Development of a steady detonation reactor with state-to-state thermochemical modeling (English)
- New search for: Vargas, J.
- Further information on Vargas, J.:
- https://orcid.org/0000-0002-5909-1512
- New search for: Mével, R.
- Further information on Mével, R.:
- https://orcid.org/0000-0002-0032-350X
- New search for: Lino da Silva, M.
- Further information on Lino da Silva, M.:
- https://orcid.org/0000-0002-1993-1548
- New search for: Lacoste, D. A.
- Further information on Lacoste, D. A.:
- https://orcid.org/0000-0002-4160-4762
- New search for: Vargas, J.
- Further information on Vargas, J.:
- https://orcid.org/0000-0002-5909-1512
- New search for: Mével, R.
- Further information on Mével, R.:
- https://orcid.org/0000-0002-0032-350X
- New search for: Lino da Silva, M.
- Further information on Lino da Silva, M.:
- https://orcid.org/0000-0002-1993-1548
- New search for: Lacoste, D. A.
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In:
Shock Waves
;
32
, 8
; 679-689
;
2022
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ISSN:
- Article (Journal) / Electronic Resource
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Title:Development of a steady detonation reactor with state-to-state thermochemical modeling
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Contributors:Vargas, J. ( author ) / Mével, R. ( author ) / Lino da Silva, M. ( author ) / Lacoste, D. A. ( author )
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Published in:Shock Waves ; 32, 8 ; 679-689
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Publisher:
- New search for: Springer Berlin Heidelberg
- New search for: Springer
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Place of publication:Berlin
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Publication date:2022
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ISSN:
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ZDBID:
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DOI:
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Type of media:Article (Journal)
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Type of material:Electronic Resource
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Language:English
- New search for: 50.33
- Further information on Basic classification
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Keywords:
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Classification:
BKL: 50.33 Technische Strömungsmechanik -
Source:
Table of contents – Volume 32, Issue 8
The tables of contents are generated automatically and are based on the data records of the individual contributions available in the index of the TIB portal. The display of the Tables of Contents may therefore be incomplete.
- 679
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Development of a steady detonation reactor with state-to-state thermochemical modelingVargas, J. / Mével, R. / Lino da Silva, M. / Lacoste, D. A. et al. | 2022
- 691
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Shock ignition of aluminium particle clouds in the low-temperature regimeOmang, M. / Hauge, K. O. et al. | 2022
- 703
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Characterization of blast waves using solid and gaseous explosives: application to dynamic buckling of cylindrical shellsThierry, V. / Tang, B. / Joffrin, P. / Bui, T.-T. / Berthet-Rambaud, P. / Limam, A. et al. | 2022
- 715
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Shock wave response of porous carbon fiber–epoxy compositeMochalova, V. / Utkin, A. / Sosikov, V. / Yakushev, V. / Zhukov, A. et al. | 2022
- 727
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Improved shock-reloading technique for dynamic yield strength measurementsLi, X. / Duan, Z. / Nan, X. / Gan, Y. / Yu, Y. / Hu, J. et al. | 2022
- 733
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The effect of increasing rarefaction on the formation of Edney shock interaction patterns: type-I to type-VIAgir, M. B. / White, C. / Kontis, K. et al. | 2022
- 753
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Free-standing conical shockMölder, S. / Timofeev, E. et al. | 2022
- 759
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Thermo-chemical analyses of steady detonation wave using the Shock and Detonation Toolbox in CanteraLi, Z. / Weng, Z. / Mével, R. et al. | 2022