Porous materials are omnipresent in nature: microporous materials, such as zeolite minerals, with pores of angstrom, molecular dimensions; mesoprous materials, such as cell membranes, with nanometre-sized pores; macroporous materials, such as diatom skeletons, with micron-sized pores. Synthetic analogues of such materials are prepared and studied here and find many industrial uses in for instance catalysis, water treatment, environmental clean-up, molecular separation and opto-electronics.
The goal of the centre is to create an easy-to-access-and-use, multidisciplinary workshop with extensive facilities, that allows researchers to fabricate, visualise and characterise structures and devices containing individual elements from a few microns down to 10 nm in size.
The group's research activities cover a range of topics concerned with the fundamental materials and physics issues surrounding advanced semiconductor devices, novel high speed electronic and optoelectronic devices, and advanced sensors and systems.
The Nano Engineering & Storage Technology (NEST) research group (formerly the Electronic & Information Storage Systems Research Group) has research interests in nano fabrication for data storage and advanced sensors applications and the investigation of data storage systems in general. The NEST group is housed in an integrated suite of staff offices, general-purpose laboratory space and class 100/1000 cleanrooms and is a founder member of the Manchester Centre for Mesoscience and Nanotechnology (CMN) where the ground-breaking Nobel prize winning work on Graphene by Andre Geim and Konstantin Novoselov was undertaken.
EPSRC CDT in the Science and Applications of Graphene and Related Nanomaterials (GrapheneNOWNANO) is a newly established Centre for Doctoral Training (CDT) based at the University of Manchester in partnership with Lancaster University. It builds on the world-leading expertise in the science and technology of graphene and other two-dimensional (2D) materials at Manchester and Lancaster to offer a broad interdisciplinary CDT.
The Mission of the Center for Nanomedicine and Cellular Delivery (CNCD) at the University of Maryland is to create a multidisciplinary research environment that will provide expertise and foster collaborations for the design, development and translation into clinic of nanosystems for therapeutic and diagnostic purposes.
The Center for Superconductivity Research has been merged with Condensed Matter Physics to create a new collaborative entity known as the Center for Nanophysics and Advanced Materials (CNAM). The CNAM is dedicated to advancing science and technology in the important areas of nanophysics and novel electronic materials.
The mission of IBBR is to leverage collective research strengths of the partnering Institutions in medicine, biosciences, technology, quantitative sciences and engineering, to develop integrated, cross-disciplinary team approaches to scientific discovery and education and to serve the expanding economic base of biosciences and technology in the state of Maryland and the Nation.
The group's research is centered on techniques for fabricating and characterizing nanometer scale structures, in directing their rapid self-assembly and in using nanometer scale structures to enhance the efficiency of devices which involve their interaction with light.
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.
The Master of Nanoelectronic Engineering will enable students to become familiar with theories governing nano-electronic systems and become proficient in the design and fabrication of nano-electronic systems and integrated circuits. Theory, concepts and design methodologies taught in the course are put into practice during laboratory sessions and used for the design project.
Current areas of research include: quantum dots in LEDs and solar cells and biolabelling, plasmonics, energy transfer mechanisms in nanoscale systems, nanomechanics, smart functional materials, nanofabrication techniques and nanocrystal doping.
Materials science at the University of Melbourne extends across a range of fields including physics, chemistry, biology, medicine and engineering. The center showcases materials research under five interdisciplinary themes: Materials conservation, Materials for medicine, Quantum and nanophotonic materials, Materials for energy and Materials processing.
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.