Article Category: Conference Proceedings of the 13th International Conference “Methods of Absolute Chronology” June 5–7th, 2019, Tarnowskie Gory, Poland
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Aitken MJ, 1985a. Thermoluminescence Dating. Studies in Archaeological Science. Academic Press, London.AitkenMJ1985aAcademic PressLondonSearch in Google Scholar
Aitken MJ, 1985b. Alpha particle effectiveness: Numerical relationship between systems. Ancient TL 3: 22–25.AitkenMJ1985bAlpha particle effectiveness: Numerical relationship between systems32225Search in Google Scholar
Aitken MJ, 1998. An Introduction to Optical Dating: The Dating of Quaternary Sediments by the use of Photon-Stimulated Luminescence. Oxford University Press, Oxford.AitkenMJ1998Oxford University PressOxfordSearch in Google Scholar
Aitken MJ, and Bowman SGE, 1975. Thermoluminescent dating: Assessment of alpha particle contribution. Archaeometry 17(1): 132–138, DOI:10.1111/j.1475-4754.1975.tb00127.x.AitkenMJBowmanSGE1975Thermoluminescent dating: Assessment of alpha particle contribution17113213810.1111/j.1475-4754.1975.tb00127.xOpen DOISearch in Google Scholar
Bell WT, 1980. Alpha dose attenuation in quartz grains for thermoluminescence dating. Ancient TL 12: 4–8.BellWT1980Alpha dose attenuation in quartz grains for thermoluminescence dating1248Search in Google Scholar
Bos AJJ., Wallinga J, Johns C, Abellon RD, Brouwer JC, Schaart DR and Murray AS, 2006. Accurate calibration of a laboratory beta particle dose rate for dating purposes. Radiation Measurements 41(7–8): 1020–1025, DOI:10.1016/j.radmeas.2006.04.003.BosAJJ.WallingaJJohnsCAbellonRDBrouwerJCSchaartDRMurrayAS2006Accurate calibration of a laboratory beta particle dose rate for dating purposes417–81020102510.1016/j.radmeas.2006.04.003Open DOISearch in Google Scholar
Bøtter-Jensen L, Bulur E, Duller GAT and Murray AS, 2000. Advances in luminescence instrument systems. Radiation Measurements 32(5–6): 523–528, DOI:10.1016/S1350-4487(00)00039-1.Bøtter-JensenLBulurEDullerGATMurrayAS2000Advances in luminescence instrument systems325–652352810.1016/S1350-4487(00)00039-1Open DOISearch in Google Scholar
Bøtter-Jensen L, Thomsen KJ and Jain M, 2010. Review of optically stimulated luminescence (OSL) instrumental developments for retrospective dosimetry. Radiation Measurements 45(3–6): 253–257, DOI:10.1016/j.radmeas.2009.11.030.Bøtter-JensenLThomsenKJJainM2010Review of optically stimulated luminescence (OSL) instrumental developments for retrospective dosimetry453–625325710.1016/j.radmeas.2009.11.030Open DOISearch in Google Scholar
Bowman SGE and Huntley DJ, 1984. A new proposal for the expression of alpha efficiency in TL dating. Ancient TL 2: 6–8.BowmanSGEHuntleyDJ1984A new proposal for the expression of alpha efficiency in TL dating268Search in Google Scholar
Brennan BJ and Lyons RG, 1989. Ranges of alpha particles in various media. Ancient TL 7: 33–37.BrennanBJLyonsRG1989Ranges of alpha particles in various media73337Search in Google Scholar
Buechi MW, Lowick SE, Anselmetti FS, 2017. Luminescence dating of glaciolacustrine silt in overdeepened basin fills beyond the last interglacial. Quaternary Geochronology 37: 55–67, DOI:10.1016/j.quageo.2016.09.009.BuechiMWLowickSEAnselmettiFS2017Luminescence dating of glaciolacustrine silt in overdeepened basin fills beyond the last interglacial37556710.1016/j.quageo.2016.09.009Open DOISearch in Google Scholar
