论文信息 - Investigation of a thermoluminescence response and trapping parameters and theoretical model to explain concentration quenching for $$\hbox {Yb}^{3+}$$Yb3+-doped $$\hbox {ZrO}_{{2}}$$ZrO2 phosphors under UV exposure - 字舞流文

Investigation of a thermoluminescence response and trapping parameters and theoretical model to explain concentration quenching for $$\hbox {Yb}^{3+}$$Yb3+-doped $$\hbox {ZrO}_{{2}}$$ZrO2 phosphors under UV exposure

Kanchan Upadhyay | Anupama Asthana | R. Tamrakar

[1] D. P. Bisen,et al. 3T1R model and tuning of thermoluminescence intensity by optimization of dopant concentration in monoclinic Gd2O3:Er3+;Yb3+ co-doped phosphor. , 2017, Physical chemistry chemical physics : PCCP.

[2] S. Sharma,et al. Thermoluminescence glow curve analysis of γ-irradiated Eu3+ doped SnO2 composites , 2016 .

[3] S. C. Sharma,et al. Structural, photoluminescence and thermoluminescence properties of CeO2 nanoparticles , 2016 .

[4] C. Bootjomchai,et al. Thermoluminescence studies on alkali-silicate glass doped with dysprosium oxide for use in radiation dosimetry measurement , 2015 .

[5] L. Escobar-Alarcón,et al. Co nanoparticle effects on the thermoluminescent signal induced by UV and gamma radiation in ZrO2 powders , 2014 .

[6] D. Mendoza-Anaya,et al. Thermoluminescence response induced by Uv radiation in Eu-doped zirconia nanopowders , 2014 .

[7] Pratik Kumar,et al. Synthesis and thermoluminescence characteristics of gamma and proton irradiated nanocrystalline MgB4O7: Dy, Na , 2013 .

[8] S. C. Sharma,et al. Effect of different fuels on structural, thermo and photoluminescent properties of Gd2O3 nanoparticles. , 2012, Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy.

[9] B. Mukherjee,et al. An ultra sensitive fast neutron area monitor using gadolinium covered aluminium oxide dosimeter (TLD-500) chips , 2011 .

[10] Reuven Chen,et al. A model for explaining the concentration quenching of thermoluminescence , 2011 .

[11] Z. Khan,et al. Thermoluminescence and photoluminescence of ZrO2 nanoparticles , 2011 .

[12] S. Lochab,et al. Synthesis and characterization of thermoluminescent Li2B4O7 nanophosphor , 2011 .

[13] T. Karali,et al. Influence of heating rate on thermoluminescence of Mg2SiO4 : Tb dosimeter , 2009 .

[14] A. Pandey,et al. Nanocrystalline MgB4O7:Dy for high dose measurement of gamma radiation , 2007 .

[15] C. Furetta,et al. Preparation of luminescent nanocrystals started from amorphous zirconia prepared by sol–gel technique , 2006 .

[16] C. Furetta,et al. Thermoluminescence characteristics of hydrogenated amorphous zirconia , 2005 .

[17] Chunhua Yan,et al. Doping effects of Yb3+ on the crystal structures, nanoparticle properties and electrical behaviors of ZrO2 derived from a facile urea-based hydrothermal route , 2004 .

[18] S. Aruna,et al. MIXTURE OF FUELS APPROACH FOR THE SOLUTION COMBUSTION SYNTHESIS OF AL2O3–ZRO2 NANOCOMPOSITE , 2004 .

[19] V. Castaño,et al. Monoclinic ZrO2 as a broad spectral response thermoluminescence UV dosemeter , 2003 .

[20] M. Garcı́a,et al. Thermoluminescent response of ZrO2 + PTFE prepared in Mexico to 90Sr/90Y beta particles. , 2002, Radiation protection dosimetry.

[21] F. Hashmi,et al. Thermoluminescence from X-Ray-Irradiated Stabilized ZrO2 Single Crystals , 1977 .