The group is particularly interested in discovering novel nanobiology of nanomaterials. Some of this nanobiology is detrimental to the organism's well being and some is beneficial. The differentiation of either conclusion depends heavily on our understanding of how nanomaterials interact with biological systems. The group approaches their work from an observation initiated and hypothesis driven manner. From these findings, they aim to develop nanoparticle specific rules that drive certain cell effect. Understanding these rules helps to design better nanoparticles.
Excellent students from all scientific and engineering, as well as biomedical disciplines are welcome to apply for NanoCore PhD Scholarships. Students whom we are recruiting typically are in the top 10% of their class and have shown the ambition and ability to immerse themselves in challenging, high impact research projects. We also highly welcome students who have entrepreneurial ambitions.
Graphene is a new age multifunctional material. As chemists, we are engaged in the growth, processing, derivatizing of graphene to make dna sensors, hybrids for solar cells, membrane for water purification. We hope to improve the quality of human life by researching on graphene, which we believe to be a fundamental building block for many useful devices.
The Environmental Nanoscience Initiative was set up by NERC, Defra and the Environment Agency in the UK to begin to answer some questions of basic nanosciences research; into fate and behavior, ecotoxicology and ecological effects of engineering nanoparticles.
Located at North Dakota State University, Fargo, the NDSU Center for Nanoscale Science and Engineering provides research and development with world-class facilities, equipment and staff with broad-based expertise.
The Network for Computational Nanotechnology (7 universities) has a mission to connect theory, experiment, and computation in a way that makes a difference to the future of nanotechnology. While addressing challenges in nanotechnology NCN researchers produce new algorithms, approaches, and software tools with capabilities not yet available commercially.
The main objective of the project, which ran from 08/2004 until 07/2006, was to mobilize human and material resources in the field of nanostructured materials in New Member States of the EU, to consolidate, strengthen, and enhance the dispersed research/technological potential in this field of research, to promote and use the results of 5th FP and 6th FP, and to improve the knowledge based application oriented nanoscience and nanotechnology in Europe.
The NEURONANO network major aim is to integrate carbon nanotubes (CNT) with multielectrode array (MEA) technology to develop a new generation biochips to help repair damaged central nervous system (CNS) tissues.
NJIT is renowned for expertise in architecture, applied mathematics, wireless communications and networking, solar physics, advanced engineered particulate materials, nanotechnology, neural engineering and e-learning.
The research in Prof. Dong Ko's group focuses on how we can utilize nanocrystals for direct conversion into electricity of two of the most important ubiquitous sources of free energy: sunlight and waste heat.
The New Mexico EPSCoR program is a statewide collaborative partnership of colleges and universities, national laboratories, industry, and state government united in an effort to promote research, increase opportunities for training the workforce of scientists and engineers and, ultimately, to promote the economic development of the state of New Mexico. The goal of the NM EPSCoR program is to increase the competitiveness of NM researchers within targeted science and technology fields through sustainable infrastructure improvements.
Nanoscience and materials at NYU includes fullerene derivatization studies, chiral sensors and triggered materials, peptide nanotechnology; peptide surface interactions, molecular imaging agents, and proteins containing unnatural amino acids.
The project focuses on the research and development of a new bioactive non-resorbable fibre-reinforced composite (FRC) material for load-bearing bone and joint implants in skeletal reconstruction of orthopaedic and trauma patients. A special emphasis will be placed on the development of bioactive and antibacterial surface treatments of the implants. Another objective is to produce novel composite-based bioactive resorbable fixation devices for ligament repairs of the knee and shoulder.
The ETM group focuses on unique strengths and capabilities to conduct world leading research, benefiting from synergies between: microelectronics; materials research and design to simulate nanostructures and technology processes and devices; fabrication in two in-house class 100-1000 clean rooms; characterisation of materials, devices and circuits; research on emerging electronic technologies
Research activities in the group encompass a wide range of themes at the cutting-edge of nanoscale science and nanotechnology - principal interests lie in the synthesis and characterisation of new nanomaterials, such as nanodiamonds, silicon nanocrystals, gold nitride (AuN) and photon reactions on ice.