Federal Science and Technology Grants

The DoD Reconstructive Transplant, Idea Discovery Award is a funding opportunity aimed at supporting innovative, high-risk/high-reward research projects related to reconstructive transplant, with a focus on generating robust data, addressing military health care needs, advancing women's health research, and adhering to rigorous experimental design, with a total budget not exceeding $500,000.

This initiative provides a platform for technology providers, including industry and academic innovators, to showcase their AI and data analytics solutions to government buyers in the Department of Defense for potential procurement.

This funding opportunity provides financial support to state and local governments for improving cybersecurity measures and reducing risks to critical infrastructure.

Agency Description: The Advanced Research Projects Agency Energy (ARPA-E), an organization within the Department of Energy (DOE), is chartered by Congress in the America COMPETES Act of 2007 (P.L. 110-69), as amended by the America COMPETES Reauthorization Act of 2010 (P.L. 111-358), as further amended by the Energy Act of 2020 (P.L. 116-260): (A) to enhance the economic and energy security of the United States through the development of energy technologies that (i) reduce imports of energy from foreign sources; (ii) reduce energy-related emissions, including greenhouse gases; (iii) improve the energy efficiency of all economic sectors; (iv) provide transformative solutions to improve the management, clean-up, and disposal of radioactive waste and spent nuclear fuel; and (v) improve the resilience, reliability, and security of infrastructure to produce, deliver, and store energy; and (B) to ensure that the United States maintains a technological lead in developing and deploying advanced energy technologies. ARPA-E issues this Funding Opportunity Announcement (FOA) under its authorizing statute codified at 42 U.S.C. 16538. The FOA and any cooperative agreements or grants made under this FOA are subject to 2 C.F.R. Part 200 as supplemented by 2 C.F.R. Part 910. ARPA-E funds research on, and the development of, transformative science and technology solutions to address the energy and environmental missions of the Department. The agency focuses on technologies that can be meaningfully advanced with a modest investment over a defined period of time in order to catalyze the translation from scientific discovery to early-stage technology. For the latest news and information about ARPA-E, its programs and the research projects currently supported, see: http://arpa-e.energy.gov/. ARPA-E funds transformational research. Existing energy technologies generally progress on established learning curves where refinements to a technology and the economies of scale that accrue as manufacturing and distribution develop drive improvements to the cost/performance metric in a gradual fashion. This continual improvement of a technology is important to its increased commercial deployment and is appropriately the focus of the private sector or the applied technology offices within DOE. In contrast, ARPA-E supports transformative research that has the potential to create fundamentally new learning curves. ARPA-E technology projects typically start with cost/performance estimates well above the level of an incumbent technology. Given the high risk inherent in these projects, many will fail to progress, but some may succeed in generating a new learning curve with a projected cost/performance metric that is significantly better than that of the incumbent technology. ARPA-E funds technology with the potential to be disruptive in the marketplace. The mere creation of a new learning curve does not ensure market penetration. Rather, the ultimate value of a technology is determined by the marketplace, and impactful technologies ultimately become disruptive that is, they are widely adopted and displace existing technologies from the marketplace or create entirely new markets. ARPA-E understands that definitive proof of market disruption takes time, particularly for energy technologies. Therefore, ARPA-E funds the development of technologies that, if technically successful, have clear disruptive potential, e.g., by demonstrating capability for manufacturing at competitive cost and deployment at scale. ARPA-E funds applied research and development. The Office of Management and Budget defines applied research as an original investigation undertaken in order to acquire new knowledgedirected primarily towards a specific practical aim or objective and defines experimental development as creative and systematic work, drawing on knowledge gained from research and practical experience, which is directed at producing new products or processes or improving existing products or processes. Applicants interested in receiving financial assistance for basic research (defined by the Office of Management and Budget as experimental or theoretical work undertaken primarily to acquire new knowledge of the underlying foundations of phenomena and observable facts) should contact the DOEs Office of Science (http://science.energy.gov/). Office of Science national scientific user facilities (http://science.energy.gov/user-facilities/) are open to all researchers, including ARPA-E Applicants and awardees. These facilities provide advanced tools of modern science including accelerators, colliders, supercomputers, light sources and neutron sources, as well as facilities for studying the nanoworld, the environment, and the atmosphere. Projects focused on early-stage R for the improvement of technology along defined roadmaps may be more appropriate for support through the DOE applied energy offices including: the Office of Energy Efficiency and Renewable Energy (http://www.eere.energy.gov/), the Office of Fossil Energy and Carbon Management (https://www.energy.gov/fecm/office-fossil-energy-and-carbon-management), the Office of Nuclear Energy (http://www.energy.gov/ne/office-nuclear-energy), and the Office of Electricity (https://www.energy.gov/oe/office-electricity). FOA Description: According to the U.S. Environmental Protection Agency (EPA), a circular economy refers to an economy that uses a systems-focused approach and involves industrial processes and economic activities that are restorative or regenerative by design, enables resources used in such processes and activities to maintain their highest value for as long as possible, and aims for the elimination of waste through the superior