### Abstract

The thermon gas may be seen as the main thermal-energy carrier in heat conduction. Consider phonons, which are defined as the energy quanta for quantized lattice vibrationss, and the phonon gas, which consists of a large number of randomly moving phonons. In the same way, a thermon in gas and metal is defined as the equivalent mass of thermal energy of a gas molecule or an electron, respectively, and the thermon gas consists of a large number of randomly moving thermons. Like the phonon and the photon, the rest mass of a thermon is zero. Because the mass of a moving thermon changes continuously, the thermon may be regarded as a nonquantized quasiparticle. Thus, heat flux can be seen as the directional flow of the thermon gas due to a given temperature gradient. The thermon mass is m_{h}=E/c^{2}, where E is the thermal energy and c is the speed of light, and the thermon gas is actually a compressible gas flow with real mass. According to the principle of aerodynamics, the state equations of a thermon gas in either gas or metal are obtained by different statistical functions. Furthermore, Newtonian mechanics may be applied to obtain the momentum-conservation equation of a thermon gas, which is actually the general heat-conduction law, and which reduces to Fourier's law when thermal inertia is negligible. The general heat-conduction law is a damped wave equation that can be used to quantitatively investigate thermal wave phenomena caused by heating of thin metal films by ultrafast laser pulses. The numerical solution of the general heat-conduction law is obtained using a finite-difference method with double precision, and the results show that the thermal wave increases as the spatial inertia of the thermon gas increases.

Original language | English |
---|---|

Pages (from-to) | 3350-3355 |

Number of pages | 6 |

Journal | Chinese Science Bulletin |

Volume | 55 |

Issue number | 29 |

DOIs | |

Publication status | Published - Oct 1 2010 |

Externally published | Yes |

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### All Science Journal Classification (ASJC) codes

- General

### Cite this

*Chinese Science Bulletin*,

*55*(29), 3350-3355. https://doi.org/10.1007/s11434-010-4036-0

**Thermon gas as the thermal energy carrier in gas and metals.** / Wang, Hai Dong; Guo, Zeng Yuan.

Research output: Contribution to journal › Article

*Chinese Science Bulletin*, vol. 55, no. 29, pp. 3350-3355. https://doi.org/10.1007/s11434-010-4036-0

}

TY - JOUR

T1 - Thermon gas as the thermal energy carrier in gas and metals

AU - Wang, Hai Dong

AU - Guo, Zeng Yuan

PY - 2010/10/1

Y1 - 2010/10/1

N2 - The thermon gas may be seen as the main thermal-energy carrier in heat conduction. Consider phonons, which are defined as the energy quanta for quantized lattice vibrationss, and the phonon gas, which consists of a large number of randomly moving phonons. In the same way, a thermon in gas and metal is defined as the equivalent mass of thermal energy of a gas molecule or an electron, respectively, and the thermon gas consists of a large number of randomly moving thermons. Like the phonon and the photon, the rest mass of a thermon is zero. Because the mass of a moving thermon changes continuously, the thermon may be regarded as a nonquantized quasiparticle. Thus, heat flux can be seen as the directional flow of the thermon gas due to a given temperature gradient. The thermon mass is mh=E/c2, where E is the thermal energy and c is the speed of light, and the thermon gas is actually a compressible gas flow with real mass. According to the principle of aerodynamics, the state equations of a thermon gas in either gas or metal are obtained by different statistical functions. Furthermore, Newtonian mechanics may be applied to obtain the momentum-conservation equation of a thermon gas, which is actually the general heat-conduction law, and which reduces to Fourier's law when thermal inertia is negligible. The general heat-conduction law is a damped wave equation that can be used to quantitatively investigate thermal wave phenomena caused by heating of thin metal films by ultrafast laser pulses. The numerical solution of the general heat-conduction law is obtained using a finite-difference method with double precision, and the results show that the thermal wave increases as the spatial inertia of the thermon gas increases.

AB - The thermon gas may be seen as the main thermal-energy carrier in heat conduction. Consider phonons, which are defined as the energy quanta for quantized lattice vibrationss, and the phonon gas, which consists of a large number of randomly moving phonons. In the same way, a thermon in gas and metal is defined as the equivalent mass of thermal energy of a gas molecule or an electron, respectively, and the thermon gas consists of a large number of randomly moving thermons. Like the phonon and the photon, the rest mass of a thermon is zero. Because the mass of a moving thermon changes continuously, the thermon may be regarded as a nonquantized quasiparticle. Thus, heat flux can be seen as the directional flow of the thermon gas due to a given temperature gradient. The thermon mass is mh=E/c2, where E is the thermal energy and c is the speed of light, and the thermon gas is actually a compressible gas flow with real mass. According to the principle of aerodynamics, the state equations of a thermon gas in either gas or metal are obtained by different statistical functions. Furthermore, Newtonian mechanics may be applied to obtain the momentum-conservation equation of a thermon gas, which is actually the general heat-conduction law, and which reduces to Fourier's law when thermal inertia is negligible. The general heat-conduction law is a damped wave equation that can be used to quantitatively investigate thermal wave phenomena caused by heating of thin metal films by ultrafast laser pulses. The numerical solution of the general heat-conduction law is obtained using a finite-difference method with double precision, and the results show that the thermal wave increases as the spatial inertia of the thermon gas increases.

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U2 - 10.1007/s11434-010-4036-0

DO - 10.1007/s11434-010-4036-0

M3 - Article

VL - 55

SP - 3350

EP - 3355

JO - Science Bulletin

JF - Science Bulletin

SN - 2095-9273

IS - 29

ER -