Dietze M, Kreutzer S, Burow C, Fuchs MC, Fischer M and Schmidt C, 2016. The abanico plot: Visualising chronometric data with individual standard errors. Quaternary Geochronology 31: 12–18, DOI:10.1016/j.quageo.2015.09.003.DietzeMKreutzerSBurowCFuchsMCFischerMSchmidtC2016The abanico plot: Visualising chronometric data with individual standard errors31121810.1016/j.quageo.2015.09.003Open DOISearch in Google Scholar
Duller GAT, 2015. The analyst software package for luminescence data: Overview and recent improvements. Ancient TL 33: 35–42.DullerGAT2015The analyst software package for luminescence data: Overview and recent improvements333542Search in Google Scholar
Fleming S, 1979. Thermoluminescence Techniques in Archaeology. Clarendon Press, Oxford.FlemingS1979Clarendon PressOxfordSearch in Google Scholar
Franklin AD and Hornyak WF, 1992. Normalization of inclusion size quartz TL data. Ancient TL 10: 1–6.FranklinADHornyakWF1992Normalization of inclusion size quartz TL data1016Search in Google Scholar
Gao L, Long H, Tamura T, Ye L, Hou Y, Shen J, 2020. Refined chronostratigraphy of a late Quaternary Sedimentary sequence from the Yangtze River delta based on K-feldspar luminescence dating. Marine Geology 427: 106271. DOI:10.1016/j.margeo.2020.106271.GaoLLongHTamuraTYeLHouYShenJ2020Refined chronostratigraphy of a late Quaternary Sedimentary sequence from the Yangtze River delta based on K-feldspar luminescence dating42710627110.1016/j.margeo.2020.106271Open DOISearch in Google Scholar
Göksu HY, Bailiff IK, Bøtter-Jensen L, Brodski L, Hütt G and Stoneham D, 1995. Interlaboratory beta source calibration using TL and OSL on natural quartz. Radiation Measurements 24(4): 479–483, DOI:10.1016/1350-4487(95)00258-G.GöksuHYBailiffIKBøtter-JensenLBrodskiLHüttGStonehamD1995Interlaboratory beta source calibration using TL and OSL on natural quartz24447948310.1016/1350-4487(95)00258-GOpen DOISearch in Google Scholar
Guérin G and Valladas H, 2014. Cross-calibration between beta and gamma sources using quartz OSL: Consequences of the use of the SAR protocol in optical dating. Radiation Measurements 68: 31–37, DOI:10.1016/j.radmeas.2014.06.010.GuérinGValladasH2014Cross-calibration between beta and gamma sources using quartz OSL: Consequences of the use of the SAR protocol in optical dating68313710.1016/j.radmeas.2014.06.010Open DOISearch in Google Scholar
Hansen V, Murray AS, Buylaert JP, Yeo EY and Thomsen K, 2015. A new irradiated quartz for beta source calibration. Radiation Measurements 81: 123–127, DOI:10.1016/j.radmeas.2015.02.017.HansenVMurrayASBuylaertJPYeoEYThomsenK2015A new irradiated quartz for beta source calibration8112312710.1016/j.radmeas.2015.02.017Open DOISearch in Google Scholar
Hansen V, Murray AS, Thomsen K, Jain M, Autzen M and Buylaert JP, 2018. Towards the origins of over-dispersion in beta source calibration. Radiation Measurements 120: 1–6, DOI:10.1016/j.radmeas.2018.05.014.HansenVMurrayASThomsenKJainMAutzenMBuylaertJP2018Towards the origins of over-dispersion in beta source calibration1201610.1016/j.radmeas.2018.05.014Open DOISearch in Google Scholar
Kadereit A and Kreutzer S, 2013. Risø calibration quartz – A challenge for β-source calibration. An applied study with relevance for luminescence dating. Measurement 46(7): 2238–2250, DOI:10.1016/j.measurement.2013.03.005.KadereitAKreutzerS2013Risø calibration quartz – A challenge for β-source calibration. An applied study with relevance for luminescence dating4672238225010.1016/j.measurement.2013.03.005Open DOISearch in Google Scholar