design of materials, products, and systems. Further, a circular economy reduces material use, redesigns materials, products, and services to be less resource intensive, and recaptures waste as a resource to manufacture new materials and products. Successfully achieving a circular economy requires implementing the above principles to the supply chains of numerous products. Specifically, creating a circular EV battery supply chain focuses on optimizing the full vehicle life cycle. Thus, the emphasis must shift from production and sales within an ownership model to a model focusing on customers mobility needs and access in the form of leasing, as it exists today, vehicle-on-demand (e.g., Zipcar), and mobility-on-demand (e.g., robotaxis). These different business models may coexist but will require increasing collaboration and transparency among different actors, while costs and revenues will be distributed across the supply chain. A circular supply chain offers new revenue streams and business opportunities by providing services to maximize EVs lifetime performance through: Enhancing regular predictive maintenance; Repairing and remanufacturing of battery modules and packs; Improving the reuse and recovery of EOL parts and materials; and Minimizing carbon footprint and maximizing resource efficiency. A circular supply chain also offers opportunities to reduce production and operating costs by: Improving the quality and stability of critical minerals supply chains through cell regeneration, reuse, and recycling; Facilitating rework, reuse, repair, and remanufacture of batteries through modular designs, reversible manufacturing materials and methods; and Reducing asset costs per unit amount of energy delivered owing to the retention of the embedded manufacturing value of batteries, their prolonged lifetime, and the extended use of EVs. The overarching goal of the CIRCULAR program is to successfully translate the above definition of a circular economy to the domestic EV battery supply chain by supporting the development of innovative solutions that can overcome both the technological and economic barriers to broad commercial adoption. CIRCULAR acknowledges that simultaneous advancements in multiple technological domains may be required to accomplish this ambitious objective. Therefore, the program is intentionally structured into four technology development categories designed to converge towards the creation of a domestic circular supply chain for EV batteries. The CIRCULAR program recognizes that conventional recycling is not the only, nor primary, pathway to closing the supply chain loop. Therefore, the primary objective of this program is to catalyze the creation of a circular EV battery supply chain in North America. The program will support the development and deployment of foundational technologies capable of maintaining materials and products in circulation at their highest level of performance and safety for as long as possible. Achieving this goal will directly impact ARPA-E mission areas as follows: Decrease Energy-Related Imports: The CIRCULAR program aims to reduce the import of critical battery materials, cells, packs, and EVs by establishing new supply chain loops within the U.S. Currently, individual steps in the battery supply chain (mining, material processing, cell component assembly, battery cell manufacturing, and recycling) are concentrated mostly outside of the U.S. Reduce Emissions: The CIRCULAR program aims to decrease the domestic energy burden and carbon footprint of the EV battery supply chain by extending the service life of battery cells and packs and by maintaining manufacturing value to the greatest extent possible through regeneration, repair, reuse, and remanufacture. The program will also reduce emissions associated with battery recycling by minimizing the amount of waste and by recycling only pack components that have reached their EOL. Improve Energy Efficiency: The CIRCULAR program aims to minimize energy and material consumption within the battery supply chain and to exploit opportunities to improve energy efficiency through innovative battery design, material regeneration, and/or manufacturing strategies. According to the U.S. Environmental Protection Agency (EPA), a circular economy refers to an economy that uses a systems-focused approach and involves industrial processes and economic activities that are restorative or regenerative by design, enables resources used in such processes and activities to maintain their highest value for as long as possible, and aims for the elimination of waste through the superior design of materials, products, and systems. Further, a circular economy reduces material use, redesigns materials, products, and services to be less resource intensive, and recaptures waste as a resource to manufacture new materials and products. Successfully achieving a circular economy requires implementing the above principles to the supply chains of numerous products. Specifically, creating a circular EV battery supply chain focuses on optimizing the full vehicle life cycle. Thus, the emphasis must shift from production and sales within an ownership model to a model focusing on customers mobility needs and access in the form of leasing, as it exists today, vehicle-on-demand (e.g., Zipcar), and mobility-on-demand (e.g., robotaxis). These different business models may coexist but will require increasing collaboration and transparency among different actors, while costs and revenues will be distributed across the supply chain. A circular supply chain offers new revenue streams and business opportunities22 by providing services to maximize EVs lifetime performance through: Enhancing regular predictive maintenance; Repairing and remanufacturing of battery modules and packs; Improving the reuse and recovery of EOL parts and materials; and Minimizing carbon footprint and maximizing resource efficiency. A circular supply chain also offers opportunities to reduce production and operating costs by: Improving the quality and stability of critical minerals supply chains through cell regeneration, reuse, and recycling; Facilitating rework, reuse, repair, and remanufacture of batteries through modular designs, reversible manufacturing materials and methods; and Reducing asset costs per unit amount of energy delivered owing to the retention of the embedded manufacturing value of batteries, their prolonged lifetime, and the extended use of EVs. To view the FOA in its entirety, please visit https://arpa-e-foa.energy.gov.

