Research grants

The NSF EPSCoR Graduate Fellowship Program (EGFP) provides an opportunity for applicants who received the distinction of GRFP Honorable Mention no more than three years before the proposal due date to be named NSF EPSCoR Graduate Fellows and obtain financial support for their graduate education at an institution in an EPSCoR jurisdiction. EGFP aims to enhance the capacity and competitiveness of EPSCoR jurisdictions by providing funding to graduate degree-awarding institutions to support NSF EPSCoR Graduate Fellows as they pursue graduate degrees in the disciplines specified by the NSF Directorates and Office that are participating in the EGFP funding program. Fellows may pursue degrees in field that differ from the field or sub-field of studythat the GRFP Honorable Mention recipients previously listed in their GRFP application. EGFP awards will be made to institutions in EPSCoR jurisdictions. Awards will provide three years of stipend and associated cost-of-education allowance for each NSF EPSCoR Graduate Fellow. Stipends must be budgeted at the level of $37,000 per year per Fellow and cost-of-education allowances must be budgeted at the level of $16,000 per year per Fellow. A total of three years of support must be budgeted per Fellow. Each Fellow must be given up to five years to utilize the support. Awardees will administer the awards such that the Fellows receive the full stipend amount and the institution retains the full cost-of-education allowance during the three years that each Fellow receives support.All submissions must request support for a minimum of three Fellows.

PLEASE NOTE:  No submissions through Grants.gov will be accepted. All submissions must follow SAM.gov instructions. For full opportunity announcement reference the SAM.gov link.

NSF-supported science and engineering research increasingly relies on cutting-edge infrastructure. With its Major Research Instrumentation (MRI) program and Major Multi-user Facilities ("Major Facilities") projects, NSF supports infrastructure projects at the lower and higher range of infrastructure project costs, Foundation-wide, across science and engineering research disciplines. The Foundation-wide Mid-scale Research Infrastructure opportunity is intended to provide NSF with an agile, Foundation-wide process to fund experimental research capabilities in the mid-scale range between MRI and Major Multi-user Facilities. NSF defines Research Infrastructure (RI) as any combination of facilities, equipment, instrumentation, or computational hardware or software, and the necessary human capital in support of the same. Major facilities and mid-scale projects are subsets of research infrastructure. The NSF Mid-scale Research Infrastructure-1 Program (Mid-scale RI-1) supports either design activities or implementation of unique and compelling RI projects. Mid-scale implementation projects may include any combination of equipment, instrumentation, cyberinfrastructure, broadly used large scale datasets and the personnel needed to successfully commission the project. Mid-scale RI-1 design activities include the design efforts intended to lead to eventual implementation of a mid-scale class RI project. Mid-scale RI-1 projects should involve the training of a diverse workforce engaged in the design and implementation of STEM research infrastructure. Mid-scale RI-1 projects should directly enable advances in any of the research domains supported by NSF. Projects may also include upgrades to existing research infrastructure. Mid-scale RI-1 emphasizes strong scientific merit, a response to an identified need of the research community and/or fulfillment of a national need to enable U.S. researchers to be competitive in a global research environment. Well-conceived technical and management plans are essential for both design and implementation proposals, as are well-developed plans (e.g., mentoring and professional development) for student training and the involvement of a diverse STEM workforce in all aspects of mid-scale design and/or implementation activities. The inclusion of individual project participants that will lead to a supportive working environment is especially encouraged at all levels of the project team. Within Mid-scale RI-1, proposers may submit two types of projects, “Implementation” (e.g., acquisition and/or construction) or “Design”. The “Design” track is intended to facilitate progress toward readiness for a mid-scale range implementation project. Both Implementation projects and Design activities may involve new or upgraded research infrastructure. Mid-scale RI-1 "Implementation" projects may have a total project cost ranging from $4 million up to but not including $20 million. Mid-scale RI-1 "Design" activities may request less than $4 million, with a minimum request of $400,000 and a maximum request up to but not including $20 million, as appropriate, to prepare for a future mid-scale range implementation project. Note: Successful award of a Mid-scale RI-1 design activity does not imply NSF's commitment to the future implementation of the project being designed, nor is a Mid-scale RI-1 design award required for the submission of an implementation project. The Mid-scale RI-1 Program seeks to broaden the representation of PIs and institutions in its award portfolio, including a geographically diverse set of institutions (especially those in EPSCoR jurisdictions). Proposals submitted by, or involving partnerships between institutions are encouraged. Participation in this opportunity is encouraged for the full spectrum of diverse talent society has to offer to include PIs who are women, early-career researchers, persons with disabilities, or members of other groups underrepresented in STEM. To improve participation in science and engineering research for persons with disabilities, Mid-scale RI-1 encourages PIs to incorporate accessibility as part of Mid-scale RI-1 design activity and implementation projects. Please consult NSF's Research Infrastructure Guide, or RIG (available at https://www.nsf.gov/bfa/lfo/lfo_documents.jsp ), for definitions of certain terms used in this solicitation, such as the Project Execution Plan (PEP) and Design and Execution Plan (DEP). The RIG provides guidance specific to Mid-scale Research Infrastructure Projects, including references to other parts of the RIG as needed. Note that PEP or DEP should be appropriately scaled for the complexity of the project and may not require all of the elements described in the RIG. Mid-scale research infrastructure projects with total project costs beyond the Mid-scale RI-1 Program limit are separately solicited through the Mid-scale RI-2 Program. Proposals to the Mid-scale RI-1 Program with total project costs outside of this solicitation's budgetary limits, either during initial submission or after cost analyses/revisions during subsequent review, are subject to return without further review.

