V
V. V. Golovko
Researcher at Chalk River Laboratories
Publications - 3
Citations - 92
V. V. Golovko is an academic researcher from Chalk River Laboratories. The author has contributed to research in topics: Scintillation & Dark matter. The author has an hindex of 2, co-authored 3 publications receiving 78 citations.
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Journal ArticleDOI
Design and construction of the DEAP-3600 dark matter detector
P. Amaudruz,M. Baldwin,M. Batygov,B. Beltran,C. E. Bina,D. Bishop,J. Bonatt,Gary Boorman,Mark Guy Boulay,Mark Guy Boulay,B. Broerman,T. Bromwich,J. F. Bueno,P. M. Burghardt,A. Butcher,Bei Cai,Stephen Kam-wah Chan,Min Chen,R. Chouinard,S. Churchwell,B. T. Cleveland,D. Cranshaw,K. Dering,J. DiGioseffo,S. Dittmeier,F. Duncan,Monica Dunford,A. Erlandson,A. Erlandson,N. Fatemighomi,S. Florian,A. Flower,R. Ford,R. Gagnon,P. Giampa,V. V. Golovko,P. Gorel,P. Gorel,R. Gornea,E. Grace,K. Graham,Darren Grant,E. Gulyev,A. Hall,A. L. Hallin,M. Hamstra,M. Hamstra,P. J. Harvey,C. Hearns,C. J. Jillings,O. Kamaev,A. Kemp,M. Kuźniak,M. Kuźniak,S. Langrock,F. La Zia,B. Lehnert,O. Li,J. Lidgard,P. Liimatainen,C. Lim,T. Lindner,Y. Linn,Shuai Liu,Peter Majewski,R. Mathew,A. B. McDonald,T. McElroy,K. W. McFarlane,T. McGinn,J. B. McLaughlin,S. Mead,R. Mehdiyev,C. Mielnichuk,Jocelyn Monroe,A. Muir,P. Nadeau,C. Nantais,C. Ng,A. J. Noble,E. O'Dwyer,C. Ohlmann,K. Olchanski,K. S. Olsen,C. Ouellet,P. Pasuthip,S. J. M. Peeters,T. Pollmann,T. Pollmann,T. Pollmann,E. T. Rand,W. Rau,C. Rethmeier,F. Retiere,N. Seeburn,B. Shaw,K. Singhrao,K. Singhrao,P. Skensved,B. Smith,N. J. T. Smith,T. Sonley,J. Soukup,R. Stainforth,C. Stone,V. Strickland,V. Strickland,Bhaskar Sur,J. Tang,Joanne Taylor,Laurelle Maria Veloce,E. Vázquez-Jáuregui,E. Vázquez-Jáuregui,J. Walding,Martin Ward,S. Westerdale,Randall White,E. Woolsey,J. Zielinski +118 more
TL;DR: The Dark Matter Experiment using Argon Pulse-shape discrimination (DEAP) has been designed for a direct detection search for particle dark matter using a single-phase liquid argon target as mentioned in this paper, and the projected cross section sensitivity for DEAP-3600 to the spin-independent scattering of Weakly Interacting Massive Particles (WIMPs) on nucleons is 10−46cm2 for a 100 GeV/c2 WIMP mass with a fiducial exposure of 3 tonne-years.