The Research Experiences for Teachers (RET) in Engineering and Computer Science program supports authentic summer research experiences for K-14 educators to foster long-term collaborations between universities, community colleges, school districts, and industry partners. With this solicitation, the Directorates for Engineering (ENG) and Computer and Information Science and Engineering (CISE) focus on a reciprocal exchange of expertise between K-14 educators and research faculty and (when applicable) industry mentors. K-14 educators will enhance their scientific disciplinary knowledge in engineering or computer science and translate their research experiences into classroom activities and curricula to broaden their students awareness of and participation in computing and engineering pathways. At the same time, the hosting research faculty will deepen their understanding of classroom practices, current curricula, pedagogy, and K-14 educational environments.

In FY23, the OCRP established a new academy, the Ovarian Cancer Clinical Trial Academy (OCCTA), which will focus on clinical trial research in ovarian cancer. The intent of the OCCTA is to enhance knowledge within next generation of Early-Career Investigators (ECIs) in clinical trial research and to produce effective treatments and cures for ovarian cancer. The OCCTA will bring together established investigators (the Academy Dean and Assistant Dean), established Career Guides (mentors), and a group of ECIs/Scholars to conduct successful, highly productive clinical trials in ovarian cancer. The OCCTA strives to develop successful, highly productive ovarian cancer clinical trialists in a collaborative research and career development environment, providing intensive mentoring, national networking, collaborations, and a peer group for junior clinical trialists. The OCCTA, through its Leadership, provides for professional and leadership development of the ECIs to include skills and competencies needed to execute clinical trials.

This funding opportunity supports researchers in atmospheric science to utilize satellite data for advancing the understanding of precipitation, cloud dynamics, and related processes, particularly through the integration of legacy and current satellite missions.

This funding opportunity supports U.S.-based organizations in developing a centralized hub to advance the use of artificial intelligence and technology in research related to aging and Alzheimer's Disease, fostering collaboration and stakeholder engagement across multiple projects.

This funding opportunity provides financial support to a wide range of organizations, including governments, educational institutions, and nonprofits, to strengthen public health systems and improve responses to infectious disease threats in Bangladesh.

This grant provides funding to U.S. academic institutions to support doctoral students conducting research that addresses critical issues in criminal justice, such as crime prevention and victim services.

This funding opportunity provides financial support to state and territorial governments to enhance their cybersecurity capabilities and resilience against digital threats.

This funding opportunity provides financial support for research projects that enhance data collection and analysis related to breast cancer, specifically targeting gaps in existing clinical studies and involving consumer advocates in the research process.

