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V. M. Mostepanenko

Identifiers

  • name variant V. M. Mostepanenko 0.60 · backfill

Papers (130)

  1. The effect of agglomeration of magnetic nanoparticles on the Casimir pressure through a ferrofluid physics.app-ph · 2019 · author #2
  2. Whether an enormously large energy density of the quantum vacuum is catastrophic physics.gen-ph · 2019 · author #1
  3. Fluctuation-induced free energy of thin peptide films physics.app-ph · 2019 · author #3
  4. Impact of magnetic nanoparticles on the Casimir pressure in three-layer systems cond-mat.mes-hall · 2019 · author #2
  5. Low-temperature behavior of the Casimir-Polder free energy and entropy for an atom interacting with graphene quant-ph · 2018 · author #2
  6. Impact of chemical potential on the reflectance of graphene in the infrared and microwave domains cond-mat.mes-hall · 2018 · author #2
  7. Graphene may help to solve the Casimir conundrum in indium tin oxide systems cond-mat.other · 2018 · author #2
  8. Optical chopper driven by the Casimir force physics.optics · 2018 · author #2
  9. Maximum reflectance and transmittance of films coated with gapped graphene in the context of Dirac model cond-mat.mes-hall · 2018 · author #2
  10. Kramers-Kronig relations and causality conditions for graphene in the framework of the Dirac model cond-mat.mes-hall · 2018 · author #2
  11. Reducing detrimental electrostatic effects in Casimir-force measurements and Casimir-force-based microdevices quant-ph · 2018 · author #3
  12. Influence of chemical potential on the Casimir-Polder interaction between an atom and gapped graphene or graphene-coated substrate cond-mat.mes-hall · 2018 · author #3
  13. Nonperturbative theory of atom-surface interaction: Corrections at short separations quant-ph · 2018 · author #3
  14. Conductivity of graphene in the framework of Dirac model: Interplay between nonzero mass gap and chemical potential cond-mat.mes-hall · 2017 · author #2
  15. Thermal effect in the Casimir force for graphene and graphene-coated substrates: Impact of nonzero mass gap and chemical potential cond-mat.other · 2017 · author #3
  16. How to observe the giant thermal effect in the Casimir force for graphene systems cond-mat.mes-hall · 2017 · author #3
  17. Universal experimental test for the role of free charge carriers in thermal Casimir effect within a micrometer separation range cond-mat.other · 2017 · author #3
  18. Casimir free energy of dielectric films: Classical limit, low-temperature behavior and control cond-mat.mtrl-sci · 2017 · author #2
  19. Constraints on axion-like particles and non-Newtonian gravity from measuring the difference of Casimir forces hep-ph · 2017 · author #2
  20. Low-temperature behavior of the Casimir free energy and entropy of metallic films quant-ph · 2017 · author #2
  21. Optical properties of dielectric plates coated with gapped graphene cond-mat.mtrl-sci · 2017 · author #2
  22. Quantum electrodynamic approach to the conductivity of gapped graphene cond-mat.mes-hall · 2016 · author #2
  23. Nernst heat theorem for the thermal Casimir interaction between two graphene sheets quant-ph · 2016 · author #3
  24. Constraining axion coupling constants from measuring the Casimir interaction between polarized test bodies hep-ph · 2016 · author #3
  25. Casimir free energy and pressure for magnetic metal films quant-ph · 2016 · author #2
  26. Conductivity of pure graphene: Theoretical approach using the polarization tensor cond-mat.mtrl-sci · 2016 · author #2
  27. A few remarks on the relationship between elementary particle physics, gravitation and cosmology physics.hist-ph · 2016 · author #1
  28. Reflectivity properties of graphene with nonzero mass-gap parameter cond-mat.mes-hall · 2016 · author #2
  29. Comment on "Lifshitz-Matsubara sum formula for the Casimir pressure between magnetic metallic mirrors" quant-ph · 2016 · author #2
  30. Characteristic properties of the Casimir free energy for metal films deposited on metallic plates quant-ph · 2016 · author #2
  31. Progress in constraining axion and non-Newtonian gravity from the Casimir effect hep-ph · 2016 · author #1
