Obstructed Breakup of Slender Drops in a Microfluidic Junction
Physical review letters, 2012•APS
In this Letter we present a theoretical analysis of the droplet breakup with “permanent
obstruction” in<? format?> a microfluidic T junction [M.-C. Jullien et al., Phys. Fluids 21,
072001 (2009) PHFLE6 1070-6631 10.1063/1.3170983]. The proposed theory is based on
a simple geometric construction for the interface shape combined with Tanner's law for
the<? format?> local contact angle. The resulting scaling of the droplet deformation with time
and capillary number is in excellent agreement with the results of direct numerical …
obstruction” in<? format?> a microfluidic T junction [M.-C. Jullien et al., Phys. Fluids 21,
072001 (2009) PHFLE6 1070-6631 10.1063/1.3170983]. The proposed theory is based on
a simple geometric construction for the interface shape combined with Tanner's law for
the<? format?> local contact angle. The resulting scaling of the droplet deformation with time
and capillary number is in excellent agreement with the results of direct numerical …
In this Letter we present a theoretical analysis of the droplet breakup with “permanent obstruction” in <?format ?>a microfluidic junction [M.-C. Jullien et al., Phys. Fluids 21, 072001 (2009)PHFLE61070-663110.1063/1.3170983]. The proposed theory is based on a simple geometric construction for the interface shape combined with Tanner’s law for the <?format ?>local contact angle. The resulting scaling of the droplet deformation with time and capillary number is in excellent agreement with the results of direct numerical simulations and prior experiments. More rigorous analysis based on the lubrication approximation reveals a self-similar behavior analogous to the classical problem of a droplet spreading over a preexisting liquid film.
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