Nano- and Microfluidics
Welcome to the pages of the Institute for Nano- and Microfluidics. Please do not hesitate to contact us if you have any suggestions, proposals for co-operations or questions of any kind.
We are concerned with transport phenomena in fluids on the nano- and micrometer scale. In that context we are especially interested in studying fundamentals, with the intention to pave the way for novel applications. Our research extends over a broad thematic spectrum and combines experimental, theoretical and numerical approaches. Nanoscale gas kinetics, electrokinetics, interfacial flows, wetting phenomena and biomolecular separation belong to our areas of work.
April 10, 2017
Fulbright Fellow Professor Prashanta Dutta
Prof. Prashanta Dutta (http://www.mme.wsu.edu/people/faculty/faculty.html?duttaP) has come to the TU Darmstadt with a Fulbright grant from the United States (US) government to collaborate with researchers at the Institute for Nano- and Microfluidics on electric field driven transport in micro- and nanodevices. The Fulbright program is the flagship international educational exchange initiative sponsored by the United State government and the primary goal of his visit is to develop a long-term collaborative relationship between US and German researchers in the micro/nano/biofluidics area.
January 27, 2017
Knudsen pump inducing gas flow normal to temperature gradient
Knudsen pumps transport gas by exploiting temperature variations imposed by the channel boundaries, offering the advantage of not containing any moving parts. We analyzed a Knudsen pump with a temperature field generated by an applied temperature difference between the channel walls, where the ratchet-shaped wall is equipped with varying reflection properties on different sections. The figure shows streamlines and velocity magnitudes within a channel bounded by triangular teeth which are half-specularly and half-diffusely reflecting. The use of specularly reflecting patches massively increases the mass flux compared to diffusely reflecting walls.
Reference: V. Shahabi, T. Baier, E. Roohi and S. Hardt, Thermally induced gas flows in ratchet channels with diffuse and specular boundaries, Scientific Reports 7, 41412 (2017); doi:10.1038/srep41412; www.nature.com/articles/srep41412
January 02, 2017
Humboldt Fellow Dr. Aditya Bandopadhyay
On Jan 2, 2017, Dr. Aditya Bandopadhyay has joined our group as a Humboldt postdoctoral fellow. His research interests are electrokinetics, electrohydrodynamics and reactive mixing. Prior to his arrival in Germany, he has completed his education from IIT Kharagpur, India and has undertaken postdoctoral research in Geosciences Rennes, France. We look forward to a productive research collaboration.
Sept 15, 2016
Humboldt Fellow Professor Dominik Barz
On Sept 1, 2016, Professor Dominik Barz of Queen’s University/Canada joined our group. He is supported by the Humboldt Foundation and pursues a research program in the field of electrokinetic flows. We are looking forward to a fruitful co-operation.
July 4, 2016
GIF Research Grant
We have won a research grant by the German Israeli Foundation (GIF). Together with Dr. Moran Bercovici from the Israel Institute of Technology we will study methods for tailoring and reconfiguring complex electroosmotic flow patterns in a channel-free microfluidic device.
June 3, 2016
Thermoelectricity in confined liquid electrolytes
The electric field induced in a bulk phase of a liquid electrolyte exposed to a temperature gradient is attributed to different thermophoretic mobilities of the dissolved ion species. We have shown that such Soret-type ion thermodiffusion is not required to induce thermoelectricity even in the simplest electrolyte if it is confined between walls carrying a charge density. The space charge of the electric double layer leads to selective ion diffusion driven by a temperature-dependent electrophoretic ion mobility, which —for narrow channels— may cause thermovoltages larger in magnitude than for the classical Soret effect. On the left, the corresponding (scaled) Seebeck coefficient is plotted for different values of the surface charge density against the (scaled) channel width.
February 19, 2016
Stokes drag on a sphere translating along a fluid-fluid interface
Presumably the most well-known achievement of George Gabriel Stokes is his formula for the drag force experienced by a sphere translating in an unbounded fluid at low Reynolds numbers. However, in some scenarios small particles are attached to an interface between two immiscible fluids, constrained to tangential motion relative to the interface. We have analyzed this situation and derived a generalization of Stokes’ law for large viscosity contrast and small capillary number. The image at the left is a sketch of the corresponding streamlines.
October 26, 2015
Structuring thin liquid films utilizing the Bénard-Marangoni instability
If a system of two superposed liquid films is exposed to a temperature gradient normal to the films, the upper layer exhibits convection cells which deform the lower thin film in an identical pattern. This effect can be seen in the figure above, which displays the hexagonal convection cells and the humps of the thin film below. The principle could find applications in fabricating regular, highly ordered surface structures.
Reference: I.Nejati, M. Dietzel and S. Hardt, Conjugated liquid layers driven by the short-wavelength Bénard-Marangoni instability: experiment and numerical simulation, J. Fluid Mech., 783 (2015), 46-71
July 01, 2015
Institute for Nano- and Microfluidics participates in LOEWE Cluster CompuGene
Yesterday the government of the federal state of Hessen approved approx. 4.4 million Euros funding for the LOEWE Cluster CompuGene. CompuGene will focus on the development of artificial genetic circuits which may be employed for various purposes, for example for the production of certain rare substances. We will contribute by exploring microfluidic methods for studying genetic circuits in a scenario as close as possible to in vivo conditions.
April 07, 2015
Results on motion of a microsphere along a fluid interface published in Journal of Fluid Mechanics
A microsphere driven along an interface between two fluids of highly different viscosities experiences a drag force differing from the well-known Stokes drag. Additionally, the viscous flow around the moving particle deforms the fluid-fluid interface from its equilibrium shape while the particle assumes a tilted orientation. The figure below depicts a spherical particle with a pinned three-phase contact line moving from left to right with the lower fluid having higher viscosity than the upper. The corresponding deformation of the fluid interface results in a pair interaction between particles.