  32. The van der Waals and Casimir energy of anisotropic atomically thin metallic films cond-mat.other · 2015 · author #2
  33. Casimir free energy of metallic films: Discriminating between Drude and plasma model approaches quant-ph · 2015 · author #2
  34. Casimir and van der Waals forces: Advances and problems quant-ph · 2015 · author #2
  35. Special features of the thermal Casimir effect across a uniaxial anisotropic film quant-ph · 2015 · author #1
  36. Origin of large thermal effect in the Casimir interaction between two graphene sheets cond-mat.other · 2015 · author #2
  37. Improved constraints on the coupling constants of axion-like particles to nucleons from recent Casimir-less experiment hep-ph · 2015 · author #2
  38. Constraints on axion and corrections to Newtonian gravity from the Casimir effect hep-ph · 2015 · author #2
  39. Quantum field theoretical description for the reflectivity of graphene cond-mat.mes-hall · 2015 · author #3
  40. Comparison of hydrodynamic model of graphene with recent experiment on measuring the Casimir interaction cond-mat.other · 2015 · author #2
  41. How to confirm and exclude different models of material properties in the Casimir effect quant-ph · 2014 · author #1
  42. Constraints on axion-nucleon coupling constants from measuring the Casimir force between corrugated surfaces hep-ph · 2014 · author #3
  43. Impact of graphene coating on the atom-plate interaction quant-ph · 2014 · author #2
  44. Observability of thermal effects in the Casimir interaction from graphene-coated substrates quant-ph · 2014 · author #2
  45. New constraints on the Yukawa-type corrections to Newtonian gravity at short separations hep-ph · 2014 · author #2
  46. Theory of the Casimir interaction for graphene-coated substrates using the polarization tensor and comparison with experiment cond-mat.other · 2014 · author #3
  47. Constraining axion-nucleon coupling constants from measurements of effective Casimir pressure by means of micromachined oscillator hep-ph · 2014 · author #3
  48. Stronger constraints on axion from measuring the Casimir interaction by means of dynamic atomic force microscope hep-ph · 2014 · author #3
  49. Constraints on the parameters of axion from measurements of thermal Casimir-Polder force hep-ph · 2014 · author #3
  50. Two approaches for describing the Casimir interaction with graphene: density-density correlation function versus polarization tensor cond-mat.other · 2014 · author #2
  51. Classical Casimir-Polder force between polarizable microparticles and thin films including graphene cond-mat.other · 2014 · author #2
  52. Classical limit of the Casimir interaction for thin films with applications to graphene cond-mat.other · 2013 · author #2
  53. Investigation of the Casimir interaction between two magnetic metals in comparison with nonmagnetic test bodies cond-mat.other · 2013 · author #3
  54. Casimir interaction at liquid nitrogen temperature: Comparison between experiment and theory cond-mat.other · 2013 · author #4
  55. Constraints on corrections to Newtonian gravity from two recent measurements of the Casimir interaction between metallic surfaces gr-qc · 2013 · author #3
  56. Van der Waals and Casimir interactions between two graphene sheets cond-mat.mes-hall · 2013 · author #2
  57. Measuring the Casimir force gradient from graphene on a SiO_2 substrate cond-mat.other · 2013 · author #6
  58. Demonstration of the Casimir force between ferromagnetic surfaces of a Ni-coated sphere and a Ni-coated plate cond-mat.other · 2012 · author #3
  59. Thermal Casimir effect in the interaction of graphene with dielectrics and metals cond-mat.mtrl-sci · 2012 · author #3
  60. How to modify the van der Waals and Casimir forces without change of dielectric permittivity cond-mat.other · 2012 · author #3
  61. Comment on "Casimir Force and In Situ Surface Potential Measurements on Nanomembranes" quant-ph · 2012 · author #3
  62. Thermal Casimir-Polder interaction of different atoms with graphene quant-ph · 2012 · author #3
  63. Measurement of the gradient of the Casimir force between a nonmagnetic sphere and a magnetic plate cond-mat.other · 2012 · author #4
