Behaviour of 222Rn at cryogenic temperatures

被引:0
|
作者
Lindemann, Sebastian [1 ]
Simgen, Hardy [1 ]
Zuzel, Grzegorz [2 ]
机构
[1] Max Planck Inst Kernphys, Postfach 103980, D-69029 Heidelberg, Germany
[2] Jagiellonian Univ, Inst Phys, PL-31007 Krakow, Poland
来源
TOPICAL WORKSHOP ON LOW RADIOACTIVITY TECHNIQUES - LRT 2010 | 2011年 / 1338卷
关键词
radon; low-level physics; gas counting; cryogenic gases; argon;
D O I
10.1063/1.3579574
中图分类号
O59 [应用物理学];
学科分类号
摘要
The behaviour of radon in a cryogenic environment is still not well known. Therefore, measured radon emanation rates at room temperature cannot be translated directly to cryogenic conditions. In this work we present a table-top experiment that provides a direct way of determining the behaviour of Rn-222 in cryogenic argon and helium at liquid argon temperature. We observe an increased emanation rate of Rn-222 atoms to liquid argon compared to the rate observed to helium at room temperature. We also find that Rn-222 atoms stick to cold metal surfaces when emanated to helium at liquid argon temperature but partly distribute in the liquid when emanated to cryogenic argon. Concluding, we give possible interpretations of the observations.
引用
收藏
页码:156 / +
页数:2
相关论文
共 50 条
  • [21] Test of a northwards-decreasing 222Rn source term by comparison of modelled and observed atmospheric 222Rn concentrations
    Robertson, LB
    Stevenson, DS
    Conen, F
    TELLUS SERIES B-CHEMICAL AND PHYSICAL METEOROLOGY, 2005, 57 (02): : 116 - 123
  • [22] Design and Tests of a Detector for 222Rn in Soil-gas Measurements based on 222Rn Absorbing Scintillating Polymers
    Mitev, Krasimir K.
    Tsankov, Ludmil T.
    Mitev, Mityo G.
    Dutsov, Chavdar C.
    Georgiev, Strahil B.
    Kolev, Srebrin T.
    Markov, Nikolay M.
    Todorov, Todor Hr.
    2017 IEEE NUCLEAR SCIENCE SYMPOSIUM AND MEDICAL IMAGING CONFERENCE (NSS/MIC), 2017,
  • [23] Concentrations of 222Rn and 220Rn in indoor air
    Vaupotic, Janja
    Celikovic, Igor
    Smrekar, Natasa
    Zunic, Zora S.
    Kobal, Ivan
    ACTA CHIMICA SLOVENICA, 2008, 55 (01) : 160 - 165
  • [24] 222Rn and 220Rn diffusion in two mediums
    Markovic, V. M.
    Nikezic, D.
    Stevanovic, N.
    NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2017, 857 : 16 - 23
  • [25] Determination of 222Rn absorption properties of polycarbonate foils by liquid scintillation counting. Application to 222Rn measurements
    Mitev, K.
    Cassette, P.
    Georgiev, S.
    Dimitrova, I.
    Sabot, B.
    Boshkova, T.
    Tartes, I.
    Pressyanov, D.
    APPLIED RADIATION AND ISOTOPES, 2016, 109 : 270 - 275
  • [26] Present status of 222Rn in groundwater in Extremadura
    Lopez, M. Gaian
    Sanchez, A. Martin
    JOURNAL OF ENVIRONMENTAL RADIOACTIVITY, 2008, 99 (10) : 1539 - 1543
  • [27] γ-Spectrometric Determination of 222Rn in Ground Water
    A. K. Mukhamedov
    G. V. Poteshkin
    U. S. Salikhbaev
    A. N. Safarov
    T. Kh. Khazratov
    Sh. Kh. Khushmurodov
    I. T. Muminov
    A. Kh. Inoyatov
    D. Sh. Rashidova
    I. Kh. Kholbaev
    Atomic Energy, 2002, 92 : 265 - 267
  • [28] AN INTEGRATING AIR SAMPLER FOR DETERMINATION OF 222RN
    SILL, CW
    HEALTH PHYSICS, 1969, 16 (03): : 371 - +
  • [29] An evaluation of 222Rn concentrations in Idaho groundwater
    Paulus, LR
    Gesell, TF
    Brey, RR
    HEALTH PHYSICS, 1998, 74 (02): : 237 - 241
  • [30] A Micromegas detector for 222Rn emanations measurements
    Garcia, J. A.
    Garza, J. G.
    Irastorza, I. G.
    Mirallas, H.
    LOW RADIOACTIVITY TECHNIQUES 2013 (LRT 2013), 2013, 1549 : 42 - 45
12345