The ARO is soliciting proposals for Staff Research Program opportunities. The purpose of the program is to enable ARO scientific staff to maintain and expand professional competence in support of fulfilling the ARO mission through the conduct of hands-on, basic research. The staff research will be performed collaboratively with institutions external to ARO. Staff research efforts will involve scientific study directed toward advancing the state-of-the-art or increasing knowledge and scientific understanding in engineering, physical, life and information sciences, when there is an intersection with the interests and capabilities of the participating external institutions in these basic research areas. Protection of Mission Integrity: The primary role of the ARO scientific staff is to objectively assess and fund extramural research at numerous institutions across the U.S. and throughout the world. Since it is vitally important that the ARO be impartial in its actions, ARO scientists cannot engage in activities that could compromise the perceived objectivity of that scientist with respect to the institution, or with respect to the areas of science/engineering that they are responsible for as Program Managers. Consequently, ARO Program Managers will be disqualified from taking official actions regarding any institution at which that PM conducts Staff Research. Staff research will be conducted, directed and managed by an ARO scientist at the institution's laboratory facilities or field research sites, in collaboration with a PI designated by the institution. ARO scientists will not be named as a PI on any proposal or resulting award. Results of the Staff Research Program may include publication or co-authorship of research results and presentation at scientific forums, and contribute to the education and training of students, in accordance with the terms of the cooperative agreement. NOTE: ARO scientific staff will seek out a collaborating institution to engage in staff research as opportunities arise and at the discretion of ARO.

The Division of Environmental Biology (DEB) Coresupports research and training on evolutionary and ecological processes acting at the level of populations, species, communities, ecosystems, macrosystems, and biogeographic extents. DEB encourages research that elucidates fundamental principles that identify and explain the unity and diversity of life and its interactions with the environment over space and time. Research may incorporate field, laboratory, or collection-based approaches; observational or manipulative studies; synthesis activities; phylogenetic discovery projects; or theoretical approaches involving analytical, statistical, or computational modeling. Proposals should be submitted to the core clusters ( Ecosystem Science , Evolutionary Processes , Population and Community Ecology , and Systematics and Biodiversity Science ). DEB also encourages interdisciplinary proposals that cross conceptual boundaries and integrate over levels of biological organization or across multiple spatial and temporal scales.Research addressing ecology and ecosystem science in the marine biome should be directed to the Biological Oceanography Program in the Division of Ocean Sciences; research addressing evolution and systematics in the marine biome should be directed to the Evolutionary Processes or Systematics and Biodiversity Science programs in DEB.

