Radiopurity of CaWO4 crystals for direct dark matter search with CRESST and EURECA

A. Münster; M. V. Sivers; G. Angloher; A. Bento; C. Bucci; L. Canonica; A. Erb; F. V. Feilitzsch; P. Gorla; A. Gütlein; D. Hauff; J. Jochum; H. Kraus; J. C. Lanfranchi; M. Laubenstein; J. Loebell; Y. Ortigoza; F. Petricca; W. Potzel; F. Pröbst; J. Puimedon; F. Reindl; S. Roth; K. Rottler; C. Sailer; K. Schäffner; J. Schieck; S. Scholl; S. Schönert; W. Seidel; L. Stodolsky; C. Strandhagen; R. Strauss; A. Tanzke; M. Uffinger; A. Ulrich; I. Usherov; S. Wawoczny; M. Willers; M. Wüstrich; A. Zöller

doi:10.1088/1475-7516/2014/05/018

Radiopurity of CaWO₄ crystals for direct dark matter search with CRESST and EURECA

A. Münster, M. V. Sivers, G. Angloher, A. Bento, C. Bucci, L. Canonica, A. Erb, F. V. Feilitzsch, P. Gorla, A. Gütlein, D. Hauff, J. Jochum, H. Kraus, J. C. Lanfranchi, M. Laubenstein, J. Loebell, Y. Ortigoza, F. Petricca, W. Potzel, F. PröbstJ. Puimedon, F. Reindl, S. Roth, K. Rottler, C. Sailer, K. Schäffner, J. Schieck, S. Scholl, S. Schönert, W. Seidel, L. Stodolsky, C. Strandhagen, R. Strauss, A. Tanzke, M. Uffinger, A. Ulrich, I. Usherov, S. Wawoczny, M. Willers, M. Wüstrich, A. Zöller

Chair of Experimental Astroparticle Physics

Research output: Contribution to journal › Article › peer-review

28 Scopus citations

Abstract

The direct dark matter search experiment CRESST uses scintillating CaWO₄ single crystals as targets for possible WIMP scatterings. An intrinsic radioactive contamination of the crystals as low as possible is crucial for the sensitivity of the detectors. In the past CaWO₄ crystals operated in CRESST were produced by institutes in Russia and the Ukraine. Since 2011 CaWO₄ crystals have also been grown at the crystal laboratory of the Technische Universität München (TUM) to better meet the requirements of CRESST and of the future tonne-scale multi-material experiment EURECA. The radiopurity of the raw materials and of first TUM-grown crystals was measured by ultra-low background γ-spectrometry. Two TUM-grown crystals were also operated as low-temperature detectors at a test setup in the Gran Sasso underground laboratory. These measurements were used to determine the crystals' intrinsic α-activities which were compared to those of crystals produced at other institutes. The total α-activities of TUM-grown crystals as low as 1.23±0.06 mBq/kg were found to be significantly smaller than the activities of crystals grown at other institutes typically ranging between ∼ 15 mBq/kg and ∼ 35 mBq/kg.

Original language	English
Article number	018
Journal	Journal of Cosmology and Astroparticle Physics
Volume	2014
Issue number	5
DOIs	https://doi.org/10.1088/1475-7516/2014/05/018
State	Published - May 2014

Keywords

dark matter detectors
dark matter experiments

Access to Document

10.1088/1475-7516/2014/05/018

Cite this

Münster, A., Sivers, M. V., Angloher, G., Bento, A., Bucci, C., Canonica, L., Erb, A., Feilitzsch, F. V., Gorla, P., Gütlein, A., Hauff, D., Jochum, J., Kraus, H., Lanfranchi, J. C., Laubenstein, M., Loebell, J., Ortigoza, Y., Petricca, F., Potzel, W., ... Zöller, A. (2014). Radiopurity of CaWO₄ crystals for direct dark matter search with CRESST and EURECA. Journal of Cosmology and Astroparticle Physics, 2014(5), Article 018. https://doi.org/10.1088/1475-7516/2014/05/018

