Oil Conductivity Estimation of Transformer Insulation by Switching Impulse Application. IEEE transactions on dielectrics and electrical insulation, (29)2:420-427, April 2022. [PUMA: Application Conductivity Estimation Impulse Insulation Oil Switching Transformer by of] URL
Experimental Investigation of a Ball Screw for Increasing the Accuracy of Thermal Simulations. Journal of Trends in the Development of Machinery and Associated Technology, (16)1:167-170, 2012. [PUMA: FEA accuracy ball conductivity experiment experimental investigation myown screw simulation test themal] URL
The Investigation of the Temperature and Electric Field Dependency of Mineral Oil Electrical Conductivity. 111, 2013. [PUMA: Conductivity Dependency Electric Electrical Field Mineral Oil Temperature]
Electrical Conductivity Measurement and Determination of Ion Mobility in Insulating Oil. 313-317, 2013. [PUMA: Conductivity Determination Electrical Insulating Ion Measurement Mobility Oil]
Influence of Electrode Material on Conductivity Measurements under DC Stresses. 2014. [PUMA: Conductivity DC Electrode Influence Material Measurements Stresses of on under]
The influence of moisture during the electrical conductivity measurement on the high density impregnated pressboard. University of West Bohemia, Pilsen, 2015. [PUMA: conductivity density electrical high impregnated influence measurement moisture pressboard]
Comparative Study on Impact of Cellulose Particles on Electrical Conductivity of Mineral Oil and Natural Ester. 412-417, 2016. [PUMA: Conductivity Electrical Mineral Oil of]
Study on Moisture Influence on Electrical Conductivity of Natural Ester Fluid and Mineral Oil. 290-293, 2017. [PUMA: Conductivity Electrical Ester Fluid Mineral Natural Oil]
Influence of Cellulose Contamination Level on Electrical Conductivity of Natural and Synthetic Ester Liquids Compared to Mineral Oil. 2017. [PUMA: cellulose conductivity contamination electrival]
Electrical Conductivity of Oil and Oil-impregnated Pressboard dependent on Aging Byproducts. 2017. [PUMA: conductivity electrical of oil]
Infrared conductivity of the organic conductor α-(BEDT-TTF)2KHg(SCN)4. Synthetic Metals 133-134: 91-94, (133-134):91-94, Elsevier BV, March 2003. [PUMA: BEDT-TTF conductivity infrared] URL
DC and high-frequency conductivity of the organic metals β''-(BEDT-TTF)2SF5RSO3(R = CH2CF2 and CHF). Synthetic Metals, (159)11:1043-1049, June 2009. [PUMA: BEDT-TTF conductivity metal organic]
Microwave measurements of the in-plane and c-axis conductivity in HgBa2CuO4+δ: Discriminating between superconducting fluctuations and pseudogap effects. Phys. Rev. B, (80)9:094511, American Physical Society, September 2009. [PUMA: c-axis conductivity in-plane measurements microwave] URL
Microwave conductivity of heavy fermions in UPd2Al3. The European Physical Journal B, (74)3:331-338, March 2010. [PUMA: conductivity fermions heavy]
Terahertz conductivity of the heavy-fermion compound UNi2Al3. Phys. Rev. B, (84)3:035132, American Physical Society, July 2011. [PUMA: UNi2Al3 conductivity] URL
Terahertz conductivity of Sr1-xCaxRuO3. Phys. Rev. B, (93)16:165131, American Physical Society, April 2016. [PUMA: conductivity terahertz] URL
Optical conductivity in multiferroic GaV4S8 and GeV4S8: Phonons and electronic transitions. Phys. Rev. B, (96)14:144302, American Physical Society, October 2017. [PUMA: conductivity phonons] URL
Flat Optical Conductivity in ZrSiS due to Two-Dimensional Dirac Bands. Phys. Rev. Lett., (119)18:187401, American Physical Society, November 2017. [PUMA: Dirac ZrSiS bands conductivity] URL