The Defense Security Cooperation Agency’s (DSCA) Defense Security Cooperation University (DSCU) promotes access to and production of knowledge on security cooperation. Security cooperation refers to “all Department of Defense (DoD) interactions with foreign security establishments that build and develop allied and partner security capabilities and capacity for self-defense and multinational operations, provide the Armed Forces of the United States with access to the foreign country during peacetime or a contingency operation, and build relationships that promote specific United States security interests” (Joint Publication 3-20, Security Cooperation, 1-2; see also 10 USC § 16, “Security Cooperation”).  Evidence-, theory, and data-building activities that contribute to the body of knowledge on security cooperation or irregular warfare, and that result in lessons that can be applied to practice, are the primary focus of this notice of funding opportunity (NFO). Research products sponsored through this NFO must be unclassified and publicly accessible. DSCU expects awardees to participate in conferences, seminars, focus groups and events, and to make final research products and supporting data (if applicable) easily accessible to the public, in order to enhance dissemination of research findings and facilitate application of lessons learned in areas of policy, practice, and workforce professionalization. The DSCU research grant program, conducted pursuant to 10 USC § 4001 and 10 USC § 384(g), is generally open to a broad range of researchers, although individual DSCU components may have restrictions on who may receive grants. Please see the full NFO for complete details.

The Biomechanics and Mechanobiology (BMMB) program is part of the Mechanics of Materials cluster within the Division of Civil, Mechanical, and Manufacturing Innovation. The BMMB program supports fundamental and transformative research that advances our understanding of engineering biomechanics and/or mechanobiology. The program emphasizes the study of biological mechanics across multiple domains, from sub-cellular to whole organism. Distinct from conventional engineering materials, the program encourages the consideration of diverse living tissues as smart materials that are self-designing. BMMB projects must have a clear biological component, a clear mechanics component, and must improve our understanding of the mechanical behavior of a living system. Investigations of the mechanical behavior of biological molecules, cells, tissues, and living systems are welcome. An important concern is the influence of in vivo mechanical forces on cell and matrix biology in the histomorphogenesis, maintenance, regeneration, repair, and aging of tissues and organs. The program is also interested in efforts to translate recent biomechanical and mechanobiological discoveries into engineering science. Multiscale mechanics approaches are encouraged but not required. Projects may include theoretical, computational, or experimental approaches, or a combination thereof. NSF does not support clinical trials; however, feasibility studies involving human volunteers or animal subjects may be supported if appropriate to the scientific objectives of the project. Proposals should address the novelty and/or potentially transformative nature of the proposed work compared to previous work in the field. Also, it is essential to address why the proposed work is important in terms of engineering science, and to state the potential impact of success in the research on society and/or industry. Innovative proposals outside of these specific areas of biomechanics and mechanobiology will be considered. However, prior to submission of particularly unique topics, it is strongly recommended that Principal Investigators (PIs) contact the program director to discuss how the proposed work fits within the scope of the program and avoid the possibility of the proposal being returned without review. Related programs also fund certain aspects of biomechanics and mechanobiology research, and PIs are encouraged to examine these to find the appropriate program for submission. Proposals with a heavy emphasis on tissue engineering or developing validated models of tissue and organ systems should consider the Engineering of Biomedical Systems (EBMS) program.Projects addressing biological questions about the physiological mechanisms and structural features of organisms should consult the Physiological Mechanisms & Biomechanics (PMB) program.Projects elucidating aspects of neural control may consider the Perception, Action, & Cognition (PAC) program or the Mind, Machine, and Motor Nexus (M3X) program if the project contains work relevant to human-machine interaction. Projects in rehabilitation engineering should consider the Disability and Rehabilitation Engineering (DARE) program. Projects focused on fundamental research related to design, characterization, and modification of biomaterials should consider the Biomaterials (BMAT) program. Manufacturing systems proposals should consider the Advanced Manufacturing (AM) program. Work on the interplay between structure, dynamics, and function of biomolecules without advancing our understanding of the mechanics of a living system should consider the Molecular Biophysics program. Researchers who believe their work may span multiple programs are particularly encouraged to contact the cognizant program directors well in advance of submission. The duration of unsolicited proposal awards is generally up to three years; proposals for a shorter duration are welcome. Single-investigator award budgets typically include support for one graduate student (or equivalent trainee) and up to one month of PI time per year (awards for multiple investigator projects are typically larger). Proposal budgets or durations that are much larger than typical should be discussed with the program director prior to submission. Proposers can view budget amounts and other information from recent awards made by this program via the “What Has Been Funded (Recent Awards Made Through This Program, with Abstracts)” link towards the bottom of this page.