@article{7942d39a195f4fc59764c5eeac1f1f1e,

title = "Radiopurity of CaWO4 crystals for direct dark matter search with CRESST and EURECA",

abstract = "The direct dark matter search experiment CRESST uses scintillating CaWO4 single crystals as targets for possible WIMP scatterings. An intrinsic radioactive contamination of the crystals as low as possible is crucial for the sensitivity of the detectors. In the past CaWO4 crystals operated in CRESST were produced by institutes in Russia and the Ukraine. Since 2011 CaWO4 crystals have also been grown at the crystal laboratory of the Technische Universit{\"a}t M{\"u}nchen (TUM) to better meet the requirements of CRESST and of the future tonne-scale multi-material experiment EURECA. The radiopurity of the raw materials and of first TUM-grown crystals was measured by ultra-low background γ-spectrometry. Two TUM-grown crystals were also operated as low-temperature detectors at a test setup in the Gran Sasso underground laboratory. These measurements were used to determine the crystals' intrinsic α-activities which were compared to those of crystals produced at other institutes. The total α-activities of TUM-grown crystals as low as 1.23±0.06 mBq/kg were found to be significantly smaller than the activities of crystals grown at other institutes typically ranging between ∼ 15 mBq/kg and ∼ 35 mBq/kg.",

keywords = "dark matter detectors, dark matter experiments",

author = "A. M{\"u}nster and Sivers, {M. V.} and G. Angloher and A. Bento and C. Bucci and L. Canonica and A. Erb and Feilitzsch, {F. V.} and P. Gorla and A. G{\"u}tlein and D. Hauff and J. Jochum and H. Kraus and Lanfranchi, {J. C.} and M. Laubenstein and J. Loebell and Y. Ortigoza and F. Petricca and W. Potzel and F. Pr{\"o}bst and J. Puimedon and F. Reindl and S. Roth and K. Rottler and C. Sailer and K. Sch{\"a}ffner and J. Schieck and S. Scholl and S. Sch{\"o}nert and W. Seidel and L. Stodolsky and C. Strandhagen and R. Strauss and A. Tanzke and M. Uffinger and A. Ulrich and I. Usherov and S. Wawoczny and M. Willers and M. W{\"u}strich and A. Z{\"o}ller",

year = "2014",

month = may,

doi = "10.1088/1475-7516/2014/05/018",

language = "English",

volume = "2014",

journal = "Journal of Cosmology and Astroparticle Physics",

issn = "1475-7516",

publisher = "IOP Publishing Ltd.",

number = "5",

}

Münster, A, Sivers, MV, Angloher, G, Bento, A, Bucci, C, Canonica, L, Erb, A, Feilitzsch, FV, Gorla, P, Gütlein, A, Hauff, D, Jochum, J, Kraus, H, Lanfranchi, JC, Laubenstein, M, Loebell, J, Ortigoza, Y, Petricca, F, Potzel, W, Pröbst, F, Puimedon, J, Reindl, F, Roth, S, Rottler, K, Sailer, C, Schäffner, K, Schieck, J, Scholl, S, Schönert, S, Seidel, W, Stodolsky, L, Strandhagen, C, Strauss, R, Tanzke, A, Uffinger, M, Ulrich, A, Usherov, I, Wawoczny, S, Willers, M, Wüstrich, M & Zöller, A 2014, 'Radiopurity of CaWO₄ crystals for direct dark matter search with CRESST and EURECA', Journal of Cosmology and Astroparticle Physics, vol. 2014, no. 5, 018. https://doi.org/10.1088/1475-7516/2014/05/018

TY - JOUR

T1 - Radiopurity of CaWO4 crystals for direct dark matter search with CRESST and EURECA

AU - Münster, A.

AU - Sivers, M. V.

AU - Angloher, G.

AU - Bento, A.

AU - Bucci, C.

