Introduction to heterogeneous integration for Nano-Bio-CMOS sensors on Chip.
Understanding and designing of active Bio/CMOS interfaces powered by nanostructures.
This course gives the basics for understanding nanotechnology from an engineer's perspective: physical background, materials aspects and scaling laws, fabrication and imaging of nanoscale devices.
This course concerns modern bioanalytical techniques to investigate biomolecules both in vitro and in vivo, including recent methods to image, track and manipulate single molecules. We cover the basic
The labels "biosensor" and "eBiochip" have been employed to refer to the most diverse systems and in several fields of application. The course is meant not only to provide means to dig into this sea
This course provides practical experience in the numerical simulation of fluid flows. Numerical methods are presented in the framework of the finite volume method. A simple solver is developed with Ma
In this course we study heat transfer (and energy conversion) from a microscopic perspective. First we focus on understanding why classical laws (i.e. Fourier Law) are what they are and what are their
Introduction to the application of the notions and methods of theoretical physics to problems in biology.
This course shows students how the physical principles of conservation, symmetry, and locality influence the dynamics of living organisms at the molecular and cellular level. Computer simulations are
This doctoral class covers the scaling of MEMS devices, including mechanical, thermal, electrostatic, electromagnetic, and microfluidic aspects.
Students are given the means to dig effectively into modern scientific literature in the multidisciplinary field of bioengineering.
The method relies on granting sufficient time to become familiar wi
