L. He and F. Riz, Effect of cavitation on flow and turbulence in plain orifices for high-speed atomization, Atomization and Sprays, vol.5, pp.569-584, 1995.

A. Sou, S. Hosokawa, and A. Tomiyama, Effects of cavitation in a nozzle on liquid jet atomization, Int. Journ Heat and Mass Transfer, vol.50, pp.3575-3582, 2007.

C. Dumouchel, Liquid atomization and spray: A multi-scale description, Keynote Lecture ASME-FEDSM, FEDSM2017-69590, pp.1-12, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01621280

A. Sou, R. H. Pratama, T. Tomisaka, and Y. Kibayashi, Caviatation flow in nozzle of liquid injector, ICLASS 2012, 2012.

C. Dumouchel, J. B. Blaisot, E. Bouche, T. Ménard, and T. Vu, Multi-scale analysis of atomizing liquid ligaments, Int. Journ. Multiphase Flows, vol.73, pp.251-263, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01612376

N. Fdida and J. Blaisot, Drop size distribution measured by imaging: determination of the measurement volume by the calibration of the point spread function, Measurement Science and Technology, vol.21, p.25501, 2009.

C. Dumouchel, References Textural atomization designates the production of liquid drops from the peeling off of liquid gas interfaces. This mechanism is usually observed in the near nozzle region and is often associated with a significant level of turbulence in the flow issuing from the injector, Particle & Particle Systems Characterization, vol.23, pp.468-479, 2006.

, This work characterizes the textural atomization of a flow issuing from a so-called 2D atomizer in which cavitation develops as the flow rate increases. The experimental work shows visualizations of the flow inside the discharge orifice and the textural atomization process in the near nozzle region. Internal velocity fields obtained by LDV measurements are presented. A multi-scale analyzing tool [3] is applied to describe the textural atomization process. This analysis reports an evolution of the textural atomization liquid structures and of their deformation as cavitation effects increase