Physics:Thermomass theory

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The thermomass theory was proposed by Guo Zengyuan.[1] [2] [3] [4] [5]

Recently the thermomass theory has been compared with the extended irreversible thermodynamics and phonon hydrodynamics theory. As a statistic foundation,[6] it has been found that the convective term in the generalized heat conduction equation based on thermomass theory actually comes from the nonlinear part of the phonon distribution function, thus the derivation can be regarded as a nonlinear solution of the phonon Boltzmann equation, which extends the content of the GK model. For nonequilibrium thermodynamics the thermomass theory presents a modification of the entropy and entropy production, avoiding the paradox of negative entropy production in heat wave propagation.[7][8] Furthermore, the entropy production originates from the establishment of Onsager reciprocal relations. So the validation of the reciprocal relation is also made from a thermomass perspective. The concept of generalized forces and fluxes are clarified to remove the controversy of the proof of reciprocal relations, i.e. whether or not the generalized flux can be expressed as the time derivative of certain state variables.[9]

See also

References

  1. Guo, Z.Y. (2006). "Motion and transfer of thermal mass-Thermal mass and thermon gas". Journal of Engineering Thermophysics 27 (4): 631–634. 
  2. Wang, Moran; Cao, Bin-Yang; Guo, Zeng-Yuan (2010). "General Heat Conduction Equations Based on the Thermomass Theory". Frontiers in Heat and Mass Transfer 1 (1). doi:10.5098/hmt.v1.1.3004. 
  3. Guo, Z.Y.; Zhu, H.Y. (2007). "Motion and transfer of thermal mass-conservation equations of thermon gas and Fourier's law". Journal of Engineering Thermophysics 28 (1): 86–88. 
  4. Guo, Zeng-Yuan; Hou, Quan-Wen (2010-04-29). "Thermal Wave Based on the Thermomass Model". Journal of Heat Transfer 132 (7): 072403. doi:10.1115/1.4000987. ISSN 0022-1481. 
  5. Wang, Moran; Guo, Zeng-Yuan (2010-09-20). "Understanding of temperature and size dependences of effective thermal conductivity of nanotubes". Physics Letters A 374 (42): 4312–4315. doi:10.1016/j.physleta.2010.08.058. Bibcode2010PhLA..374.4312W. https://zenodo.org/record/1259313. 
  6. Dong, Yuan; Cao, Bing-Yang; Guo, Zeng-Yuan (2011). "Generalized heat conduction laws based on thermomass theory and phonon hydrodynamics". Journal of Applied Physics 110 (6): 063504–063504–6. doi:10.1063/1.3634113. Bibcode2011JAP...110f3504D. 
  7. Dong, Y.; Guo, Z. Y. (2011-04-01). "Entropy analyses for hyperbolic heat conduction based on the thermomass model". International Journal of Heat and Mass Transfer 54 (9–10): 1924–1929. doi:10.1016/j.ijheatmasstransfer.2011.01.011. 
  8. Dong, Yuan (2012-01-01). "General expression for entropy production in transport processes based on the thermomass model". Physical Review E 85 (6): 061107. doi:10.1103/PhysRevE.85.061107. PMID 23005051. Bibcode2012PhRvE..85f1107D. 
  9. Dong, Yuan (2012-01-01). "Clarification of Onsager reciprocal relations based on thermomass theory". Physical Review E 86 (6): 062101. doi:10.1103/PhysRevE.86.062101. PMID 23367986. Bibcode2012PhRvE..86f2101D. 

External links

  • [1] - New Concept Heat & Thermomass Theory website




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