Kreutzer S, Schmidt C, DeWitt R and Fuchs M, 2014. The a-value of polymineral fine grain samples measured with the post-IR IRSL protocol. Radiation Measurements 69: 18–29, DOI:10.1016/j.radmeas.2014.04.027.KreutzerSSchmidtCDeWittRFuchsM2014The a-value of polymineral fine grain samples measured with the post-IR IRSL protocol69182910.1016/j.radmeas.2014.04.027Open DOISearch in Google Scholar
Mauz B, Bode T, Mainz E, Blanchard H, Hilger W, Dikau R and Zöller L, 2002. The luminescence dating laboratory at University of Bonn: Equipment and procedures. Ancient TL 20(2): 53–61.MauzBBodeTMainzEBlanchardHHilgerWDikauRZöllerL2002The luminescence dating laboratory at University of Bonn: Equipment and procedures2025361Search in Google Scholar
Mauz B, Packman S and Lang A, 2006. The alpha effectiveness in silt-sized quartz: New data obtained by single and multiple aliquot protocols Ancient TL 24(2): 47–52.MauzBPackmanSLangA2006The alpha effectiveness in silt-sized quartz: New data obtained by single and multiple aliquot protocols2424752Search in Google Scholar
Murray AS and Wintle AG, 2003. The single aliquot regenerative dose protocol: Potential for improvements in reliability. Radiation Measurements 37(4–5): 377–381, DOI:10.1016/S1350-4487(03)00053-2.MurrayASWintleAG2003The single aliquot regenerative dose protocol: Potential for improvements in reliability374–537738110.1016/S1350-4487(03)00053-2Open DOISearch in Google Scholar
Ogata M, Hasebe N, Fujii N and Yamakawa M, 2017. Measuring apparent dose rate factors using beta and gamma rays, and alpha efficiency for precise thermoluminescence dating of calcite. Journal of Mineralogical and Petrological Sciences 112: 336–345.OgataMHasebeNFujiiNYamakawaM2017Measuring apparent dose rate factors using beta and gamma rays, and alpha efficiency for precise thermoluminescence dating of calcite11233634510.2465/jmps.161126Search in Google Scholar
Rees-Jones J, 1995. Optical dating of young sediments using fine-grain quartz. Ancient TL, 13: 9–14.Rees-JonesJ1995Optical dating of young sediments using fine-grain quartz13914Search in Google Scholar
Richter D, Pintaske R, Dornich K and Krbetschek M, 2012. A novel beta source design for uniform irradiation in dosimetric applications. Ancient TL 30(2): 57–63.RichterDPintaskeRDornichKKrbetschekM2012A novel beta source design for uniform irradiation in dosimetric applications3025763Search in Google Scholar
Richter D, Richter A and Dornich K, 2013. Lexsyg – A new system for luminescence research. Geochronometria 40(4): 220–228, DOI:10.2478/s13386-013-0110-0.RichterDRichterADornichK2013Lexsyg – A new system for luminescence research40422022810.2478/s13386-013-0110-0Open DOISearch in Google Scholar
Richter D, Richter A and Dornich K, 2015. Lexsyg smart – A luminescence detection system for dosimetry, material research and dating application. Geochronometria 42(1): 202–209, DOI:10.1515/geochr-2015-0022.RichterDRichterADornichK2015Lexsyg smart – A luminescence detection system for dosimetry, material research and dating application42120220910.1515/geochr-2015-0022Open DOISearch in Google Scholar
