The goal of the Ohio Third Frontier Technology Validation and Start-up Fund (TVSF) is to create greater economic growth in Ohio based on start-up companies that commercialize technologies developed by Ohio institutions of higher education and other Ohio not-for-profit research institutions. The Technology Validation and Start-Up Fund has been designed to:
1. Support protected technologies developed at Ohio research institutions that need known validation/proof that will directly impact and enhance both their commercial viability and ability to support a start-up company, and
2. Support Ohio start-up and Ohio young companies that license these validated/proven technologies from these Ohio research institutions.
The National Science Foundation (NSF) announces a fourth year of a program on collaborative research and education in the area of scalable nanomanufacturing, including the long-term societal implications of the large-scale implementation of nanomanufacturing innovations. This program is in response to and is a component of the National Nanotechnology Initiative Signature Initiative: Sustainable Nanomanufacturing - Creating the Industries of the Future (http://www.nano.gov/node/611.) Although many nanofabrication techniques have demonstrated the ability to fabricate small quantities of nanomaterials, nanostructures and nanodevices for characterization and evaluation purposes, the emphasis of the scalable nanomanufacturing program is on research to overcome the key scientific and technological barriers that prevent the production of useful nanomaterials, nanostructures, devices and systems at an industrially relevant scale, reliably, and at low cost and within environmental, health and safety guidelines.
In emerging areas of technology at the interface between fields such as the engineering of biology and cellular biomanufacturing, including the field of synthetic biology, there is an even greater need for collaborative precompetitive research that will ensure the success of these nascent technology areas. In particular, research that contributes to the establishment of standards for production; provides tools for the assessment of quality, robustness and stability of the process and product; and develops metrics that will facilitate risk assessment associated with a regulatory framework, will be essential for the eventual commercialization of products from the engineering of biology.
This solicitation aims at introducing nanoscale science, engineering, and technology through a variety of interdisciplinary approaches into undergraduate engineering education. The focus of the FY 2014 competition is on nanoscale engineering education with relevance to devices and systems and/or on the societal, ethical, economic and/or environmental issues relevant to nanotechnology.
The goal of the Office of Science Graduate Student Research (SCGSR) program is to prepare graduate students for science, technology, engineering, or mathematics (STEM) careers critically important to the DOE Office of Science mission, by providing graduate thesis research opportunities at DOE laboratories. The SCGSR program provides supplemental awards to outstanding U.S. graduate students to pursue part of their graduate thesis research at a DOE laboratory in areas that address scientific challenges central to the Office of Science mission. The research opportunity is expected to advance the graduate students' overall doctoral thesis while providing access to the expertise, resources, and capabilities available at the DOE laboratories.
The Science of Science & Innovation Policy (SciSIP) program supports research designed to advance the scientific basis of science and innovation policy. Research funded by the program thus develops, improves and expands models, analytical tools, data and metrics that can be applied in the science policy decision making process.
Amgen Scholars is hosted at 10 premier institutions within the United States. Each host institution has its own application process. U.S. citizenship or permanent residency in the United States is required, and you can apply to participate at as many host institutions as you are interested in.
Biophotonics applies photonics technology to the fields of medicine, biology and biotechnology. Basic research and innovation in photonics that is very fundamental in science and engineering is needed to lay the foundation for new technologies beyond those that are mature and ready for application in medical diagnostics and therapies. Advances are needed in nanophotonics, optogenetics, contrast and targeting agents, ultra-thin probes, wide field imaging, and rapid biomarker screening. Low cost and minimally invasive medical diagnostics and therapies are key goals.
Examples of topics are:
Macromolecule Markers - Innovative methods for labeling of macromolecules, new compositions of matter/methods of fabrication of multi-color probes such as might be used for marking and detection of specific pathological cells and push the envelope of optical sensing to the limits of detection, resolution, and identification
Low Coherence Sensing at the Nanoscale - Low coherence enhanced backscattering (LEBS), n-dimensional elastic light scattering, and angle-resolved low coherence interferometry for early cancer detection (dysplasia)
Neurophotonics - Studies of photon activation of neurons at the interface of nanomaterials attached to cells. Development and application of biocompatible photonic tools such as parallel interfaces and interconnects for communicating and control of neural networks
Micro- and Nano-photonic - Development and application of nanoparticle fluorescent quantum-dots; sensitive, multiplexed, high-throughput characterization of macromolecular properties of cells; nanomaterials and nanodevices for biomedicine
Optogenetics - Employing light-activated channels and enzymes for manipulation of neural activity with temporal precision.
