Identification of radiopure titanium for the LZ dark matter experiment and future rare event searches

Akerib, DS; Akerlof, CW; Akimov, DY; Alsum, SK; Araujo, HM; Arnquist, IJ; Arthurs, M; Bai, X; Bailey, AJ; Balajthy, J; Balashov, S; Barry, MJ; Belle, J; Beltrame, P; Benson, T; Bernard, EP; Bernstein, A; Biesiadzinski, TP; Boast, KE; Bolozdynya, A; Boxer, B; Bramante, R; Bras, P; Buckley, JH; Bugaev, VV; Bunker, R; Burdin, S; Busenitz, JK; Carels, C; Carlsmith, DL; Carlson, B; Carmona-Benitez, MC; Chan, C; Cherwinka, JJ; Chiller, AA; Chiller, C; Cottle, A; Coughlen, R; Craddock, WW; Currie, A; Dahl, CE; Davison, TJR; Dobi, A; Dobson, JEY; Druszkiewicz, E; Edberg, TK; Edwards, WR; Emmet, WT; Faham, CH; Fiorucci, S; Fruth, T; Gaitskell, RJ; Gantos, N; Gehman, VM; Gerhard, RM; Ghag, C; Gilchriese, MGD; Gomber, B; Hall, CR; Hans, S; Hanzel, K; Haselschwardt, S; Hertel, SA; Hillbrand, S; Hjernfelt, C; Hoff, MD; Holbrook, B; Holtom, E; Hoppe, EW; Hor, JY-K; Horn, M; Huang, DQ; Hurteau, TW; Ignarra, CM; Jacobsen, RG; Ji, W; Kaboth, A; Kamdin, K; Kazkaz, K; Khaitan, D; Khazov, A; Khromov, AV; Konovalov, AM; Korolkova, EV; Koyuncu, M; Kraus, H; Krebs, HJ; Kudryavtsev, VA; Kumpan, AV; Kyre, S; Lee, C; Lee, HS; Lee, J; Leonard, DS; Leonard, R; Lesko, KT; Levy, C; Liao, F-T; Lin, J; Lindote, A; Linehan, RE; Lippincott, WH; Liu, X; Lopes, MI; Paredes, BL; Lorenzon, W; Luitz, S; Majewski, P; Manalaysay, A; Manenti, L; Mannino, RL; Markley, DJ; Martin, TJ; Marzioni, MF; McConnell, CT; McKinsey, DN; Mei, D-M; Meng, Y; Miller, EH; Mizrachi, E; Mock, J; Monzani, ME; Morad, JA; Mount, BJ; Murphy, ASJ; Nehrkorn, C; Nelson, HN; Neves, F; Nikkel, JA; O'Dell, J; O'Sullivan, K; Olcina, I; Olevitch, MA; Oliver-Mallory, KC; Palladino, KJ; Pease, EK; Piepke, A; Powell, S; Preece, RM; Pushkin, K; Ratcliff, BN; Reichenbacher, J; Reichhart, L; Rhyne, CA; Richards, A; Rodrigues, JP; Rose, HJ; Rosero, R; Rossiter, P; Saba, JS; Sarychev, M; Schnee, RW; Schubnell, M; Scovell, PR; Shaw, S; Shutt, TA; Silva, C; Skarpaas, K; Skulski, W; Solmaz, M; Solovov, VN; Sorensen, P; Sosnovtsev, VV; Stancu, I; Stark, MR; Stephenson, S; Stiegler, TM; Stifter, K; Sumner, TJ; Szydagis, M; Taylor, DJ; Taylor, WC; Temples, D; Terman, PA; Thomas, KJ; Thomson, JA; Tiedt, DR; Timalsina, M; To, WH; Tomas, A; Tope, TE; Tripathi, M; Tvrznikova, L; Va'vra, J; Vacheret, A; Van der Grinten, MGD; Verbus, JR; Vuosalo, CO; Waldron, WL; Wang, R; Watson, R; Webb, RC; Wei, W-Z; While, M; White, DT; Whitis, TJ; Wisniewski, WJ; Witherell, MS; Wolfs, FLH; Woodward, D; Worm, S; Xu, J; Yeh, M; Yin, J; Zhang, C

8

IRUS Total
Downloads

Altmetric

Identification of radiopure titanium for the LZ dark matter experiment and future rare event searches

File	Description	Size	Format
1702.02646v4.pdf	Accepted version	628.12 kB	Adobe PDF	View/Open