The Established Program to Stimulate Competitive Research (EPSCoR) is designed to fulfill the mandate of the National Science Foundation (NSF) to promote scientific progress nationwide. NSF EPSCoR facilitates the establishment of partnerships among academic institutions, government, industry, and non-profit sectors that are designed to promote sustainable improvements in an EPSCoR-eligible jurisdiction’s research infrastructure, Research and Development (R&D) capacity, and R&D competitiveness. Eligibility to participate in NSF EPSCoR funding opportunities, including the EPSCoR Workshop Opportunities program, is described on the EPSCoR website (see criteria for eligibility link ). EPSCoR welcomes proposals for workshops only from institutions within EPSCoR-eligible jurisdictions (i.e. states, territories, commonwealths). These workshops must focus on innovative ways to address multi-jurisdictional efforts on themes of regional or national importance with relevance to the goals and mission of NSF and EPSCoR .

The objective of this Agreement is to advance historic preservation at the local level by establishing a task agreement between the National Park Service and the National Alliance of Preservation Commissions (NAPC) to provide training opportunities, promote the Federal Certified Local Government program, and strengthen local preservation commissions by providing bi-annual State Certified Local Government Coordinator Training

Through this solicitation, the Antarctic Sciences Section (ANT) of the Office of Polar Programs (OPP) funds cutting-edge research that requires logistical support from the U.S. Antarctic Program (USAP)and: Improves understanding of interactions among the Antarctic region and global systems. Improves understanding of the dynamic linkages among processes operating in the Antarctic and Southern Ocean and linkages to global Earth systems, which helps inform decision making regarding environmental change. Advances fundamental understanding of Earth systems and the biological, geochemical, and physical processes in the Antarctic and Southern Ocean as drivers and responders to changes on a global scale. Expands fundamental knowledge of Antarctic systems, biota, and processes. Utilizes the unique characteristics of the Antarctic region as a science observing platform. Builds capacity and enhances the US workforce for polar-related science. Antarctic fieldwork is supported only for research that must be performed, or is best performed, in Antarctica.Proposers that do NOTrequire USAP logistical support should consult the Antarctic Sciences web page for current opportunities. NSF is currently undertaking a planned multiyear program of essential maintenance and upgrade projects, with the goal of ensuring that researchers continue to have access to world-leading Antarctic facilities. The need to support this important work necessarily places some limitations on the logistical support that can currently be provided for new projects. Proposers should comply with the guidance set out below in the Program Description regarding the USAP logistical support that is available. No other USAP resources may be requested.

The Naval Air Warfare Center Aircraft Division (NAWCAD) is interested in receiving white papers for Research and Development projects which offer potential for advancement and improvement of NAWCAD operations. See attachment, FY25 NAWCAD Office-Wide N00421-25-S-0001, for further details.

This Broad Agency Announcement (BAA), which sets forth research areas of interest to the United States Army Research Institute for the Behavioral and Social Sciences (ARI), is issued under the provisions of paragraph 6.102(d)(2) and 35.016 of the Federal Acquisition Regulation (FAR), which provides for the acquisition of basic and applied research and that part of development not related to the development of a specific system or hardware procurement through the competitive selection of proposals, and 10 U.S.C. 4001, 10 U.S.C. 4021, and 10 U.S.C. 4022, which provide the authorities for issuing awards under this announcement for basic and applied research. Proposals submitted in response to this BAA and selected for award are considered to be the result of full and open competition and in full compliance with the provisions of Public Law 98-369, "The Competition in Contracting Act of 1984" and subsequent amendments. ARI is the Army’s lead agency for the conduct of research, development, and analyses for Army readiness and performance via research advances and applications of the behavioral and social sciences that address personnel, organization, and Soldier and leader development issues. Programs funded under this BAA include basic research, applied research, and advanced technology development that can improve human performance and Army readiness. Funding of research and development (R&D) within ARI areas of interest will be determined by funding constraints and priorities set during each budget cycle. Those contemplating submission of a proposal are encouraged to contact the ARI Technical Point of Contact (TPOC) identified in Section G of this BAA or the responsible ARI Manager noted at the end of the technical area entry (Part II Section A of this BAA) to determine whether the proposed R&D warrants further inquiry. If the proposed R&D warrants further inquiry and funding is available, submission of a white paper or proposal will be entertained. The recommended three-step sequence is (1) initial contact with the ARI TPOC or responsible ARI Manager, (2) white paper submission, (3) proposal submission. This sequence allows earliest determination of the potential for funding and minimizes the labor and cost associated with submission of proposals that have minimal probability of being selected for funding. Costs associated with white paper or proposal submissions in response to this BAA are not considered allowable direct charges to any resulting award. These costs may be allowable expenses to normal bid and proposal indirect costs specified in FAR 31.205-18. Applicants submitting proposals are cautioned that only a Government Contracting or Grants Officer may obligate the Government to any agreement involving expenditure of Government funds. To be eligible for an award under this announcement, a prospective awardee must meet certain minimum standards pertaining to financial resources and responsibility, ability to comply with the performance schedule, past performance, integrity, experience, technical capabilities, operational controls, and facilities. In accordance with Federal statutes, regulations, and Department of Defense (DoD) and Army policies, no person on grounds of race, color, age, sex, national origin, or disability shall be excluded from participation in, be denied the benefits of, or be subjected to discrimination under any program or activity receiving financial assistance from the Army.

