Cosmogenic production of Ar37 in the context of the LUX-ZEPLIN experiment

J Aalbers,B Wang,D Bauer,B Lopez-Paredes,R Rosero,D Naim,L Manenti,M Arthurs,C Nedlik,A Stevens,A Lindote,M Solmaz,A Manalaysay,W Turner,S Shaw,G Sinev,C Ghag,A Piepke,S Balashov,S Burdin,A Monte,P Brás,S Kravitz,N Swanson,J Xu,J Balajthy,R Cabrita,N Angelides,J Genovesi,M Buuck,T Rushton,F Neves,M Yeh,M Timalsina,M Szydagis,O Jahangir,L Korley,K Kamdin,X Bai,R Linehan,W Lorenzon,I Olcina,J Mclaughlin,S Luitz,C Silva,D Hunt,A St J Murphy,M Cascella,Y Qie,A Khazov,I Stancu,E Perry,B Suerfu,Y Wang,K Beattie,A Richards,X Liu,S Fiorucci,A Nilima,C Chan,K Stifter,A Bhatti,J Lee,Q Riffard,I Khurana,S Woodford,D Porzio,B Boxer,E Mizrachi,N Parveen,E Morrison,W Wang,A Cottle,D Kodroff,R Smith,J Bang,A David,M Tripathi,L De Viveiros,B Penning,Q Xia,N Marangou,A Fan,J Reichenbacher,H Flaecher,A Baxter,A Biekert,G Pereira,W Ji,P Rossiter,S Gokhale,D Khaitan,L Kreczko,J Pershing,E Bodnia,Z Tong,S Fayer,T Fruth,H Chen,U Utku,J Lin,E Druszkiewicz,D Santone,M Trask,X Xiang,R Taylor,M Horn,H Kraus,F Alder,J A Nikoleyczik ,R L Mannino ,Alexander A Baker ,Jason Soria ,M E Monzani ,T J Whitis ,W H Lippincott ,C Lévy ,J R Watson ,J W Bargemann ,J E Armstrong ,M Mccarthy ,J D Morales Mendoza ,M Gilchriese ,James Turner Johnson ,Michael Williams ,Andrew Naylor ,P Majewski ,C B Gwilliam ,D R Tronstad ,R White ,K C Oliver-Mallory ,R Webb ,G M Blockinger ,A A Cole ,C S Amarasinghe ,R J Gaitskell ,D R Tiedt ,P R Scovell ,C M Ignarra ,Surajit Pal ,A Kaboth ,N M Fearon ,J J Wang ,E López Asamar ,Oisín Creaner ,A Kamaha ,V Solovov ,S R Eriksen ,D R Tovey ,C Brew ,K J Palladino ,S Alsum ,P A Terman ,J Busenitz ,S A Hertel ,Joseph Silk ,J D Palmer ,J A Morad ,P Sørensen ,J E Cutter ,S J Haselschwardt ,N Chott ,T Shutt ,Adelaide Ames ,V A Kudryavtsev ,C E Dahl ,H M Araújo ,A K Al Musalhi ,H J Birch ,E F Gibson ,S Patton ,G R C Rischbieter ,M V Converse ,E D Fraser ,C Hall ,E P Bernard ,T J Sumner ,J E Y Dobson ,C Wright ,Aviral Chawla ,A B M R Sazzad ,Tyler Anderson ,M I Lopes ,M G D Van Der Grinten ,R W Schnee ,M C Carmona-Benitez ,E H Miller ,T P Biesiadzinski ,E V Korolkova ,D N Mckinsey ,H N Nelson ,B J Mount ,F L H Wolfs ,R S James ,G A Cox ,D Q Huang ,David I Woodward ,Audrius Vaitkus ,E A Leason ,D S Akerib ,C Rhyne ,Wc Taylor ,E K Pease ,D S Leonard ,W H To ,D Temples ,K T Lesko

doi:10.1103/physrevd.105.082004

Abstract

We estimate the amount of $^{37}$Ar produced in natural xenon via cosmic ray-induced spallation, an inevitable consequence of the transportation and storage of xenon on the Earth's surface. We then calculate the resulting $^{37}$Ar concentration in a 10-tonne payload~(similar to that of the LUX-ZEPLIN experiment) assuming a representative schedule of xenon purification, storage and delivery to the underground facility. Using the spallation model by Silberberg and Tsao, the sea level production rate of $^{37}$Ar in natural xenon is estimated to be 0.024~atoms/kg/day. Assuming the xenon is successively purified to remove radioactive contaminants in 1-tonne batches at a rate of 1~tonne/month, the average $^{37}$Ar activity after 10~tonnes are purified and transported underground is 0.058--0.090~$\mu$Bq/kg, depending on the degree of argon removal during above-ground purification. Such cosmogenic $^{37}$Ar will appear as a noticeable background in the early science data, while decaying with a 35~day half-life. This newly-noticed production mechanism of $^{37}$Ar should be considered when planning for future liquid xenon-based experiments.

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