Vol. 39, issue 07, article # 5

Nosov E. V. Convection in the vicinity of linear extended optical sources. Numerical solutions of the Navier–Stokes equations. II. Vertical configuration. // Optika Atmosfery i Okeana. 2026. V. 39. No. 07. P. 579–586. DOI: 10.15372/AOO20260705 [in Russian].
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Abstract:

The second part of the article continues numerical studies of convective and dynamic turbulence fields in the vicinity of a group of extended inclined linear optical sources. This paper studies convective air motions in the vertical configuration of an open-side room of optical systems under external wind effect. The initial and boundary conditions of the boundary value problem being solved are similar to those for the horizontal configuration; the geometric and energy characteristics of the optical sources are analogous; the composition and scope of the study are the same as in the first part. The similarities and differences between the results for both configurations are shown.

Keywords:

convection, inclined optical beam, thermal trace

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References:

1. Nosov E.V. Konvektsiya v okrestnosti lineinyh protyazhennyh opticheskih istochnikov. CHislennye resheniya uravnenii Nav'e–Stoksa. I. Gorizontal'naya konfiguratsiya // Optika atmosf. i okeana. 2026. V. 39, N 5. P. 382–391.
2. Popinet S. Gerris: A tree-based adaptive solver for the incompressible Euler equations in complex geometries // J. Comput. Phys. 2003. V. 190, N 2. P. 572–600. DOI: 10.1016/S0021-9991(03)00298-5.
3. Zuev V.I. Eksperimental'noe issledovanie neustoichivosti konvektsii, navedennoi lazernym izlucheniem // Zhurn. tehn. fiz. 1986. V. 56, N 2. P. 394–396.
4. Chodzko R.A., Lin S.C. A study of strong thermal interactions between a laser beam and an absorbing gas // AIAA J. 1971. V. 9, N 6. P. 1105–1112.
5. Tatarskii V.I. Rasprostranenie voln v turbulentnoi atmosfere. M.: Nauka, 1967. 548 p.
6. Kolmogorov A.N. Lokal'naya struktura turbulentnosti v neszhimaemoi vyazkoi zhidkosti pri ochen' bol'shih chislah Reinol'dsa // Dokl. AN SSSR. 1941. V. 30, N 4. P. 299–303.
7. Obuhov A.M. O raspredelenii energii v spektre turbulentnogo potoka // Izv. AN SSSR. Ser. geograf. i geofiz. 1941. V. 5, N 4–5. P. 453–466.
8. Monin A.S. O prirode turbulentnosti // Uspehi fiz. nauk. 1978. V. 125, N 5. P. 97–122.
9. Richardson L. Weather Prediction by Numerical Process. Cambridge: The University press, 1922. 262 p. DOI: 10.2307/3603284.
10. Monin A.S. Ob opredelenii kogerentnyh struktur // Dokl. AN SSSR. 1991. V. 318, N 4. P. 853–856.
11. Monin A.S., Yaglom A.M. Statisticheskaya gidromehanika. V. 1. SPb.: Gidrometeoizdat, 1992. 696 p.
12. Obuhov A.M. Techenie Kolmogorova i ego laboratornoe modelirovanie // Uspehi matematicheskih nauk. 1983. V. 38, N 4. P. 232.
13. Nosov V.V., Lukin V.P., Nosov E.V., Torgaev A.V. Opredelenie tipa atmosfernoi turbulentnosti po dannym meteorologicheskih izmerenii, postupayushchim v operativnom rezhime // Optika atmosf. i okeana. 2024. V. 37, N 7. P. 563–571. DOI: 10.15372/AOO20240704; Nosov V.V., Lukin V.P., Nosov E.V., Torgaev A.V. Determination of atmospheric turbulence type from operational meteorological measurements // Atmos. Ocean. Opt. 2024. V. 37, N 5. P. 605–613.
14. Nosov V.V., Lukin V.P., Nosov E.V., Torgaev A.V. Formirovanie turbulentnosti v astronomicheskih observatoriyah yuga Sibiri i Severnogo Kavkaza // Optika atmosf. i okeana. 2019. V. 32, N 3. P. 1–19.