Journal ArticleDOI
The liquid-argon scintillation pulseshape in DEAP-3600
P. Adhikari,R. Ajaj,G. R. Araujo,M. Batygov,B. Beltran,C. E. Bina,Mark Guy Boulay,Mark Guy Boulay,B. Broerman,J. F. Bueno,A. Butcher,Bei Cai,Bei Cai,Miguel Cárdenas-Montes,Stefano Cavuoti,Y. Chen,B. T. Cleveland,J. M. Corning,S. J. Daugherty,P. Di Stefano,K. Dering,Luca Doria,F. A. Duncan,Monica Dunford,A. Erlandson,A. Erlandson,N. Fatemighomi,G. Fiorillo,A. Flower,A. Flower,R. Ford,R. Gagnon,D. Gallacher,E. A. Garcés,P. Garcia Abia,S. Garg,P. Giampa,P. Giampa,D. Goeldi,V. V. Golovko,P. Gorel,K. Graham,Darren Grant,A. Grobov,A. Grobov,A. L. Hallin,M. Hamstra,M. Hamstra,P. J. Harvey,C. Hearns,A. Ilyasov,A. Ilyasov,A. Joy,C. J. Jillings,O. Kamaev,G. Kaur,A. Kemp,I. Kochanek,M. Kuźniak,M. Kuźniak,S. Langrock,F. La Zia,B. Lehnert,N. Levashko,N. Levashko,X. Li,O. Litvinov,J. Lock,Giuseppe Longo,I. N. Machulin,I. N. Machulin,P. Majewski,A. B. McDonald,T. McElroy,T. McGinn,T. McGinn,J. B. McLaughlin,J. B. McLaughlin,R. Mehdiyev,C. Mielnichuk,Jocelyn Monroe,P. Nadeau,C. Nantais,C. Ng,A. J. Noble,G. Oliviéro,C. Ouellet,S. Pal,P. Pasuthip,S. J. M. Peeters,V. Pesudo,M. C. Piro,T. Pollmann,E. T. Rand,C. Rethmeier,F. Retiere,E. Sanchez Garcia,T. Sánchez-Pastor,R. Santorelli,N. Seeburn,P. Skensved,B. Smith,N. J. T. Smith,T. Sonley,R. Stainforth,C. Stone,V. Strickland,V. Strickland,M. Stringer,Bhaskar Sur,E. Vázquez-Jáuregui,E. Vázquez-Jáuregui,Laurelle Maria Veloce,S. Viel,J. Walding,M. Waqar,Martin Ward,S. Westerdale,J. Willis,A. Zuñiga-Reyes +119 more
TL;DR: In this paper, the authors present a model for the pulseshape of electromagnetic background events in the energy region of interest for dark matter searches, which is composed of LAr scintillation physics, including the so-called intermediate component, the time response of the TPB wavelength shifter, including delayed TPB emission at $${\mathcal {O}}$(m) time-scales, and the PMT response.
Journal ArticleDOI
Pulse-shape discrimination against low-energy Ar-39 beta decays in liquid argon with 4.5 tonne-years of DEAP-3600 data
P. Adhikari,R. Ajaj,M. Alpízar-Venegas,Pierre-Andre Amaudruz,D. J. Auty,M. Batygov,B. Beltran,H. Benmansour,C. E. Bina,J. Bonatt,W. Bonivento,M. G. Boulay,B. Broerman,J. F. Bueno,P. M. Burghardt,A. Butcher,M. Cadeddu,B. Cai,Miguel Cárdenas-Montes,Stefano Cavuoti,Min Chen,Y. Chen,B. T. Cleveland,J. M. Corning,D. Cranshaw,S. J. Daugherty,P. DelGobbo,K. Dering,J. DiGioseffo,P. Di Stefano,Luca Doria,F. A. Duncan,Monica Dunford,E. Ellingwood,A. Erlandson,S. S. Farahani,N. Fatemighomi,G. Fiorillo,S. Florian,T. Flower,R. Ford,R. Gagnon,D. Gallacher,P. Garcia Abia,S. Garg,P. Giampa,D. Goeldi,V. V. Golovko,P. Gorel,K. Graham,Darren Grant,A. Grobov,A. L. Hallin,M. Hamstra,P. J. Harvey,C. Hearns,T. Hugues,A. Ilyasov,A. Joy,B. Jigmeddorj,C. J. Jillings,O. Kamaev,G. Kaur,A. A. Kemp,I. Kochanek,M. Kuźniak,M. Lai,S. Langrock,B. Lehnert,A. Leonhardt,N. Levashko,Xiujiang Li,J. Lidgard,T. Lindner,M. Lissia,J. Lock,Giuseppe Longo,I. N. Machulin,A. B. McDonald,T. McElroy,T. McGinn,J. B. McLaughlin,R. Mehdiyev,C. Mielnichuk,Jocelyn Monroe,P. Nadeau,C. Nantais,C. Ng,A. J. Noble,E. O'Dwyer,G. Oliviéro,C. Ouellet,S. Pal,P. Pasuthip,S. J. M. Peeters,M. Perry,V. Pesudo,E. Picciau,M. C. Piro,T. Pollmann,E. T. Rand,C. Rethmeier,F. Retiere,I. Rodríguez-García,L. Roszkowski,J. B. Ruhland,E. Sánchez-García,R. Santorelli,D. Sinclair,P. Skensved,B. Smith,N. J. T. Smith,T. Sonley,J. Soukup,R. Stainforth,C. Stone,V. Strickland,M. Stringer,Bhaskar Sur,J. Tang,E. Vázquez-Jáuregui,S. Viel,J. Walding,M. Waqar,Martin Ward,S. Westerdale,J. Willis,A. Zuñiga-Reyes +127 more
TL;DR: In this article, the authors used two types of PSD estimator: the prompt fraction, which considers the fraction of the scintillation signal in a narrow and a wide time window around the event peak, and the log-likelihood-ratio, which compares the observed photon arrival times to a signal and a background model.