  64. Gradient of the Casimir force between Au surfaces of a sphere and a plate measured using atomic force microscope in a frequency shift technique cond-mat.other · 2012 · author #5
  65. Comparison between experiment and theory for the thermal Casimir force quant-ph · 2012 · author #3
  66. Observation of reduction in Casimir force without change of dielectric permittivity quant-ph · 2012 · author #5
  67. New constraints on Yukawa-type interactions from the Casimir effect hep-ph · 2012 · author #1
  68. Modifying the Casimir force between indium tin oxide film and Au sphere quant-ph · 2012 · author #5
  69. Thermal Casimir effect for neutrino and electromagnetic fields in closed Friedmann cosmological model gr-qc · 2011 · author #2
  70. The Casimir force between a microfabricated elliptic cylinder and a plate quant-ph · 2011 · author #6
  71. Observation of the Thermal Casimir Force is Open to Question quant-ph · 2011 · author #5
  72. Reduction of the Casimir force from indium tin oxide film by UV treatment quant-ph · 2011 · author #4
  73. Control of the Casimir Force Using Semiconductor Test Bodies cond-mat.mtrl-sci · 2011 · author #3
  74. Constraints on non-Newtonian gravity from measuring the Casimir force in a configuration with nanoscale rectangular corrugations hep-ph · 2011 · author #3
  75. Impact of surface imperfections on the Casimir force for lenses of centimeter-size curvature radii cond-mat.other · 2011 · author #4
  76. What is credible and what is incredible in the measurements of the Casimir force quant-ph · 2010 · author #2
  77. Comment on "Temperature dependence of the Casimir force for lossy bulk media" quant-ph · 2010 · author #3
  78. Possibility of measuring the thermal Casimir interaction between a plate and a cylinder attached to a micromachined oscillator quant-ph · 2010 · author #6
  79. Possibility to measure thermal effects in the Casimir force cond-mat.mtrl-sci · 2010 · author #3
  80. Lateral Casimir force between sinusoidally corrugated surfaces: Asymmetric profiles, deviations from the proximity force approximation and comparison with exact theory quant-ph · 2010 · author #4
  81. Magnetic materials and the problem of thermal Casimir force cond-mat.other · 2010 · author #3
  82. On the definition of dielectric permittivity for media with temporal dispersion in the presence of free charge carriers quant-ph · 2009 · author #4
  83. Why Screening Effects Do Not Influence the Casimir Force quant-ph · 2009 · author #1
  84. Problems in the Lifshitz Theory of Atom-Wall Interaction quant-ph · 2009 · author #3
  85. Capacitance measurements and electrostatic calibrations in experiments measuring the Casimir force quant-ph · 2009 · author #7
  86. The impact of magnetic properties on atom-wall interaction quant-ph · 2009 · author #3
  87. Application of the proximity force approximation to gravitational and Yukawa-type forces quant-ph · 2009 · author #6
  88. Experiment, theory and the Casimir effect quant-ph · 2009 · author #1
  89. The Casimir force between real materials: experiment and theory cond-mat.other · 2009 · author #3
  90. Comment on "Application of the Lifshitz theory to poor conductors" [arXiv:0809.3901] cond-mat.mtrl-sci · 2008 · author #3
  91. Comment on "Contribution of drifting carriers to the Casimir-Lifshitz and Casimir-Polder interactions with semiconductor materials" quant-ph · 2008 · author #8
  92. Comment on "Thermal Lifshitz force between an atom and a conductor with a small density of carriers" quant-ph · 2008 · author #4
  93. Comment on "Anomalous temperature dependence of the Casimir force for thin metal films" [arXiv:0712.1395] cond-mat.other · 2008 · author #3
  94. Lifshitz theory of atom-wall interaction with applications to quantum reflection quant-ph · 2008 · author #3
  95. Comment on "Anomalies in electrostatic calibration for the measurement of the Casimir force in a sphere-plane geometry" quant-ph · 2008 · author #7
  96. Thermal Casimir effect in ideal metal rectangular boxes quant-ph · 2008 · author #3
  97. Comment on "Possible resolution of the Casimir force finite temperature correction "controversies"" quant-ph · 2008 · author #8
