Experimental and theoretical research carried out at the Max Planck Institute of Microstructure Physics is primarily focussed on solid state phenomena that are determined by small dimensions and surfaces and interfaces. The investigations concentrate on establishing relations between the magnetic, electronic, optical, and mechanical properties of solids and their microstructure. Thin films and surfaces are investigated as well as nanocrystalline materials, phase boundaries and defects in bulk crystals.
Investigation of semiconductors and devices for optoelectronic applications including photovoltaic energy conversion and optical communications. Development of thin film transistors for electronic displays and imaging systems.
The group's research in micro- and nanobioengineering is focused on miniaturizing biological experimentation to microscopic scales and progresses along two axes: Firstly, create tools and use them for precisely controlling and varying the cellular microenvironment, which will allow studying the response of cells and groups of cells to external cues and stimuli applied to single cells. Secondly, the large scale parallelization of the biological experiments for both protein analysis and cell biological experiments.
The group's research focuses on the application and development of advanced microscopy techniques to study the structure of materials at very high spatial resolution. The core area of research is based on transmission electron microscopy methods but they also use scanning probe techniques and other characterization techniques to provide information on how the structure of materials affects the properties these materials exhibit.
MBIís primary focus is to identify, measure and describe how the forces for motility and morphogenesis are expressed at the molecular, cellular and tissue level. Toward that goal, we are working to create a common international standard for defining these steps by developing powerful new computational models, experimental reagents, and tools for studying diseases of cells and tissues. Our goal is then to transfer these basic discoveries to both the clinic and the classroom.
(Site in German) The BMBF supported research project on metal gate electrodes and epitaxial oxides as gate stacks for future CMOS logic and memory generations (MEGA EPOS) refers to the BMBF research program IKT2020 - Elektronik und Mikrosysteme. The consortium is coordinated by Gesellschaft für Angewandte Mikro- und Optoelektronik (AMO) and consists of seven partners acting from basic research to application.
The Melbourne Centre for Nanofabrication is the Victorian Node and headquarters of the Australian National Fabrication Facility (ANFF). Opened in July 2010, this multi-user research facility is operating the largest purpose-built cleanroom complex in the Southern Hemisphere. Drawing upon the wealth of knowledge within six Universities and CSIRO, they are uniquely placed in a thriving cosmopolitan world-centre enabling us to bridge the gaps between scientific disciplines and commercial needs.
The main scientific objective of the partners of this consortium is to develop new types of artificial materials, referred to below as metamaterials, with electromagnetic properties that cannot be found among natural materials. The results of this development should lead to a conceptually new range of radio, microwave, and optical technologies, based on revolutionary new materials made by large-scale assembly of some basic elements (nanoscopic and microscopic) in unprecedented combinations.
'Bringing intelligence into micro-nano-systems' - The focus of this research group is integration of adaptive and machine learning techniques with micro-systems to achieve ultra-low power and robust operation.
The MOE lab focuses on inorganic and organic excitonic materials for solar energy production and utilization. They look to exploit oriented, crystalline, nanostructured and excitonic films through organic-inorganic and organic-organic interactions while studying fundamental relationships between structure and photophysical properties.
The Graduate Certificate in Nanotechnology recognizes advanced study of scientific, technological, and engineering topics in nanotechnology, including aspects of 1) characterization; 2) micro- to nano-scale fabrication and control; and 3) devices, systems and integration. The certificate also requires study of the societal and ethical implications of emerging technologies.
The minor in Nanoscale Science and Engineering (Nanotechnology) is deliberately designed to introduce students to the basic issues and overall scope of this field, encourage students to pursue interdisciplinary coursework outside their major, develop an understanding of the importance of flexibility in terms of careers, research, and education, and be flexible to allow for participation by students in diverse majors.
Micronova is a center for the design, development and fabrication of micro- and nanosystems. Micronova is run jointly by the VTT Technical Research Centre of Finland and Helsinki University of Technology (TKK).
Nanomicrowave is a Marie Curie Initial Training Network (ITN) aiming to train a new generation of multidisciplinary researchers in the field of nanoscale microwave technologies and related emerging applications. The consortium consists of three industrial partners and seven academic and research institutions.
The graduate program in Micro and Nanotechnology is a joint interdisciplinary program of the following Departments: Biological Sciences, Chemistry, Physics, Chemical Engineering, Electrical and Electronics Engineering, Engineering Sciences, Metallurgical and Materials Engineering, Mining Engineering and Mechanical Engineering.
The PhD program in Micro and Nanotechnology is a joint interdisciplinary program of the following Departments: Biological Sciences, Chemistry, Physics, Chemical Engineering, Electrical and Electronics Engineering, Engineering Sciences, Metallurgical and Materials Engineering, Mining Engineering and Mechanical Engineering.