The far-reaching impact and rate of innovation in the computer and information science and engineering fields has been remarkable, generating economic prosperity and enhancing the quality of life for people throughout the world. More than a decade ago, the National Science Foundation’s (NSF) Directorate for Computer and Information Science and Engineering (CISE) established the Expeditions in Computing (Expeditions) program to build on past successes and provide the CISE research and education community with the opportunity to pursue ambitious, fundamental research agendas that promise to define the future of computing and information. In planning Expeditions projects, investigators are strongly encouraged to come together within or across departments or institutions to combine their creative talents in the identification of compelling, transformative research agendas that look ahead by at least a decade and promise disruptive innovations in computer and information science and engineering for many years to come. Now funded at levels up to $15,000,000 for seven years, Expeditions projects represent some of the largest single investments currently made by the CISE directorate. Together with the Science and Technology Centers and the National Artificial Intelligence Research Institutes that CISE supports, Expeditions projects form the centerpiece of the directorate's center-scale award portfolio. With awards funded at levels that promote the formation of large research teams, CISE recognizes that concurrent research advances in multiple fields or sub-fields are often necessary to stimulate deep and enduring outcomes. The awards made in this program will complement research areas supported by other CISE programs, which target particular computer and information science and engineering fields. Additionally, CISE offers Innovation Transition (InTrans) awards for teams nearing the end of their Expeditions as well as Secure and Trustworthy Cyberspace (SaTC) and Cyber-Physical Systems (CPS) Frontier projects. The goal of InTransis to continue the long-term vision and objectives of CISE’s center-scale projects. Through InTrans awards, CISE will provide limited funds to match industry support.

Pioneering Aerospace Capabilities, Engineering and Research (PACER)

The Plant Genome Research Program (PGRP) supports genome-scale research that addresses challenging questions of biological, societal and economic importance. PGRP encourages the development of innovative tools, technologies, and resources that empower a broad plant research community to answer scientific questions on a genome-wide scale. Emphasis is placed on the scale and depth of the question being addressed and the creativity of the approach. Data produced by plant genomics should be usable, accessible, integrated across scales, and of high impact across biology. Training, broadening participation, and career development are essential to scientific progress and should be integrated in all PGRP-funded projects. Two funding tracks are currently available: RESEARCH-PGR TRACK: Genome-scale plant research to address fundamental questions in biology, including processes of economic and/or societal importance. TRTech-PGR TRACK: Tools, resources, and technology breakthroughs that further enable functional plant genomics.

The Water, Landscape, and Critical Zone Processes program supports research on the Earth’s near-surface environment and how that environment responds to change. The Program focuses on the complex interplay amongst and between hydrologic, geomorphic, and geochemical processes and how they regulate the structure and function of the Earth’s near surface. These processes drive weathering and soil development, control water availability and quality, and help regulate the Earth’s climate system, all of which are important for natural resource sustainability and mitigation of natural hazards. It is expected that the research funded in this program will advance fundamental knowledge in Earth surface processes, leading to transformational discoveries in Earth Sciences.

