CNSE's Nanoscale Engineering program provides corresponding skill and expertise in the design, fabrication, and integration of nanoscale devices, structures, and systems for the development and deployment of emerging nanotechnologies.
Sharing the brain power of academic and corporate partners throughout the State of Arkansas, the Nanotechnology Center is a state-of-the-art, user-oriented facility focused on education, research, and economic development.
The Institute for Nanoscience and Engineering has a group of facilities that is unique among universities, including scanning tunneling microscopy, atomic force microscopy, transmission electron microscopy, X-ray photoelectric spectroscopy, a focus ion beam, scanning electron microscopy, electrical and magnetic characterization, single molecule/particle spectroscopy, auger spectroscopy, X-ray, Fourrier transform infrared spectroscopy, and Raman spectroscopy. In addition, the institute benefits from the use of the High Performance Supercomputing Facility on campus.
The Center for Environmental Implications of Nanotechnology (CEIN) explores the impact of libraries of engineered nanomaterials on a range of cellular lifeforms, organisms and plants in terrestrial, fresh water and sea water environments. By being able to predict which nanomaterial physicochemical properties are potentially hazardous, the CEIN will be able to provide advice on the safe design of engineered nanomaterials from an environmental perspective.
The Micro-Nano Innovations (MiNI) Laboratory, led by Dr. Tingrui Pan, is an incubator for exploratory interdisciplinary research bridging nanoengineering and biomedicine. They endeavor to develop novel micro-nanoengineered platforms for contemporary biological applications, to deliver innovative engineered solutions to pressing medical problems, and to educate next-generation bioengineers for future healthcare.
NEAT focuses on applications in ceramic, chemical, electronic, environmental, and agricultural technology; environmental transport and transformation and resulting roles in environmental pollution and remediation; interactions with the biosphere, especially microorganisms; effects on health.
Seung-Wuk Lee's research group uses chemical and biological approaches to create precisely defined nanomaterials, to investigate complex phenomena at their interfaces, and to develop novel, biomimetic, functional materials. Specifically, they focus on bone and its basic building blocks to study the fundamental mechanisms of bone mineralization and resorption and to develop bioinspired functional materials and devices.