Kirby Research Group at Cornell: Microfluidics and Nanofluidics :

Cornell University, College of Engineering

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Cornell Micro/Nanofluidics Laboratory

The Micro/Nanofluidics Laboratory, directed by Professor Brian Kirby, is a research group in the Sibley School of Mechanical and Aerospace Engineering at Cornell University devoted to research on understanding and application of micro- and nanofluidic systems. Micro-and Nanofluidics describe fluidic regimes defined by the length scale of the flow channels, the techniques for making the devices, and the dominant physics.

Features

Kirby Lab Microfluidics Nanofluidics electromechanics in tissue-engineered scaffolds

Engineering better cartilage
How we combine microfabrication and electrokinetics to engineer electromechanical properties in cartilage tissue engineering scaffolds

Kirby Lab microfluidics for processing nanofibers

Weaving the next generation of nanofiber textiles
How microfluidic flow control enables materials characterization in nanofibers

Patterned surface microstructures
Studying neurobiology with microfluidic tools

News

Kirby to speak at Berkeley Nanosci. and Nanoeng. Institute 4 Dec 2009

Kirby to speak at Stanford Mechanical Engineering Dept 3 Dec 2009

Cornell wins $13M NIH Cancer center

Christiansen and Berglund win undergraduate research awards

Five abstracts to be presented at uTAS in Jeju, Korea

Hawkins to present at BMES

Kirby to speak at Texas

Kondapalli reports on measurements of protein folding in microdevices

Tandon reports on electrokinetic transients on hydrophobic substrates

Tandon appointed 2009 GK-12 Fellow in Biomedical Engineering

Pratt, Huang, and Barbati win NSF awards


	Vishal presents his work on interfacial potentials in hydrophobic microsystems at MicroTAS 2008 in San Diego.

	Stress-strain curve of tissue-engineered scaffolds used for seeding chondrocytes. We are designing biomaterials with controlled material properties so as to enable studies of mechanotransduction in chondrocytes during physiological loading.


	Double layer overlap in nanochannels. The interplay of shielding ion layers in nanoscale channels is a hallmark of nanofluidics, one of our key research interests.