To support activities that develop, expand, strengthen, or sustain NIST partnership programs and/or support the conduct of research or a recipient's portion of collaborative research in a variety of areas including, but not limited to: Metrology; S tandards; N anotechnology; A rtificial I ntelligence; A dvanced C ommunications; A dvanced M anufacturing; P romotion of U.S. innovation and industrial competitiveness; M easurements in S ciences; N eutron R esearch; and enhancing coordination of the U.S. S tandards S ystem with government and private sector organizations.

Materials Research is the field of science where physics, chemistry, materials science, and engineering naturally converge in the pursuit of the fundamental understanding of the properties of materials and the phenomena they host. Materials are abundant and pervasive, serving as critical building blocks in technology and innovation. Materials Research impacts life and society, as it shapes our understanding of the material world and enables significant advances spanning the range from nanoelectronics to health-related fields. The development and deployment of advanced materials are major drivers of U.S. economic growth. Research supported by the Division of Materials Research (DMR) focuses on advancing the fundamental understanding of materials, materials discovery, design, synthesis, characterization, properties, and materials-related phenomena. DMR awards enable understanding of the electronic, atomic, and molecular structures, mechanisms, and processes that govern nanoscale to macroscale morphology and properties; manipulation and control of these properties; discovery of emerging phenomena of matter and materials; and creation of novel design, synthesis, and processing strategies that lead to new materials with unique characteristics. These discoveries and advancements transcend traditional scientific and engineering disciplines. Projects supported by DMR are not only essential for the development of future technologies and industries that address societal needs, but also for the preparation of the next generation of materials researchers. Additional Information Eligibility rules apply for submissions; please see Section II. Program Description, Section IV. Eligibility Information, and Section V.A Proposal Preparation Instructions

The Structure and Physics of the Solid Earth Program (SPSE) aims to advance fundamental knowledge about the ongoing dynamical processes over the age of the Earth that evolve the structure of planet Earth and underpin geohazards. SPSE supports research at all temporal and spatial scales, from the Earth's core to its crust. Through laboratory, field, theoretical, and computational studies, the program encompasses a wide range of disciplines including structural geology, tectonics, and geophysics. Research in these areas can help improve our understanding of natural hazards including earthquakes and mass flows, as well as Earth’s formation and its magnetic field.

MCB supports research that promises to uncover the fundamental properties of living systems across atomic, molecular, subcellular, and cellular scales. The program gives high priority to projects that advance mechanistic understanding of the structure, function, and evolution of molecular, subcellular, and cellular systems, especially research that aims at quantitative and predictive knowledge of complex behavior and emergent properties. MCB encourages research exploring new concepts in molecular and cellular biology, while incorporating insights and approaches from other scientific disciplines, such as chemistry, computer science, engineering, mathematics, and physics, to illuminate principles that govern life at the molecular and cellular level. MCB also encourages research that exploits experimental and theoretical approaches and utilizes a diverse spectrum of model and non-model animals, plants, and microbes across the tree of life. Proposals that pursue potentially transformative ideas are welcome, even if these entail higher risk. This solicitation calls for proposals in research areas supported by the four MCB core clusters, including: (i) structure, dynamics, and function of biomolecules and supramolecular assemblies, especially under physiological conditions ( Molecular Biophysics ); (ii) organization, processing, expression, regulation, and evolution of genetic and epigenetic information ( Genetic Mechanisms ); (iii) cellular structure, properties, and function across broad spatiotemporal scales ( Cellular Dynamics and Function ); and (iv) systems and/or synthetic biology to study complex interactions through modeling or manipulation or design of living systems at the molecular-to-cellular scale ( Systems and Synthetic Biology ). All MCB clusters prioritize projects that integrate across scales, investigate molecular and cellular evolution, synergize experimental research with computational or mathematical modeling, and/or develop innovative, broadly applicable methods and technologies. Projects that bridge the intellectual edges between MCB clusters are welcome. Projects that integrate molecular and cellular biosciences with other subdisciplines of biology are also welcome through the new Integrative Research in Biology (IntBIO) track. Regarding health-related challenges, NSF supports basic research in all areas of the biological sciences and recognizes that this foundational research is likely to impact many different areas, including human health. MCB celebrates all the biological science discoveries funded through MCB awards that have had major impacts on health, environment, energy, food production, and other applications. Nevertheless, research focused exclusively on understanding human diseases and their treatment is normally outside of the scope offunding and will be returned without review unless that research significantly advances other fields such as engineering, computer science, or the mathematical and physical sciences.

