Insight into the micro scale dynamics of a micro fluidic wetting-based conveying system by particle based simulation

Lienemann, Jan; Weiß, Dennis; Greiner, Andreas; Kauzlarić, David; Grünert, Oliver; Korvink, Jan G.

doi:10.1007/s00542-012-1460-x

Cited by 4 publications

(5 citation statements)

References 42 publications

(35 reference statements)

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“…By accounting for both liquid meniscus' partial wetting of solid surfaces (earlier attempted 26,27 ) and limited angle hysteresis over edges, the model portraits more accurately the behavior of finitely-deformable solid/liquid interfaces. For displacements larger than the elastic limit, we show that this behavior is distinctively characterized by the unpinning of triple contact lines.…”

Section: Introductionmentioning

confidence: 98%

Modeling capillary forces for large displacements

Mastrangeli

Arutinov

Smits

et al. 2014

Microfluid Nanofluid

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Originally applied to the accurate, passive positioning of submillimetric devices, recent works proved capillary self-alignment as effective also for larger components and relatively large initial offsets. In this paper we describe an analytic quasi-static model of 1D capillary restoring forces that generalizes existing geometrical models and extends the validity to large displacements from equilibrium. The piece-wise nature of the model accounts for contact line unpinning singularities ensuing from large perturbations of the liquid meniscus and dewetting of the bounding surfaces. The superior accuracy of the generalized model across the extended displacement range, and particularly beyond the elastic regime as compared to purely elastic models, is supported by finite element simulations and recent experimental evidence. Limits of the model are discussed in relation to the aspect ratio of the meniscus, contact angle hysteresis, tilting and self-alignment dynamics.

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Section: Introductionmentioning

confidence: 98%

Modeling capillary forces for large displacements

Mastrangeli

Arutinov

Smits

et al. 2014

Microfluid Nanofluid

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“…in analogy to (8). This also gives P 0 = P. L is the conventional Liouville operator introduced earlier.…”

Section: Mori Hierarchymentioning

confidence: 86%

“…The term 'coarse-graining' (CG) refers to a collection of methods used to reduce the number of degrees of freedom of complex atomistic systems such as polymers [1,2], proteins [3], fluids [4][5][6][7][8] or combinations thereof. The motivation for doing so is straightforward: computational time can be saved or larger systems over longer time-scales can be approached by keeping only the relevant part of the information.…”

Section: Introductionmentioning

confidence: 99%

Markovian equations of motion for non-Markovian coarse-graining and properties for graphene blobs

et al. 2013

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We obtain Markovian equations of motion for a many body system of interacting coarse-grained (CG) variables and additional fluxes. The investigated CG variables belong to the special family of linear combinations of atomistic degrees of freedom. The system of Markovian equations of motion approximates Mori's exact non-Markovian generalized Langevin equation and is easy to solve by computer simulation. All parameters of the equations can be obtained from equilibrium molecular dynamics simulations of the investigated microscopic system. These parameters are either equal to the famous static covariances from Mori's continued fraction or they represent generalized constant friction matrices. We propose two different ways to compute these friction matrices based on Mori's continued fraction. Finally, some of the parameters are computed numerically for the special case of centre of mass 6

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“…In all these cases particle dynamics was used for an SPH-simulation of the fluid dynamics of the moulded material. Further fluid dynamic applications of SYMPLER have been the simulation and design of electrowetting based microfluidic devices for the transportation of pico-to nanoliter droplets [46,47], constraint SPH-simulations of haemodynamics for the estimation of blood flow measurements with magnetic resonance imaging [48], and hydrodynamics with convective transport and dynamics of local magnetisation [49].…”

Section: Some Application Examplesmentioning

confidence: 99%