Références

[1] NIST chemistry webbook. Consulté : 13/02/2014.

[2] Air-Liquide : Modélisation des transferts par ébullition dans les réservoirs cryogéniques de lanceurs Ariane V-A5ME ; Marylou Garnier, Zacharie Vatimbella Consulté : 12/03/2014.

[3] Bassenghi, Federica. "Validation of the CFD code NEPTUNE for a full scale simulator for decay heat removal systems with in-pool heat exchangers." (2013).

[4] Dropkin, D., and E. Somerscales. "Heat transfer by natural convection in liquids confined by two parallel plates which are inclined at various angles with respect to the horizontal." Journal of Heat Transfer 87 (1965): 77.

[5] Incropera, Frank P., Adrienne S. Lavine, and David P. DeWitt. Fundamentals of heat and mass transfer. John Wiley & Sons Incorporated, 2011.

[6] Kurul, N., and Mm Z. Podowski. "Multidimensional effects in forced convection subcooled boiling." Proceedings of the Ninth International Heat Transfer Conference. Vol. 2. 1990.

[7] Montout, Michaël. Contribution au développement d'une Approche Prédictive Locale de la crise d'ébullition. Diss. INPT, 2009.

[8] Wright, John L. "A correlation to quantify convective heat transfer between vertical window glazings." TRANSACTIONS-AMERICAN SOCIETY OF HEATING REFRIGERATING AND AIR CONDITIONING ENGINEERS 102 (1996): 940-9

[9] Yeoh, G. H., et al. "Fundamental consideration of wall heat partition of vertical subcooled boiling flows." International Journal of Heat and Mass Transfer 51.15 (2008): 3840-3853.
 
[10] Seiler-Marie, Nathalie. "Modélisation et simulation des phénomènes d'ébullition et du transfert de chaleur dans la zone d'impact d'un jet sur une plaque chaude." (2004).