The Foundational Research in Robotics (FRR) program, jointly led by the CISE and ENG Directorates, supports research on robotic systems that exhibit significant levels of both computational capability and physical complexity. For the purposes of this program, a robot is defined as intelligence embodied in an engineered construct, with the ability to process information, sense, plan, and move within or substantially alter its working environment. Here intelligence includes a broad class of methods that enable a robot to solve problems or to make contextually appropriate decisions and act upon them. The program welcomes research that considers inextricably interwoven questions of intelligence, computation, and embodiment. Projects may also focus on a distinct aspect of intelligence, computation, or embodiment, as long as the proposed research is clearly justified in the context of a class of robots. The focus of the FRR program is on foundational advances in robotics. Robotics is a deeply interdisciplinary field, and proposals are encouraged across the full range of fundamental engineering and computer science research challenges arising in robotics. To be responsive to the FRR program, each proposal should clearly articulate the following three points: The focus of the research project should be a robot or a class of robots, as defined above. [Is there a robot?] The goal of the project should be to endow a robot or a class of robots with new and useful capabilities or to significantly enhance existing capabilities. [Will a robot gain a new or significantly improved capability?] The intellectual contribution of the proposed work should address fundamental gaps in robotics. [Is robotics essential to the intellectual merit of the proposal?] Meaningful experimental validation on a physical platform is encouraged. Projects that do not represent a direct fundamental contribution to the science of robotics or are better aligned with other existing programs at NSF should not be submitted to the FRR program. Potential investigators are strongly encouraged to discuss their projects with an FRR Program Officer before submission. Non-compliant proposals may be returned without review.

The Environmental Engineering program is part of the Environmental Engineering and Sustainability cluster, which also includes 1) the Nanoscale Interactions program; and 2) the Environmental Sustainability program. Environmental engineering is an interdisciplinary field that applies chemical, biological, and physical scientific principles to protect human and ecological health. The goal of the Environmental Engineering program is tosupport potentially transformative fundamental research that applies scientific and engineering principles to 1) prevent, minimize, or re-use solid, liquid, and gaseous discharges of pollution to soil, water, and air by closing resource loops or through other measures; 2) mitigate the ecological and human-health impacts of such releases by smart/adaptive/reactive amendments or manipulation of the environment, and 3) remediate polluted environments through engineered chemical, biological, and/or geo-physical processes. Integral to achieving these goals is a fundamental understanding of the transport and biogeochemical reactivity of pollutants in the environment. Therefore, research on environmental micro/biology, environmental chemistry, and environmental geophysics may be relevant providing the research has a clear objective of protecting human and ecological health. Major areas of interest include (but are not limited to): Building afuture without pollution or waste: Investigation of innovative biogeochemical processes that prevent or minimize the production of waste; waste valorization and other research that will lead to new technologies toextract resources from waste streams to close the resource loop. Sustainable supply and protection ofwater: Investigation of innovative biogeochemical processesthat remove, biologically or chemically transform, and/or prevent therelease of contaminants in surface and groundwater; innovative processesfor recovery of water, nutrients, and other resources from wastewater,saline water, or brines; innovative approaches to smart and adaptive management of surface water, groundwater, and urban watersheds and storm water to maintain/improve quality and prevent downstream impacts from nutrients and other water constituents. Environmentalchemistry, fate, and transport of nutrients and contaminants of emergingconcern in air, water, soils, and sediments:Investigation of transport and biogeochemical reactivity in theenvironment; environmental forensics to identify sources and reaction pathways; field- and laboratory scale experimental research that bridgesgaps between data and predictions from molecular, continuum, and field-scale modeling. Environmentalengineering of the built environment: Research to understand the biogeochemical reactivity of the builtenvironment with the goal of enhancing and improving human and ecological health; research that will lead to new technologies to improve outdoor and indoor air quality; research to understand how drinking water and wastewater chemical characteristics and microbial community structure impact or are affected by water quality and human health. NOTE: Proposals with a scientific focus on chemical or physical separation processes (for example, materials or processes for reverse osmosis, membrane distillation, and hypo-filtration) should be submitted to the Interfacial Engineering program (CBET 1417). Proposals that seek to advance fundamental and quantitative understanding of the behaviors of nanomaterials and nanosystems should be submitted to the Nanoscale Interactions program (CBET 1179). Proposals focused on in vitro molecular-level environmental chemistry research should be submitted to Environmental Chemical Sciences program (CHE-ECS 6882). Proposals focusing on industrial ecology, green engineering, and ecological/earth systems engineering should be submitted to the Environmental Sustainability program (CBET 7643). Proposals whose main research focus is on materials development, sensors, or environmental monitoring that do not seek to understand biogeochemical reactivity mechanisms or treatment efficiency are not encouraged and may be returned without review. Innovative proposals outside of these specific interest areas may be considered. However, prior to submission, it is recommended that the PI contact the program director to avoid the possibility of the proposal being returned without review. INFORMATION COMMON TO MOST CBET PROGRAMS Proposals should address the novelty and/or potentially transformative nature of the proposed work compared to previous work in the field. Also, it is important to address why the proposed work is important in terms of engineering science, as well as to also project the potential impact on society and/or industry of success in the research. The novelty or potentially transformative nature of the research should be included, as a minimum, in the Project Summary of each proposal. The duration of unsolicited proposal awards in CBET is generally up to three years. Single-investigator award budgets typically include support for one graduate student (or equivalent) and up to one month of PI time per year(awards for multiple investigator projects are typically larger). Proposal budgets that are much larger than typical should be discussed with the program director prior to submission. Proposers can view budget amounts and other information from recent awards made by this program via the “What Has Been Funded (Recent Awards Made Through This Program, with Abstracts)” link towards the bottom of this page. Faculty Early Career Development(CAREER)program proposals are strongly encouraged. Award duration is five years. The submission deadline for Engineering CAREER proposals is in July every year. Learn more in the CAREER program description . Proposals for Conferences, Workshops, and Supplements: PIs are strongly encouraged to discuss their requests with the program director before submission of the proposal. Grants forRapid Response Research(RAPID)andEArly-concept Grants for Exploratory Research(EAGER)are also considered when appropriate.Please note that proposals of these types must be discussed with the program director before submission.Grant Opportunities for Academic Liaison with Industry (GOALI)proposals that integrate fundamental research with translational results and are consistent with the application areas of interest to each program are also encouraged.Please note that RAPID, EAGER, and GOALI proposals can be submitted anytime during the year. Details about RAPID, EAGER, and GOALI are available in the Proposal & Award Policies & Procedures Guide(PAPPG), Part 1, Chapter II, Section E: Types of Proposals . Compliance: Proposals that are not compliant with the Proposal & Award Policies & Procedures Guide (PAPPG) will be returned without review.