The Communications, Circuits, and Sensing-Systems (CCSS) program is intended to spur visionary systems-oriented activities in collaborative, multidisciplinary, and integrative research. CCSS supports systems research in hardware, signal processing techniques, and architectures to enable the next generation of cyber-physical systems (CPS) that leverage computation, communication, and algorithms integrated with physical domains. CCSS offers new challenges at all levels of systems integration to address future societal needs. CCSS supports innovative research and integrated educational activities in micro- and nano-systems, communications systems, and cyber-physical systems. The goal is to design, develop, and implement new complex and hybrid systems at all scales, including nano, micro, and macro, that lead to innovative engineering principles and solutions for a variety of application domains including, but not limited to, healthcare, medicine, environmental monitoring, communications, disaster mitigation, homeland security, transportation, manufacturing, energy, and smart buildings. CCSS also supports integration technologies at both intra-and inter-chip levels, new and advanced radio frequency (RF), millimeter wave and optical wireless and hybrid communications systems architectures, and sensing and imaging at terahertz (THz) frequencies.
The Environmental Health and Safety of Nanotechnology (Nano EHS) program provides support to examine and mitigate the environmental effects of nanotechnologies. Fundamental research is sought to understand, evaluate, and lessen the impact of nanotechnology on the environment and biological systems.
The program emphasizes engineering principles underlying the environmental health and safety impacts of nanotechnology. Innovative methods related to clean nanomaterials production processes, waste reduction, recycling, and industrial ecology of nanotechnology are also of interest.
The Energy, Power, and Adaptive Systems (EPAS) program invests in the design and analysis of intelligent and adaptive engineering networks, including sensing, imaging, controls, and computational technologies for a variety of application domains. EPAS places emphasis on electric power networks and grids, including generation, transmission and integration of renewable, sustainable and distributed energy systems; high power electronics and drives; and understanding of associated regulatory and economic structures. Topics of interest include alternate energy sources, the Smart Grid, and interdependencies of critical infrastructure in power and communications. The program also places emphasis on energy scavenging and alternative energy technologies, including solar cells, ocean waves, wind, and low-head hydro. In addition, the program supports innovative test beds, and laboratory and curriculum development to integrate research and education. EPAS invests in adaptive dynamic programming, brain-like networked architectures performing real-time learning, neuromorphic engineering, telerobotics, and systems theory. The program supports distributed control of multi-agent systems with embedded computation for sensor and adaptive networks. EPAS provides additional emphasis on emerging areas, such as quantum systems engineering, quantum and molecular modeling and simulation of devices and systems.
The competition for individual sites will be for consideration of large and small university-based user facilities, including those at minority-serving institutions, that are geographically distributed and with diverse and complementary capabilities to support current and anticipated future user needs across the broad spectrum of nanoscale science, engineering, and technology domains. The selected individual sites will have autonomy in their operation and management, but will be required to act in concert with a Coordinating Office that will be separately competed and chosen at a later stage. Some sites may choose to partner with facilities at regional or smaller institutions that would bring specific capabilities for users and benefits to student training. The overall collection of selected sites and their capabilities will provide users with cost-effective access both to the specialized tools, processes, and expertise to support complex multi-step fabrication at the nanoscale level for structures, materials, devices, and systems, as well as to the associated instrumentation for characterization, analysis, and probing at these dimensions. The program aims to make these capabilities broadly available to the nation's researchers in academe, industry, and government to help catalyze new discoveries in science and engineering and to stimulate technological innovation.
The Electronics, Photonics, and Magnetic Devices (EPMD) program seeks to improve the fundamental understanding of devices and components based on the principles of micro- and nanoelectronics, photonics, magnetics, optoelectronics, electromechanics, electromagnetics, and related physical phenomena. The program enables discovery and innovation advancing the frontiers of nanoelectronics, spin electronics, molecular and organic electronics, bioelectronics, non-silicon electronics, flexible electronics, microwave photonics, micro/nano-electromechanical systems (MEMS/NEMS), sensors and actuators, power electronics, and mixed signal devices. EPMD supports related topics in quantum engineering and novel electromagnetic materials-based high frequency device solutions, radio frequency (RF) integrated circuits, and reconfigurable antennas needed for communications, telemedicine, and other wireless applications. The program supports cooperative efforts with the semiconductor industry on new nanoelectronics concepts beyond the scaling limits of silicon technology. EPMD additionally emphasizes emerging areas of diagnostic, wearable and implantable devices, and supports manipulation and measurement with nanoscale precision through new approaches to extreme ultraviolet metrology.
The Electronic and Photonic Materials (EPM) program seeks to advance the field of electronics and photonics through basic, potentially transformative materials science research. The scope of the program encompasses the discovery and understanding of materials and material integration with potential for major technological innovations.