Richter D, Zink AJC., Przegietka KR, Cardoso GO, Gouveia MA and Prudêncio MI, 2003. Source calibrations and blind test results from the new Luminescence Dating Laboratory at the Instituto Tecnológico e Nuclear, Sacavém, Portugal. Ancient TL 21(1): 43–48.RichterDZinkAJC.PrzegietkaKRCardosoGOGouveiaMAPrudêncioMI2003Source calibrations and blind test results from the new Luminescence Dating Laboratory at the Instituto Tecnológico e Nuclear, Sacavém, Portugal2114348Search in Google Scholar
Schmidt C, Bösken J and Kolb T, 2018. Is there a common alpha-efficiency in polymineral samples measured by various infrared stimulated luminescence protocols?. Geochronometria 45: 160–172, DOI:10.1515/geochr-2015-0095.SchmidtCBöskenJKolbT2018Is there a common alpha-efficiency in polymineral samples measured by various infrared stimulated luminescence protocols?4516017210.1515/geochr-2015-0095Open DOISearch in Google Scholar
Singhvi AK and Aitken MJ, 1978. Americium-241 for alpha irradiations. Ancient TL 3: 2–9.SinghviAKAitkenMJ1978Americium-241 for alpha irradiations329Search in Google Scholar
Sipos Gy, Kiss T and Tóth O, 2016. Constraining the age of flood-plain levels along the lower section of River Tisza, Hungary. Journal of Environmental Geography 9(1–2): 39–44, DOI:10.1515/jengeo-2016-0006.SiposGyKissTTóthO2016Constraining the age of flood-plain levels along the lower section of River Tisza, Hungary91–2394410.1515/jengeo-2016-0006Open DOISearch in Google Scholar
Sipos Gy, Marković SB, Filyó D, Tóth O, Gavrilov MB, Nagy I, Lukic T, Bartyik T, Kiss T, Mezősi G, (in prep). Aeolian dust deposition during the last glacial cycle at the centre of the Backa Loess Plateau, Vojvodina, Serbia.SiposGyMarkovićSBFilyóDTóthOGavrilovMBNagyILukicTBartyikTKissTMezősiG(in prep).VojvodinaSerbiaSearch in Google Scholar
Thiel C, Buylaert JP, Murray AS, Terhorst B, Hofer I, Tsukamoto S and Frechen M, 2011. Luminescence dating of the Stratzing loess profile (Austria) – Testing the potential of an elevated temperature post-IR IRSL protocol. Quaternary International 234: 23–31, DOI:10.1016/j.quaint.2010.05.018.ThielCBuylaertJPMurrayASTerhorstBHoferITsukamotoSFrechenM2011Luminescence dating of the Stratzing loess profile (Austria) – Testing the potential of an elevated temperature post-IR IRSL protocol234233110.1016/j.quaint.2010.05.018Open DOISearch in Google Scholar
Thomsen KJ, Murray AS, Jain M and Bøtter-Jensen L, 2008. Laboratory fading rates of various luminescence signals from feldspar-rich sediment extracts. Radiation Measurements 43: 1474–1486, DOI:10.1016/j.radmeas.2008.06.002.ThomsenKJMurrayASJainMBøtter-JensenL2008Laboratory fading rates of various luminescence signals from feldspar-rich sediment extracts431474148610.1016/j.radmeas.2008.06.002Open DOISearch in Google Scholar
Tribolo C, Kreutzer S and Mercier N, 2019. How reliable are our beta-source calibrations? Ancient TL, 37(1): 1–10.TriboloCKreutzerSMercierN2019How reliable are our beta-source calibrations?371110Search in Google Scholar
Zimmerman DW, 1971. Thermoluminescent dating using fine grains from pottery. Archaeometry 13(1): 29–52.ZimmermanDW1971Thermoluminescent dating using fine grains from pottery131295210.1111/j.1475-4754.1971.tb00028.xSearch in Google Scholar
Zimmerman DW, 1972. Relative thermoluminescence effects of alpha- and beta-irradiation. Radiation Effects 14: 81–92, DOI:10.1080/00337577208230476.ZimmermanDW1972Relative thermoluminescence effects of alpha- and beta-irradiation14819210.1080/00337577208230476Open DOISearch in Google Scholar