• Bonczyk M, Michalik B, Chmielewska I. The self-absorption correction factor for 210Pb concentration in mining waste and influence on environmental radiation risk assessment. Isotopes in environmental and HealthStudies (2016) vol. 52.
  • Skubacz K., Wojtecki Ł., Urban P. 2016. The influence of particle size distribution on dose conversion factors for radon progeny in the underground excavations of hard coal mine. Journal of EnvironmentalRadioactivity. 162-163, 68-79.
  • Skubacz K., 2015. Measurements of low doses with Panasonic dosimeters. Algorithm and tests. RadiationMeasurements. 75. 9-14.
  • P. Urban, K. Skubacz, Nowy system dozymetryczny do pomiaru dawek promieniowania jonizującego absorbowanego przez personel placówek służby zdrowia wykorzystujący metodę termoluminescencji. Wiadomości Lekarskie 2015, 68(1),69-76.
  • Bzowski Z, Michalik B. Mineral composition and heavy metal contamination of sediments originating from radium rich formation water. Chemosphere 122 (2015) 79–87.
  • S. Chałupnik, A. Smoliński, M. Wysocka, 2014, Calibration of the method for C-14 measurements in combustion gases, Radiocarbon 56(3), 1207-1214.
  • Chmielewska I., Chałupnik S., Bonczyk M., 2014: Natural radioactivity in drinking underground waters in Upper Silesia and solid waste produced during treatment, Appl. Radiat. Isot. 93, 96-100.
  • B. Michalik, J. Brown, P. Krajewski. The fate and behaviour of enhanced natural radioactivity with respect to environmental protection. EnvironmentalImpactAssessmentReview 38 (2013) p.163–171.
  • Chałupnik S., Franus W., Wysocka M., Gzyl G. 2013, Application of zeolites for radium removal from mine water, Environmental Science and Pollution Research International; 20: 7900–7906.
  • Chałupnik, S.; Meisenberg, O.; Bi, L.; et al. 2010, Application of LSC and TLD methods for the measurement of radon and thoron decay products in air, Radiation Protection Dosimetry, Volume: 141 Issue: 4 Special Issue: SI, pp 390-394.

+ 48-32-259-2000