Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state

Physics

Text available via DOI:

https://doi.org/10.1103/PhysRevE.105.054133
Final published version
Available under license: CC BY: Creative Commons Attribution 4.0 International License

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Published

Standard

Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state. / Żuk, Paweł J.; Makuch, Karol; Hołyst, Robert et al.
In: Physical Review E, Vol. 105, No. 5, 054133, 23.05.2022.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Żuk, PJ, Makuch, K, Hołyst, R & Maciołek, A 2022, 'Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state', Physical Review E, vol. 105, no. 5, 054133. https://doi.org/10.1103/PhysRevE.105.054133

APA

Żuk, P. J., Makuch, K., Hołyst, R., & Maciołek, A. (2022). Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state. Physical Review E, 105(5), Article 054133. https://doi.org/10.1103/PhysRevE.105.054133

Vancouver

Żuk PJ, Makuch K, Hołyst R, Maciołek A. Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state. Physical Review E. 2022 May 23;105(5):054133. doi: 10.1103/PhysRevE.105.054133

Author

Żuk, Paweł J. ; Makuch, Karol ; Hołyst, Robert et al. / Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state. In: Physical Review E. 2022 ; Vol. 105, No. 5.

Bibtex

@article{139a59c8cc0542f58bfbba74843424fe,

title = "Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state",

abstract = "We investigate the thermal relaxation of an ideal gas from a nonequilibrium stationary state. The gas is enclosed between two walls, which initially have different temperatures. After making one of the walls adiabatic, the system returns to equilibrium. We notice two distinct modes of heat transport and associated timescales: one connected with a traveling heat front and the other with internal energy diffusion. At the heat front, which moves at the speed of sound, pressure, temperature, and density change abruptly, leaving lower values behind. This is unlike a shock wave, a sound wave, or a thermal wave. The front moves multiple times between the walls and is the dominant heat transport mode until surpassed by diffusion. We found that it can constitute an order 1 factor in shaping the dynamics of the outflow of internal energy. We found that cooling such a system is quicker than heating, and that hotter bodies cool down quicker than colder ones. The latter is known as the Mpemba effect.",

author = "{\.Z}uk, {Pawe{\l} J.} and Karol Makuch and Robert Ho{\l}yst and Anna Macio{\l}ek",

year = "2022",

month = may,

day = "23",

doi = "10.1103/PhysRevE.105.054133",

language = "English",

volume = "105",

journal = "Physical Review E",

issn = "1539-3755",

publisher = "American Physical Society",

number = "5",

}

RIS

TY - JOUR

T1 - Transient dynamics in the outflow of energy from a system in a nonequilibrium stationary state

AU - Żuk, Paweł J.

AU - Makuch, Karol

AU - Hołyst, Robert

AU - Maciołek, Anna

PY - 2022/5/23

Y1 - 2022/5/23

N2 - We investigate the thermal relaxation of an ideal gas from a nonequilibrium stationary state. The gas is enclosed between two walls, which initially have different temperatures. After making one of the walls adiabatic, the system returns to equilibrium. We notice two distinct modes of heat transport and associated timescales: one connected with a traveling heat front and the other with internal energy diffusion. At the heat front, which moves at the speed of sound, pressure, temperature, and density change abruptly, leaving lower values behind. This is unlike a shock wave, a sound wave, or a thermal wave. The front moves multiple times between the walls and is the dominant heat transport mode until surpassed by diffusion. We found that it can constitute an order 1 factor in shaping the dynamics of the outflow of internal energy. We found that cooling such a system is quicker than heating, and that hotter bodies cool down quicker than colder ones. The latter is known as the Mpemba effect.

AB - We investigate the thermal relaxation of an ideal gas from a nonequilibrium stationary state. The gas is enclosed between two walls, which initially have different temperatures. After making one of the walls adiabatic, the system returns to equilibrium. We notice two distinct modes of heat transport and associated timescales: one connected with a traveling heat front and the other with internal energy diffusion. At the heat front, which moves at the speed of sound, pressure, temperature, and density change abruptly, leaving lower values behind. This is unlike a shock wave, a sound wave, or a thermal wave. The front moves multiple times between the walls and is the dominant heat transport mode until surpassed by diffusion. We found that it can constitute an order 1 factor in shaping the dynamics of the outflow of internal energy. We found that cooling such a system is quicker than heating, and that hotter bodies cool down quicker than colder ones. The latter is known as the Mpemba effect.

U2 - 10.1103/PhysRevE.105.054133

DO - 10.1103/PhysRevE.105.054133

M3 - Journal article

VL - 105

JO - Physical Review E

JF - Physical Review E

SN - 1539-3755

IS - 5

M1 - 054133

ER -

Research

Links

Text available via DOI: