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The PRORP Idea Development Award is designed to promote new ideas that are still in the early stages of development and have the potential to yield highly impactful data and new avenues of investigation. This mechanism supports conceptually innovative, high-risk/high-reward research that could lead to critical discoveries or major advancements that will accelerate progress in the clinical care of combat-related orthopaedic injuries. Applications should include a well-formulated, testable hypothesis based on strong scientific rationale.

To potentially support the full-scale testing of MHK wave energy devices, the Water Power Program intends to evaluate site locations, designs, and estimated costs for an open water, fully energetic domestic wave test facility. It is expected that a viable grid-connected facility will be capable of testing both scaled prototypes and full-scale (utility-scale) wave energy conversion devices in order to evolve reliable, low cost, renewable energy alternatives to fossil fuel. Prototype testing is essential to mature existing wave technologies, validate performance against analytic models, demonstrate compliance with applicable design standards and thereby mitigate the technical and financial risk of developing and deploying mass-produced wave energy devices, plants, technologies and related products. Construction and operation of a full-scale domestic wave test facility will assist the U.S. industry by identifying design and manufacturing deficiencies early in the development cycle and validate modifications and improvements prior to commercial deployment. Ultimately, this new testing capability will improve the country?s competitiveness in MHK energy technology, encourage domestic manufacturing, job creation, and provide a new technology that utilizes an untapped renewable resource to help achieve the nation?s energy goals. This FOA is intended to identify possible site locations and evaluate the potential to establish a national wave testing facility within U.S. territorial waters. 

Next-generation wireless networks, utilizing a wide swath of wireless spectrum and an array of novel technologies in the wired and wireless domains, are on the cusp of unleashing a broadband revolution with promised peak bit rates of tens of gigabits per second and latencies of less than a millisecond. Such innovations will make possible a new set of applications such as autonomous vehicles, industrial robotics, tactile Internet applications, virtual and augmented reality, and dense Internet of Things (IoT) deployments. A key requirement of these applications is fast information response time that is invariant as a function of the bandwidth demanded, users/devices supported, and data generated, of which low-latency wireless access time is only one component. Intrinsic security, seamless mobility, scalable content caching, and discovery/distribution services are also essential for such applications. This solicitation seeks unique data network architectures featuring an information plane using an Information-Centric Networking (ICN) approach and addressing discovery, movement, delivery, management, and protection of information within a network, along with the abstraction of an underlying communication plane creating opportunities for new efficiencies and optimizations across communications technologies that could also address latency and scale requirements.

NSF and RNP/CTIC request joint research proposals submitted separately to both NSF and RNP/CTIC using the proposal submission process specific to each agency. Research topics of special interest to NSF and RNP/CTIC are: (1) security and privacy in networks; (2) the Internet of Things and cyber-physical human systems; and (3) malware detection. These topics that are of considerable mutual interest recognize the emerging threat and new opportunity in an increasingly networked world of people and smart technologies as well as the urgent need to address the societal challenge of cybersecurity. NSF strongly encourages new collaborations pursuant to this DCL.

This program supports fundamental scientific research in ceramics (e.g., oxides, carbides, nitrides and borides), glass-ceramics, inorganic glasses, ceramic-based composites and inorganic carbon-based materials. Projects should be centered on experiments; inclusion of computational and theory components are encouraged. The objective of the program is to increase fundamental understanding and to develop predictive capabilities for relating synthesis, processing, and microstructure of these materials to their properties and ultimate performance in various environments and applications. Research to enhance or enable the discovery or creation of new ceramic materials is welcome. Development of new experimental techniques or novel approaches to carry out projects is encouraged. Topics supported include basic processes and mechanisms associated with nucleation and growth of thin films; bulk crystal growth; phase transformations and equilibria; morphology; surface modification; corrosion, interfaces and grain boundary structure; and defects. Additional Information Eligibility rules apply for submissions; please see the Program Description section of the CER solicitation for details. PIs are encouraged to include all anticipated broader impact activities in their initial proposals, rather than planning on supplemental requests. Most projects include: (1) the anticipated significance on science, engineering and/or technology including possible benefits to society, (2) plans for the dissemination, and (3) broadening participation of underrepresented groups and/or excellence in training, mentoring, and/or teaching. Many successful proposals include one additional broader impact activity.

Understanding the dynamic activity of neural circuits is central to the NIH BRAIN Initiative.  This FOA seeks applications for proof-of-concept testing and development of new technologies and novel approaches for large scale recording and manipulation of neural activity to enable transformative understanding of dynamic signaling in the nervous system.  In particular, we seek exceptionally creative approaches to address major challenges associated with recording and manipulating neural activity, at or near cellular resolution, at multiple spatial and/or temporal scales, in any region and throughout the entire depth of the brain.  It is expected that the proposed research may be high-risk, but if successful could profoundly change the course of neuroscience research.

Understanding the dynamic activity of neural circuits is central to the NIH BRAIN Initiative.  This FOA seeks applications for proof-of-concept testing and development of new technologies and novel approaches for large scale recording and manipulation of neural activity to enable transformative understanding of dynamic signaling in the nervous system.  In particular, we seek exceptionally creative approaches to address major challenges associated with recording and manipulating neural activity, at or near cellular resolution, at multiple spatial and/or temporal scales, in any region and throughout the entire depth of the brain.  It is expected that the proposed research may be high-risk, but if successful could profoundly change the course of neuroscience research.

The U.S. Environmental Protection Agency (EPA), as part of its Science to Achieve Results (STAR) program, is seeking applications proposing research that will contribute to an improved ability to understand and anticipate the public health and environmental impacts and behavioral drivers of significant changes in energy production and consumption in the United States, particularly those changes associated with advancing toward the deep decarbonization necessary to achieve national and international climate change mitigation objectives and avoid the most significant health, environmental, and economic impacts of climate change. The proposed research is intended to contribute to the development of new insights and predictive tools related to the multimedia, life-cycle impacts of the decarbonization of electricity generation; the electrification of end uses; the adoption of low-carbon emitting, renewable fuels; and the adoption of energy efficiency measures. The proposed research is also intended to contribute to an improved understanding of the drivers of individual, firm (i.e. business), and community decisions that affect energy consumption patterns, including decisions about the adoption of new technologies and energy efficiency measures.

As part of NSF's Cyberinfrastructure Framework for 21st Century Science and Engineering (CIF21) activity, the Directorate for Education and Human Resources (EHR) seeks to enable research communities to develop visions, teams, and capabilities dedicated to creating new, large-scale, next-generation data resources and relevant analytic techniques to advance fundamental research for areas of research covered by EHR programs. Successful proposals will outline activities that will have significant impacts across multiple fields by enabling new types of data-intensive research. Investigators should think broadly and create a vision that extends intellectually across multiple disciplines and that includes-but is not necessarily limited to - areas of research funded by EHR.

In 2013, a new NSF-funded petascale computing system, Blue Waters, was deployed at the University of Illinois.  The goal of this project and system is to open up new possibilities in science and engineering by providing computational capability that makes it possible for investigators to tackle much larger and more complex research challenges across a wide spectrum of domains.  The purpose of this solicitation is to invite research groups to submit requests for allocations of resources on the Blue Waters system. Proposers must show a compelling science or engineering challenge that will require petascale computing resources. Proposers must also be prepared to demonstrate that they have a science or engineering research problem that requires and can effectively exploit the petascale computing  capabilities offered by Blue Waters.  Proposals from or including junior researchers are encouraged, as one of the goals of this solicitation is to build a community capable of using petascale computing.

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. 

Effective September 1, 2013, the Materials Engineering and Processing Program (MEP) (PD 13-8092) will be accepting proposals that address engineering principles as they relate to material processing and performance. This program replaces the Materials Processing and Manufacturing (MPM), Materials and Surface Engineering (MSE), and Structural Mechanics and Materials (SMM) programs. This new MEP program is effectively a merger and evolutionary advance of these three programs. The MPM, MSE and SMM programs will no longer be accepting new proposals1. The Division of Civil, Mechanical, and Manufacturing Innovation (CMM) in Directorate for Engineering (ENG) of the National Science Foundation (NSF) created the Materials Engineering and Processing (MEP) program to support fundamental research addressing the interrelationship of materials processing, structure, properties and/or life-cycle performance for targeted applications. Processing and performance of all material systems are of interest. These include polymers, metals, ceramics, semiconductors, composites, and hybrids thereof. Research driven by scientific hypotheses are encouraged when suitable, and materials in bulk form or focus on special zones such as surfaces or interfaces that are to be used in structural and/or functional applications are appropriate for this program. Analytical, experimental, and numerical studies are supported and collaborative proposals with industry (i.e. Grant Opportunities for Academic Liaison with Industry (GOALI)) are encouraged.

This Funding Opportunity Announcement (FOA) is a new initiative to support the development of cancer-relevant technologies suitable for use in low- and middle-income countries (LMICs).  Specifically, the FOA solicits applications for projects to adapt, apply, and validate existing or emerging technologies into a new generation of user-friendly, low-cost devices or assays that are clinically comparable to currently used technologies for imaging, in vitro detection/diagnosis, or treatment of cancers in humans living in LMICs. Funds will be made available through the UH2/UH3 phased innovation cooperative agreement award mechanism.  Applicants should have a working assay or prototype (not necessarily already capable of cancer applications).  The initial 2-year (or shorter) UH2 exploratory phase will be a feasibility study to demonstrate technical functionality and clinical potential for use in LMIC settings by meeting specific performance milestones.  UH2 projects that have met their milestones will be administratively considered by NCI and prioritized for transition to the UH3 validation phase.  UH3 awards will support improvements and validations of the technologies in the LMIC settings.  The project period for the UH3 phase is up to 3 years.  Projects proposed in response to this FOA will require multidisciplinary efforts to succeed and therefore all applicant teams must include expertise in engineering/assay/treatment development, oncology, global healthcare delivery, and business development.  Investigators responding to this FOA must address both UH2 and UH3 phases.

This program supports fundamental research including combined experiment and theory projects in ceramics (e.g., oxides, carbides, nitrides and borides), glass-ceramics, inorganic glasses, ceramic-based composites and inorganic carbon-based materials. The objective of the program is to increase fundamental understanding and to develop predictive capabilities for relating synthesis, processing, and microstructure of these materials to their properties and ultimate performance in various environments and applications. Research to enhance or enable the discovery or creation of new ceramic materials is welcome. Development of new experimental techniques or novel approaches to carry out projects is encouraged. Topics supported include basic processes and mechanisms associated with nucleation and growth of thin films; bulk crystal growth; phase transformations and equilibria; morphology; surface modification; corrosion, interfaces and grain boundary structure; and defects. The microstructures investigated range from crystalline, polycrystalline, and amorphous to composite and nanostructured materials. 

In 2013, a new NSF-funded petascale computing system, Blue Waters, was deployed at the University of Illinois. The goal of this project and system is to open up new possibilities in science and engineering by providing computational capability that makes it possible for investigators to tackle much larger and more complex research challenges across a wide spectrum of domains. The purpose of this solicitation is to invite research groups to submit requests for allocations of resources on the Blue Waters system. Proposers must show a compelling science or engineering challenge that will require petascale computing resources. Proposers must also be prepared to demonstrate that they have a science or engineering research problem that requires and can effectively exploit the petascale computing capabilities offered by Blue Waters. Proposals from or including junior researchers are encouraged, as one of the goals of this solicitation is to build a community capable of using petascale computing.

We are pleased to announce that the new OARS website is up and running (although the new Research Compliance and Undergraduate Research sections are still in development).   If you haven't had a chance to check it out yet, we hope you will soon.  Once you've visited, we'd be grateful if you'd give us five minutes of your time to let us know how we're doing by completing a brief eight-question survey at https://miamioh.qualtrics.com/SE/?SID=SV_erhRsEFwwWVP6m1 Finally, don't forget to update any bookmarks you may have to material on our old website!

The Office of Fusion Energy Sciences (FES) of the Office of Science (SC), U.S. Department of Energy (DOE), announces its interest in receiving new or renewal grant applications for theoretical and computational research relevant to the U.S. magnetic fusion energy sciences program. Applications selected in response to this FOA will be funded in Fiscal Year 2015, subject to the availability of appropriated funds. The specific areas of interest are: 1. Macroscopic Stability 2. Confinement and Transport 3. Boundary Physics 4. Plasma Heating & Non-inductive Current Drive, and 5. Energetic Particles Specific information about each topical area is included in the Supplementary information section of the full Funding Opportunity Announcement (FOA) document. Due to the limited availability of funds, Principal Investigators with continuing theory grants may not submit a new application in the same topical areas as their existing grant. A Principal Investigator may submit only one application in response to this FOA, but applications can target multiple topical areas. 

The Design of Engineering Material Systems (DEMS) program supports fundamental research intended to lead to new paradigms of design, development, and insertion of advanced engineering material systems. Fundamental research that develops and creatively integrates theory, processing/manufacturing, data/informatics, experimental, and/or computational approaches with rigorous engineering design principles, approaches, and tools to enable the accelerated design and development of materials is welcome. Research proposals are sought that strive to develop systematic scientific methodologies to tailor the behavior of material systems in ways that are driven by performance metrics and incorporate processing/manufacturing. While an emphasis on a specific material system may be appropriate to provide the necessary project focus, techniques developed should transcend materials systems. Ultimately it is expected that research outcomes will be methodologies to enable the discovery of materials systems with new properties and behavior, and enable their rapid insertion into engineering systems.Proposals that focus on modeling, simulation, and prediction of material performance (even when research is coupled with experiments for validation or guidance) without an intellectual emphasis on design are not appropriate for this program and should be submitted to other disciplinary programs.

The Sensors, Dynamics, and Control (SDC) program supports fundamental research on the analysis, measurement, monitoring and control of complex dynamical and structural systems, including development of new analytical, computational and experimental tools, and novel applications to engineered and natural systems. Program objectives are the discovery of new phenomena and the investigation of innovative methods and applications for dynamics, measurement, and control. Transformative research on complex networks, linear and nonlinear discrete or infinite dimensional systems spanning a multitude of time and length scales and physical domains are of interest, as are highly interdisciplinary projects and projects addressing security, resilience and sustainability. Basic research strongly motivated by industry needs or other real-life applications is welcome.The SDC program supports fundamental research on the theories of dynamical systems to uncover novel paradigms for modeling, control and analysis of dynamic phenomena and systems that undergo spatial and temporal evolution with applications crossing interdisciplinary boundaries, along with fundamental studies on stability, phase transitions, and wave propagation in complex and non-local media. Furthermore, the program supports fundamental research on monitoring, analysis, and decision-making processes for integrity monitoring, sensors reliability and safety of complex engineered systems, especially under conditions of uncertainty. Of interest is the investigation of big data (high-volume and high-speed) issues related to virtually-continuous streams of measurements from heterogeneous sensors for continuous systems monitoring. The SDC program also includes fundamental research on control theory and its applications. Topics of current interest include unconventional applications of control; the combined roles of feedback, feedforward and uncertainty; integrated feedback, communication and signal processing; and control conc

The purpose of this Brain Research through Advancing Innovative Neurotechnologies (BRAIN) Initiative is to encourage applications that will develop and validate novel tools to facilitate the detailed analysis of complex circuits and provide insights into cellular interactions that underlie brain function. The new tools and technologies should inform and/or exploit cell-type and/or circuit-level specificity. Plans for validating the utility of the tool/technology will be an essential feature of a successful application. The development of new genetic and non-genetic tools for delivering genes, proteins and chemicals to cells of interest or approaches that are expected to target specific cell types and/or circuits in the nervous system with greater precision and sensitivity than currently established methods are encouraged. Tools that can be used in a number of species / model organisms rather than those restricted to a single species are highly desired. Applications that provide approaches that break through existing technical barriers to substantially improve current capabilities are highly encouraged.

Mark your calendar for the 2015 NIH Regional Seminar on Program Funding and Grants Administration in Baltimore, Maryland - May 6-8, 2015. This two-day seminar, with an optional third day of pre-seminar workshops, is ideal for anyone in the extramural research community who is new to working with NIH grants, including administrators, new and early stage investigators, and grant writers. Registration will open in early 2015.