This fellowship provides financial support for U.S. doctoral students conducting research in marine population dynamics or resource economics, helping them contribute to the conservation and management of marine ecosystems.

The Department of Defense seeks innovative applications to cooperatively partner with eligible entities in the implementation, execution, -development and administration of a Consortium of MSIs and HBCUs to conduct basic, applied and advance research and development efforts at educational institutions pursuant to Section 252 of the FY10 National Defense Authorization Act (NDAA) codified in 10 USC 4144, Research and Education Programs and Activities: Historically Black Colleges and Universities (HBCU) and Minority Serving Institutions of Higher Education.

The intent of this solicitation is to request proposals from organizations who are willing to serve as resource providers within the NSF Advanced Computing Systems and Services (ACSS) program. Resource providers would (1) provide advanced cyberinfrastructure (CI) resources in production operations to support the full range of computational- and data-intensive research across all of science and engineering (S), and (2) ensure democratized and equitable access to the proposed resources. The current solicitation is intended to complement previous NSF investments in advanced computational infrastructure by provisioning resources, broadly defined in this solicitation to include systems and/or services, in two categories: Category I, Capacity Resources: production computational resources maximizing the capacity provided to support the broad range of computation and data analytics needs in S research; and Category II, Innovative Prototypes/Testbeds: innovative forward-looking capabilities deploying novel technologies, architectures, usage modes, etc., and exploring new target applications, methods, and paradigms for S discoveries. Resource Providers supported via this solicitation will be incorporated into NSFs ACSS program portfolio. This program complements investments in leadership-class computing and funds a federation of nationally available HPC resources that are technically diverse and intended to enable discoveries at a computational scale beyond the research of individual or regional academic institutions. NSF anticipates that at least 90% of the provisioned resource will be available to the S community through an open peer-reviewed national allocation process and have resource users be supported by community and other support services. Such allocation and support services are expected to be coordinated through the NSF-funded Advanced Cyberinfrastructure Coordination Ecosystem: Services Support (ACCESS) suite of services, or an NSF-approved alternative as may emerge. If this is not feasible for the proposed resource, proposers must clearly explain in detail why this is the case and how they intend to make the proposed resource available to the national S community. The ACSS Program especially seeks broad representation of PIs (including women, underrepresented minorities, and individuals with disabilities)and institutions (including those that have not historically provided nationally allocatable cyberinfrastructure)in both the community of resource awardees and resources users to continue growing the scale and diversity of the S community.

This funding opportunity provides financial support to organizations and institutions working to implement and promote research findings that improve the lives of individuals with disabilities through better community living, health, and employment outcomes.

This grant provides funding for innovative research to develop organoid systems that can process information and interact with technology, targeting researchers and engineers in fields like biology, computer science, and engineering.

This funding opportunity supports researchers and organizations conducting innovative studies and technology development related to ocean surface topography and its impact on Earth's systems.