The MME program supports fundamental research that enables the development of new and/or improved manufacturing machines and equipment, and optimization of their use, with a particular focus on equipment appropriate for the manufacture of mechanical and electromechanical devices, products, and systems featuring scales from microns to meters (proposals relating to nanomanufacturing should be submitted to the CMMI NanoManufacturing program, and those relating to the manufacture of electronic devices such as IC products should be submitted to the ECCS Division).
NIST is soliciting applications for financial assistance for Fiscal Year 2016 (FY16) within the following NIST Laboratory grant programs: (1) the Material Measurement Laboratory (MML) Grant Program; (2) the Physical Measurement Laboratory (PML) Grant Program; (3) the Engineering Laboratory (EL) Grant Program; (4) the Fire Research (FR) Grant Program; (5) the Information Technology Laboratory (ITL) Grant Program; (6) the Communications Technology Laboratory (CTL) Grant Program; (7) the NIST Center for Neutron Research (NCNR) Grant Program; (8) the Center for Nanoscale Science and Technology (CNST) Grant Program; (9) the Special Programs Office (SPO) Grant Program; (10) the Standards Coordination Office (SCO) Grant Program; (11) the International and Academic Affairs Office (IAAO) Grant Program; and (12) the Associate Director for Laboratory Programs (ADLP) Grant Program.
NIST is soliciting applications for financial assistance for Fiscal Year 2016 (FY16) within the following NIST Laboratory grant programs: (1) the Material Measurement Laboratory (MML) Grant Program; (2) the Physical Measurement Laboratory (PML) Grant Program; (3) the Engineering Laboratory (EL) Grant Program; (4) the Fire Research (FR) Grant Program; (5) the Information Technology Laboratory (ITL) Grant Program; (6) the Communications Technology Laboratory (CTL) Grant Program; (7) the NIST Center for Neutron Research (NCNR) Grant Program; (8) the Center for Nanoscale Science and Technology (CNST) Grant Program; (9) the Special Programs Office (SPO) Grant Program; (10) the Standards Coordination Office (SCO) Grant Program; (11) the International and Academic Affairs Office (IAAO) Grant Program; and (12) the Associate Director for Laboratory Programs (ADLP) Grant Program.
The International Research Network Connections (IRNC) program supports high-performance network connectivity required by international science and engineering research and education collaborations involving the NSF research community. NSF expects to make 1-2 awards to link U.S. research networks with peer networks in Europe and Africa and leverage existing international network connectivity. High-performance network connections funded by this program are intended to support science and engineering research and education applications, and preference will be given to solutions that provide the best economy of scale and demonstrate the ability to support the largest communities of interest with the broadest services. Funded projects will assist the U.S. research and education community by enabling state-of-the-art international network services and access to increased collaboration and data services. Through extended international network connections, additional research and production network services will be enabled, complementing those currently offered or planned by domestic research networks.
The International Research Network Connections (IRNC) program supports high-performance network connectivity required by international science and engineering research and education collaborations involving the NSF research community. NSF expects to make 1-2 awards to link U.S. research networks with peer networks in Europe and Africa and leverage existing international network connectivity. High-performance network connections funded by this program are intended to support science and engineering research and education applications, and preference will be given to solutions that provide the best economy of scale and demonstrate the ability to support the largest communities of interest with the broadest services. Funded projects will assist the U.S. research and education community by enabling state-of-the-art international network services and access to increased collaboration and data services. Through extended international network connections, additional research and production network services will be enabled, complementing those currently offered or planned by domestic research networks.
This Program encourages research on processes and production systems based on computation, modeling and simulation, use of process metrology, sensing, monitoring, and control, and assessment of product (nanomaterial, nanostructure, nanodevice or nanosystem) quality and performance. The Program seeks to explore transformative approaches to nanomanufacturing, including but not limited to: micro-reactor and micro-fluidics enabled nanosynthesis, bio-inspired nanomanufacturing, manufacturing by nanomachines, additive nanomanufacturing, hierarchical nanostructure assembly, continuous high-rate nanofabrication such as roll-to-roll processing or massively-parallel large-area processing, and modular manufacturing platforms for nanosystems.
Proposals should target nanomanufacturing processes with a clear commercial relevance, and should consider addressing key aspects of the nanomanufacturing value chain of nano-scale building-blocks to complex nanostructures to functional devices to integrated systems
The purpose of this Notice is to inform new NIH applicants, their mentors, and grant administrators at their institution about two upcoming webinars the NIH Center for Scientific Review (CSR) is hosting in November 2015. These webinars are designed to give participants useful insights into our application submission and peer review processes. CSR is the portal for NIH grant applications and their review for scientific and technical merit.
