New $46M Nanotech Lab Coming To UM
A next-generation nano-mechanical engineering lab complex at the University of Michigan will enable researchers to study the forces at work at the smallest scales and to advance nano-technologies in energy, manufacturing, healthcare and biotechnology.
The Center of Excellence in Nano Mechanical Science and Engineering is a $46 million facility made possible in part by a $9.5 million grant from the National Institute of Standards and Technology, announced Wednesday. The three-story complex will include 60 lab modules and space for 18 professors in a 62,880-square-foot addition to the G.G. Brown Laboratories on Hayward Street on North Campus.
"Michigan Engineering has always been strong in traditional large-scale mechanical engineering areas including automotive research," said UM engineering dean David Munson. "This new facility will propel us to the next level. It will allow researchers to pursue exciting projects at the frontiers of mechanical science and engineering, where the discipline intersects with nanoscience and biology. We would like to thank our federal lawmakers U.S. Rep. John Dingell, U.S. Sen. Carl Levin and U.S. Sen. Debbie Stabenow as well as Gov. Jennifer Granholm for their support throughout this process."
This center will complement the College of Engineering's Lurie Nanofabrication Facility, a state-of-the art lab where researchers focus on building devices at the nanoscale. In the new complex, researchers will develop the tools to measure, image, study and test nan-scale phenomena and devices.
"The award is great news for the University of Michigan and the state of Michigan," said Gov. Jennifer Granholm. "This new facility will help train the next generation of engineers in our state, and produce the cutting-edge research and development in energy, health care and manufacturing that will continue to diversify our economy and create jobs."
The center will be designed with a tightly controlled experimental environment. Existing labs in mechanical engineering, designed for macroscale research, don't have the right temperature, dust, vibration and noise controls for researchers to take accurate nanoscale measurements, said Jack Hu, associate dean for academic affairs in engineering. He led the proposal effort to NIST.
"Nanotechnology is full of promise," Hu said. "It has applications in manufacturing, in medicine and in solar and thermal energy conversion, to name just a few fields. Fundamental to all these areas is a good understanding of the mechanical behavior of nanoparticles and we don't yet have that. Through this facility, we are providing an enabling platform for this research and innovation."
Work in the lab will be divided into four thrusts: nano-measurement, single biomolecule analysis, nanoscale energy conversion and nanomanufacturing, and nano- and microelectromechanical systems for medical research and diagnostics. Some of the projects will take place in the labs are:
* Measuring the twisting forces at work in a DNA molecule, which could help researchers understand how these blueprints of life copy and repair themselves.
* Testing new techniques that map strain, temperature and forces in materials in order to understand one of the most vexing phenomena in engineering: why and how does a material's strength depend on its microscopic structure. Traditional laws cannot predict the strength of devices at the smallest scales. This research could bring about lighter materials that could improve fuel economy.
* Understanding how biological molecules interact and reproduce, how they transport molecular cargoes, and how they convert chemical signals into mechanical work. New knowledge of these processes could aid in the development of better drug delivery and treatments for cancer and neurodegenerative diseases.
* Building a microelectromechanical biochip that can affordably count thousands of single T-cells for HIV-AIDS monitoring in resource-limited settings.
* Figuring out why carbon nanotubes are so strong and conductive. They are stronger and stiffer than steel. They conduct electricity better than copper, and conduct heat better than diamonds. But to integrate them into larger devices, engineers must be able to understand and predict these properties.
Construction is expected to start in spring 2011 and finish in May 2013. In addition to the NIST funding, this project is supported by $15 million from the University of Michigan, $5 million from the College of Engineering, and $15 million in private commitments.
More at www.engin.umich.edu.
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