MassNanoTech, the research institute for nanotechnology at the University of Massachusetts Amherst, coordinates research on nanoscale materials, devices and systems, collaborates with industry, advances nanotechnology commercialization, educates students, and fosters outreach activities.
The research of Rotello's group at the University of Massachusetts focuses on the area of supramolecular chemistry: the study and application of non-covalent interactions. These interactions include hydrogen bonding, aromatic stacking and other electrostatic attractions and repulsions. We are currently employing these concepts of molecular recognition to explore a wide range of important questions in areas of biology to materials chemistry.
CHN focuses on generating knowledge and innovations in the area of template-directed assembly at high-rate, high yield nanomanufacturing. CHN represents a unique center structure, with three universities -- UMass Lowell, Northeastern University, and University of New Hampshire -- forming an equal partnership.
Mission: To lead the research effort in high throughput, environmentally-friendly processing of polymeric materials, devices, and structures and integration of other materials and devices with polymers with nanoscale control; To serve as a focal point and resource for transfer of nanoscience and nanotechnology to industrial application; To facilitate educational and outreach efforts related to nanotechnology and specifically nanomanufacturing.
The mission of the Keck Nanostructures Laboratory is to provide access to material characterization equipment, technical support, training and consultation, as well as to perform a range of services for users in the area of Atomic Force Microscopy (AFM), Small Angle X-ray Scattering (SAXS), Variable Angle Spectrocopic Elliposmetry (VASE) and Optical Microscopy.
Research in the Glotzer group focuses on understanding why and how ordered structures emerge in otherwise disordered soft materials and nanoscale systems -- and how to design and control novel, functional structures from nanoscale building blocks using unconventional methods. Our tools for discovery include molecular, mesoscale, and multiscale computer simulations.
The LNF is available, on a fee basis, for use by research groups from government, industry and universities. Equipment and processes are available for research on silicon integrated circuits, MEMS, III-V compound devices, organic devices and nanoimprint technology.
The group's research deals with nanostructures and nanostructured materials. They seek to expand the science of how to synthesize these materials and engineer their fundamental properties; to create new technology to realize the related chemical, mechanical, and thermal assembly processes; and to pioneer applications which harness the unique properties of nanostructures at small and large scales.
The MNF is one of the leading centers worldwide on micro electromechanical systems (MEMS) and microsystems. It provides facilities and processes for the integration of Si integrated circuits and MEMS with nanotechnology, with applications in biology, medical systems, chemistry, and environmental monitoring.
The Center for Nanostructure Applications is a focal point for nanotechnology at the University of Minnesota. It's a place where you will be able to find information about faculty engaged in University of Minnesota-specific information such as nano-related research and workshops, as well as announcements on nano related news, calls for proposals, conferences, and other regional and national events.
The Center for Spintronic Materials, Interfaces, and Novel Architectures (C-SPIN) is a multi-university research center that will bring together top researchers from across the nation to develop technologies for spin-based computing and memory systems. Unlike today's computers, which function on the basis of electrical charges moving across wires, the emerging spin-based computing systems will process and store information through spin, a fundamental property of electrons. Spin-based logic and memory have the potential to create computers that are smaller, faster and more energy-efficient than conventional charge-based systems. Research conducted by C-SPIN will also have an impact beyond the world of computer science through advances in materials science, chemistry, circuit design, nanotechnology, and many other fields.