AU - Canonica, L.

AU - Erb, A.

AU - Feilitzsch, F. V.

AU - Gorla, P.

AU - Gütlein, A.

AU - Hauff, D.

AU - Jochum, J.

AU - Kraus, H.

AU - Lanfranchi, J. C.

AU - Laubenstein, M.

AU - Loebell, J.

AU - Ortigoza, Y.

AU - Petricca, F.

AU - Potzel, W.

AU - Pröbst, F.

AU - Puimedon, J.

AU - Reindl, F.

AU - Roth, S.

AU - Rottler, K.

AU - Sailer, C.

AU - Schäffner, K.

AU - Schieck, J.

AU - Scholl, S.

AU - Schönert, S.

AU - Seidel, W.

AU - Stodolsky, L.

AU - Strandhagen, C.

AU - Strauss, R.

AU - Tanzke, A.

AU - Uffinger, M.

AU - Ulrich, A.

AU - Usherov, I.

AU - Wawoczny, S.

AU - Willers, M.

AU - Wüstrich, M.

AU - Zöller, A.

PY - 2014/5

Y1 - 2014/5

N2 - The direct dark matter search experiment CRESST uses scintillating CaWO4 single crystals as targets for possible WIMP scatterings. An intrinsic radioactive contamination of the crystals as low as possible is crucial for the sensitivity of the detectors. In the past CaWO4 crystals operated in CRESST were produced by institutes in Russia and the Ukraine. Since 2011 CaWO4 crystals have also been grown at the crystal laboratory of the Technische Universität München (TUM) to better meet the requirements of CRESST and of the future tonne-scale multi-material experiment EURECA. The radiopurity of the raw materials and of first TUM-grown crystals was measured by ultra-low background γ-spectrometry. Two TUM-grown crystals were also operated as low-temperature detectors at a test setup in the Gran Sasso underground laboratory. These measurements were used to determine the crystals' intrinsic α-activities which were compared to those of crystals produced at other institutes. The total α-activities of TUM-grown crystals as low as 1.23±0.06 mBq/kg were found to be significantly smaller than the activities of crystals grown at other institutes typically ranging between ∼ 15 mBq/kg and ∼ 35 mBq/kg.

AB - The direct dark matter search experiment CRESST uses scintillating CaWO4 single crystals as targets for possible WIMP scatterings. An intrinsic radioactive contamination of the crystals as low as possible is crucial for the sensitivity of the detectors. In the past CaWO4 crystals operated in CRESST were produced by institutes in Russia and the Ukraine. Since 2011 CaWO4 crystals have also been grown at the crystal laboratory of the Technische Universität München (TUM) to better meet the requirements of CRESST and of the future tonne-scale multi-material experiment EURECA. The radiopurity of the raw materials and of first TUM-grown crystals was measured by ultra-low background γ-spectrometry. Two TUM-grown crystals were also operated as low-temperature detectors at a test setup in the Gran Sasso underground laboratory. These measurements were used to determine the crystals' intrinsic α-activities which were compared to those of crystals produced at other institutes. The total α-activities of TUM-grown crystals as low as 1.23±0.06 mBq/kg were found to be significantly smaller than the activities of crystals grown at other institutes typically ranging between ∼ 15 mBq/kg and ∼ 35 mBq/kg.

KW - dark matter detectors

KW - dark matter experiments

UR - http://www.scopus.com/inward/record.url?scp=84902583824&partnerID=8YFLogxK

U2 - 10.1088/1475-7516/2014/05/018

DO - 10.1088/1475-7516/2014/05/018

M3 - Article

AN - SCOPUS:84902583824

SN - 1475-7516

VL - 2014

JO - Journal of Cosmology and Astroparticle Physics

JF - Journal of Cosmology and Astroparticle Physics

IS - 5

M1 - 018

ER -

Radiopurity of CaWO₄ crystals for direct dark matter search with CRESST and EURECA

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this