marrodán Undagoitia
J. Masbou
F. V. Massoli
D. Masson
D. Mayani
M. Messina
K. Micheneau
A. Molinario
K. Morå
M. Murra
J. Naganoma
K. Ni
U. Oberlack
P. Pakarha
B. Pelssers
R. Persiani
F. Piastra
J. Pienaar
V. Pizzella
M. C. Piro
G. Plante
N. Priel
L. Rauch
S. Reichard
C. Reuter
A. Rizzo
S. Rosendahl
N. Rupp
J.M.F. dos Santos
G. Sartorelli
M. Scheibelhut
S. Schindler
J. Schreiner
M. Schumann
L. Scotto Lavina
M. Selvi
P. Shagin
M. Silva
H. Simgen
M. V. Sivers
A. Stein
D. Thers
A. Tiseni
G. Trinchero
C. Tunnell
M. Vargas
H Wang
Z. Wang
Y. Wei
C. Weinheimer
J. Wulf
J. Ye
Y. Zhang
B Farmer

We report on WIMP search results in the XENON100 detector using a non-relativistic effective field theory approach. The data from science run II (34 kg $\times$ 224.6 live days) was re-analyzed, with an increased recoil energy interval compared to previous analyses, ranging from $(6.6 - 240)~\mathrm{keV_\mathrm{nr}}$. The data is found to be compatible with the background-only hypothesis. We present 90% confidence level exclusion limits on the coupling constants of WIMP-nucleon effective operators using a binned profile likelihood method. We also consider the case of inelastic WIMP scattering, where incident WIMPs may up-scatter to a higher mass state, and set exclusion limits on this model as well.

Keywords:

Particle physics
Detector
Dark matter
Ranging
Scattering
Confidence interval
Weakly interacting massive particles
Physics
Effective field theory
Coupling constant
Nuclear physics
high energy
WIMP
Xenon
statistical analysis

Correction
Source
Cite
Save
Machine Reading By IdeaReader

References

Citations