Advanced search

Browse by subject

Browse by provider

Browse by language

Content Details
Normal View
CIP View

Thermodynamics as a multistep relaxation...

Maslov, V. P....

Free

Share this content

Thermodynamics as a multistep relaxation process and the role of observables in different scales of quantities by Maslov, V. P. ( Author )

Content Provider	Lemonjar Open Access
Publisher	N.A
Publication Date	26-07-2023
Summary	In the first part of the paper, we introduce the concept of observable quantities associated with a macroinstrument measuring the density and temperature and with a microinstrument determining the radius of a molecule and its free path length, and also the relationship between these observable quantities. The concept of the number of degrees of freedom, which relates the observable quantities listed above, is generalized to the case of low temperatures. An analogy between the creation and annihilation operators for pairs (dimers) and the creation and annihilation operators for particles (molecules) is carried out. A generalization of the concept of a Bose condensate is introduced for classical molecules as an analog of an ideal liquid (without attraction). The negative pressure in the liquid is treated as holes (of exciton type) in the density of the Bose condensate. The phase transition gas-liquid is calculated for an ideal gas (without attraction). A comparison with experimental data is carried out. In the other part of the paper, we introduce the concept of new observable quantity, namely, of a pair (a dimer), as a result of attraction between the nearest neighbors. We treat in a new way the concepts of Boyle temperature $T_B$ (as the temperature above which the dimers disappear) and of the critical temperature $T_c$ (below which the trimers and clusters are formed). The equation for the Zeno line is interpreted as the relation describing the dependence of the temperature on the density at which the dimers disappear. We calculate the maximal density of the liquid and also the maximal density of the holes. The law of corresponding states is derived as a result of an observation by a macrodevice which cannot distinguish between molecules of distinct gases, theoretical and experimental data are compared, observations in three scales, macro, micro, and nano, are studied.
ISBN	-
Item Type	Article
File Type	pdf
File Size	37.08 KB
Language	English
Subjects	-
Unlimited	MYR 0.01
Total read	-
URL	http://arxiv.org/abs/1303.5307

Citation

Review the full bibliography data and make any necessary corrections before using. Always consult your library resources for the exact formatting and punctuation guidelines.

AMA 11th EditionReferences

Maslov, V. P.. Thermodynamics as a multistep relaxation process and the role of observables in different scales of quantities. N.A. July 26, 2023. Accessed September 20, 2024. https://online.provdatabase.com/cite/6015

APA 7th EditionReferences

Maslov, V. P.. (2023). Thermodynamics as a multistep relaxation process and the role of observables in different scales of quantities. N.A. https://online.provdatabase.com/cite/6015

Chicago 17th EditionReferences

Maslov, V. P.. Thermodynamics as a multistep relaxation process and the role of observables in different scales of quantities. N.A. 2023. https://online.provdatabase.com/cite/6015

HarvardReferences

Maslov, V. P.. (2023). Thermodynamics as a multistep relaxation process and the role of observables in different scales of quantities. [Online]. N.A. Available from: https://online.provdatabase.com/cite/6015. (Accessed 20 September 2024).

Harvard AustraliaReferences

Maslov, V. P., 2023, Thermodynamics as a multistep relaxation process and the role of observables in different scales of quantities, N.A, viewed 20 September 2024, <https://online.provdatabase.com/cite/6015>

MLA 9th EditionWorks Cited

Maslov, V. P.. Thermodynamics as a multistep relaxation process and the role of observables in different scales of quantities. N.A, 2023. PROV Database, https://online.provdatabase.com/cite/6015.

Share this eBook