This ISO seeks solution summaries and proposals for projects that fall within the general scope of the ARPA-H Scalable Solutions mission office. SSO expands what is technically possible by developing approaches that will leverage an interdisciplinary approach and collaborative networks to address challenges of geography, distribution, manufacturing, data and information, thereby improving health care access and affordability. In the United States, many communities and remote areas lack access to timely and quality health care, which leads to disparities in health outcomes for those populations. Bottlenecks during the manufacturing processes of products and health technologies also lead to delays and limited availability, preventing effective distribution of health care solutions to areas of need, especially in emergencies.ARPA-H SSO seeks solutions to improve the scalability and affordability of health care solutions, bridge gaps in underserved areas, and extend remote access to expertise by developing location-specific interventions, telemedicine solutions, and mobile health clinics. Solutions should focus on rapid innovation and the use of partnerships, as well as flexible distribution networks and streamlined manufacturing processes. The following SSO interest areas categorize the ground-breaking solutions we seek to support:Scalable Technologies and Interventions: Approaches to improve affordability and equitable access to health care that are adaptable to various geographic, demographic, economic contexts and can be rapidly deployed at scale (e.g., drug-repurposing*, telemedicine, point-of-care diagnostics, and modular health care infrastructure). Tailored solutions for the pediatric population that provide parity in access to treatments and other health care interventions with the adult population and adapt to the pediatric patients changing physiology and developmental status over the course of years. Transformational approaches to reduce or eliminate health disparities, including tools and models for product design and care delivery that scale novel approaches in human factors and human-centered design to respond to full diversity of patients. Tools to enable the scaling of provider and institutional capabilities (e.g., school nurses and schools, walk-in clinics, homesteading care) to address unmet health care access needs and expand availability of critical services. Foundational capabilities to accelerate diagnoses and reduce the cost of treatments for rare diseases wherever patients are, without the need for specialized facilities or healthcare expertise.* Solution summaries and proposals that focus on testing drugs for effectiveness for other disease states or use cases, are unlikely to be funded unless including additional R, or providing gains in cost reduction, accessibility, and/or equity.Collaborative Distribution Networks: Methods for standardization, automation, and democratization of complex procedures 5 including, but not limited to, histopathology, rare disease diagnosis and treatment, and surgical interventions to ensure access and delivery to populations diverse in demographics, geographies, and resources at scale. Approaches to enhance delivery of effective healthcare solutions in rural or low resource settings, including but not limited to "last mile delivery, at-home monitoring, imaging, drug delivery, telehealth augmentation, and support for remote medical procedures with limited need for specialized training. Technologies to enable the deployment of critical healthcare resources rapidly, equitably, and securely at scale to the point of need in permissive and non-permissive (i.e., damaged infrastructure, cyber-denied) environments during a public health crisis or natural disaster. Solutions to scale education and training of critical healthcare resources for health care providers and patients to ensure information integrity to prevent negative impacts to resource use/uptake. Innovative information technology, data and analytic products and technologies to enable ordering, inventory management, situational awareness, allocation planning and demand forecasting of critical healthcare resources during a public health crisis or natural disaster.Biomanufacturing Innovations*: Innovative manufacturing technologies and approaches that reduce cost, shorten the timeline for production, advance domestic competitiveness and reduce supply chain risk of biologics, cellular and gene therapies, pharmaceuticals, medical devices and personal protective equipment. New approaches to support predictable, programable biological production of conventional and novel materials reliability at scale in a cost-effective sustainable manner. Novel solutions to reduce the reliance on specialized handling and cold chain management of pharmaceuticals and biologics. Scalable innovations to advance and strengthen biomanufacturing supply chain and resolve bottlenecks including:o Advances in production of active pharmaceutical ingredients, process consumables, and other critical materials (i.e., enzymes, cell lines, etc);o Novel biomanufacturing-related data products, technologies or models to integrate into supply chain situational awareness systems;o Alternative materials and new manufacturing capabilities for personal protective equipment; ando Improvement of capabilities sustainably re-shore manufacturing and utilize a broad array of readily accessible and cost-efficient feedstocks as part of strengthening the local and national industry base. Analytics and novel sensor systems to precisely manage bioproduction, real-time release assays, and predictive capabilities to inform tuning of biological chassis for efficient and effective scale-up of manufacturing to industrial scale.*ARPA-H is not interested in approaches that merely increase capacity reservation.Other high-quality submissions that propose revolutionary technologies that meet the goals of SSO will be considered even if they do not address the topics listed above.Proposals are expected to use innovative approaches to enable revolutionary advances in medicine and healthcare, and the science and technology underlying these areas. While approaches that are disease agnostic are encouraged, ARPA-H welcomes proposals that bring radically new insights to address specific diseases including, but not limited to, cancer, diabetes, neurological diseases, pediatric and maternal/fetal health, infectious diseases, and cardiovascular disease.Specifically excluded are proposals that represent an evolutionary or incremental advance in the current state of the art or technology that has reached the clinical trial stage. An example of this type of proposal might include the request to fund clinical trials of an otherwise developed product. Additionally, proposals directed towards policy changes, traditional education and training, or center coordination, formation, or development, and construction of physical infrastructure are outside the scope of the ARPA-H mission.

This funding opportunity supports partnerships that enhance research and education in astronomy and astrophysics, particularly for institutions serving historically underrepresented groups, by providing authentic research experiences and fostering an inclusive environment.