Title:	Identification of radiopure titanium for the LZ dark matter experiment and future rare event searches
Authors:	Akerib, DS Akerlof, CW Akimov, DY Alsum, SK Araujo, HM Arnquist, IJ Arthurs, M Bai, X Bailey, AJ Balajthy, J Balashov, S Barry, MJ Belle, J Beltrame, P Benson, T Bernard, EP Bernstein, A Biesiadzinski, TP Boast, KE Bolozdynya, A Boxer, B Bramante, R Bras, P Buckley, JH Bugaev, VV Bunker, R Burdin, S Busenitz, JK Carels, C Carlsmith, DL Carlson, B Carmona-Benitez, MC Chan, C Cherwinka, JJ Chiller, AA Chiller, C Cottle, A Coughlen, R Craddock, WW Currie, A Dahl, CE Davison, TJR Dobi, A Dobson, JEY Druszkiewicz, E Edberg, TK Edwards, WR Emmet, WT Faham, CH Fiorucci, S Fruth, T Gaitskell, RJ Gantos, N Gehman, VM Gerhard, RM Ghag, C Gilchriese, MGD Gomber, B Hall, CR Hans, S Hanzel, K Haselschwardt, S Hertel, SA Hillbrand, S Hjernfelt, C Hoff, MD Holbrook, B Holtom, E Hoppe, EW Hor, JY-K Horn, M Huang, DQ Hurteau, TW Ignarra, CM Jacobsen, RG Ji, W Kaboth, A Kamdin, K Kazkaz, K Khaitan, D Khazov, A Khromov, AV Konovalov, AM Korolkova, EV Koyuncu, M Kraus, H Krebs, HJ Kudryavtsev, VA Kumpan, AV Kyre, S Lee, C Lee, HS Lee, J Leonard, DS Leonard, R Lesko, KT Levy, C Liao, F-T Lin, J Lindote, A Linehan, RE Lippincott, WH Liu, X Lopes, MI Paredes, BL Lorenzon, W Luitz, S Majewski, P Manalaysay, A Manenti, L Mannino, RL Markley, DJ Martin, TJ Marzioni, MF McConnell, CT McKinsey, DN Mei, D-M Meng, Y Miller, EH Mizrachi, E Mock, J Monzani, ME Morad, JA Mount, BJ Murphy, ASJ Nehrkorn, C Nelson, HN Neves, F Nikkel, JA O'Dell, J O'Sullivan, K Olcina, I Olevitch, MA Oliver-Mallory, KC Palladino, KJ Pease, EK Piepke, A Powell, S Preece, RM Pushkin, K Ratcliff, BN Reichenbacher, J Reichhart, L Rhyne, CA Richards, A Rodrigues, JP Rose, HJ Rosero, R Rossiter, P Saba, JS Sarychev, M Schnee, RW Schubnell, M Scovell, PR Shaw, S Shutt, TA Silva, C Skarpaas, K Skulski, W Solmaz, M Solovov, VN Sorensen, P Sosnovtsev, VV Stancu, I Stark, MR Stephenson, S Stiegler, TM Stifter, K Sumner, TJ Szydagis, M Taylor, DJ Taylor, WC Temples, D Terman, PA Thomas, KJ Thomson, JA Tiedt, DR Timalsina, M To, WH Tomas, A Tope, TE Tripathi, M Tvrznikova, L Va'vra, J Vacheret, A Van der Grinten, MGD Verbus, JR Vuosalo, CO Waldron, WL Wang, R Watson, R Webb, RC Wei, W-Z While, M White, DT Whitis, TJ Wisniewski, WJ Witherell, MS Wolfs, FLH Woodward, D Worm, S Xu, J Yeh, M Yin, J Zhang, C
Item Type:	Journal Article
Abstract:	The LUX-ZEPLIN (LZ) experiment will search for dark matter particle interactions with a detector containing a total of 10 tonnes of liquid xenon within a double-vessel cryostat. The large mass and proximity of the cryostat to the active detector volume demand the use of material with extremely low intrinsic radioactivity. We report on the radioassay campaign conducted to identify suitable metals, the determination of factors limiting radiopure production, and the selection of titanium for construction of the LZ cryostat and other detector components. This titanium has been measured with activities of 238Ue  < 1.6 mBq/kg, 238Ul  < 0.09 mBq/kg, 232The=0.28±0.03 mBq/kg, 232Thl=0.25±0.02 mBq/kg, 40K  < 0.54 mBq/kg, and 60Co  < 0.02 mBq/kg (68% CL). Such low intrinsic activities, which are some of the lowest ever reported for titanium, enable its use for future dark matter and other rare event searches. Monte Carlo simulations have been performed to assess the expected background contribution from the LZ cryostat with this radioactivity. In 1,000 days of WIMP search exposure of a 5.6-tonne fiducial mass, the cryostat will contribute only a mean background of 0.160 ± 0.001(stat) ± 0.030(sys) counts.
Issue Date:	25-Sep-2017
Date of Acceptance:	22-Sep-2017
URI:	http://hdl.handle.net/10044/1/55881
DOI:	https://dx.doi.org/10.1016/j.astropartphys.2017.09.002
ISSN:	0927-6505
Publisher:	Elsevier
Start Page:	1
End Page:	10
Journal / Book Title:	Astroparticle Physics
Volume:	96
Copyright Statement:	© 2017, Elsevier. Licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International http://creativecommons.org/licenses/by-nc-nd/4.0/
Sponsor/Funder:	Science and Technology Facilities Council (STFC)
Funder's Grant Number:	ST/P00377X/1
Keywords:	Science & Technology Physical Sciences Astronomy & Astrophysics Physics, Particles & Fields Physics ZEPLIN-III GERDA physics.ins-det hep-ex 0201 Astronomical And Space Sciences 0202 Atomic, Molecular, Nuclear, Particle And Plasma Physics Nuclear & Particles Physics
Publication Status:	Published
Open Access location:	https://arxiv.org/abs/1702.02646
Appears in Collections:	Physics High Energy Physics Faculty of Natural Sciences