  98. Casimir-Polder force between an atom and a dielectric plate: thermodynamics and experiment quant-ph · 2008 · author #3
  99. New approach to the thermal Casimir force between real metals quant-ph · 2008 · author #1
  100. Conductivity of dielectric and thermal atom-wall interaction quant-ph · 2008 · author #2
  101. Generalized plasma-like permittivity and thermal Casimir force between real metals quant-ph · 2007 · author #3
  102. Thermal correction to the Casimir force, radiative heat transfer, and an experiment quant-ph · 2007 · author #4
  103. Comment on ``Precision measurement of the Casimir-Lifshitz force in a fluid'' physics.atom-ph · 2007 · author #4
  104. Control of the Casimir force by the modification of dielectric properties with light cond-mat.stat-mech · 2007 · author #3
  105. Pulsating Casimir force quant-ph · 2007 · author #3
  106. Experimental approaches to the difference in the Casimir force through the varying optical properties of boundary surface quant-ph · 2007 · author #5
  107. Experiment and theory in the Casimir effect quant-ph · 2006 · author #2
  108. Comment on "Effects of spatial dispersion on electromagnetic surface modes and on modes associated with a gap between two half spaces" quant-ph · 2006 · author #2
  109. Experimental test for the conductivity properties from the Casimir force between metal and semiconductor quant-ph · 2006 · author #4
  110. Universal behavior of dispersion forces between two dielectric plates in the low-temperature limit quant-ph · 2006 · author #3
  111. Casimir-Polder interaction between an atom and a cylinder with application to nanosystems quant-ph · 2006 · author #3
  112. Thermal quantum field theory and the Casimir interaction between dielectrics quant-ph · 2005 · author #3
  113. Thermal corrections in Casimir interaction between metal and dielectric quant-ph · 2005 · author #3
  114. Casimir Effect as a Test for Thermal Corrections and Hypothetical Long-Range Interactions quant-ph · 2005 · author #6
  115. Investigation of the Casimir force between metal and semiconductor test bodies quant-ph · 2005 · author #4
  116. Precise comparison of theory and new experiment for the Casimir force leads to stronger constraints on thermal quantum effects and long-range interactions quant-ph · 2005 · author #6
  117. Some Mathematical Aspects of the Lifshitz Formula for the Thermal Casimir Force quant-ph · 2005 · author #1
  118. Dependences of the van der Waals atom-wall interaction on atomic and material properties quant-ph · 2005 · author #3
  119. Van der Waals interaction between microparticle and uniaxial crystal with application to hydrogen atoms and multiwall carbon nanotubes quant-ph · 2005 · author #3
  120. On the control of the lateral Casimir force between corrugated surfaces quant-ph · 2004 · author #4
  121. Casimir-Polder interaction between an atom and a cavity wall under the influence of real conditions quant-ph · 2004 · author #3
  122. Theory confronts experiment in the Casimir force measurements: quantification of errors and precision quant-ph · 2004 · author #4
  123. Violation of the Nernst heat theorem in the theory of thermal Casimir force between Drude metals quant-ph · 2004 · author #3
  124. Constraints on Non-Newtonian Gravity from Recent Casimir Force Measurements gr-qc · 2003 · author #1
  125. Improved tests of extra-dimensional physics and thermal quantum field theory from new Casimir force measurements hep-ph · 2003 · author #6
  126. Correlation of energy and free energy for the thermal Casimir force between real metals quant-ph · 2002 · author #3
  127. Demonstration of the Lateral Casimir Force quant-ph · 2002 · author #4
  128. New constraints on ultrashort-ranged Yukawa interactions from atomic force microscopy hep-ph · 2001 · author #3
  129. Casimir force at both non-zero temperature and finite conductivity quant-ph · 2000 · author #4
  130. New constraints for non-Newtonian gravity in nanometer range from the improved precision measurement of the Casimir force hep-ph · 2000 · author #4

Mentions

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Frequent Coauthors