TheCombustion and Fire Systemsprogram is part of the Transport Phenomena cluster, which also includes 1) theFluid Dynamicsprogram; 2) theParticulate and Multiphase Processesprogram; and 3) theThermal Transport Processesprogram. The goal of theCombustion and Fire Systemsprogram is to create new knowledge to support advances in clean energy, climate change mitigation, a cleaner environment and public safety. The program endeavors to createfundamental scientific knowledge that is needed for safe, clean and useful combustion applications and for mitigating the effects of fire.The program aims to identify and understand the controlling basic principles and to use that knowledge to create predictive capabilities for designing and optimizing practical combustion devices and understanding fire. Important outcomesfor this program include: broad-based tools — experimental, theoretical, andcomputational — that can be applied to a variety of problems in combustion technologies and fire; science and technology for clean and efficient generation of power; discoveries that enable clean environments (for example, by reduction in combustion-generated pollutants); and enhanced public safety and climate change mitigation through research on wildland and building fire growth, inhibition, and suppression. Research areas of interest for this program include: Basic combustion science: Combustion of gas, liquid, and solid fuels over abroad range of temperatures, pressures, and compositions; combustion at supercritical conditions; advanced propulsion concepts; flame synthesis ofmaterials; integration of fuel design and combustion; control of reaction pathways; development of chemical kinetics models, analytical and numerical predictive methods, and advanced diagnostic tools. Combustionscience related to clean energy: Increasing efficiency and reducing pollution; production and use of renewable and/or carbon-free fuels; biomass pyrolysis, gasification, and oxidation; technologies such as oxy-fuel combustion and chemical looping combustion for carbon capture. Fireprevention: Improved understanding of building and wildland fires to prevent their spread, inhibit their growth, and suppress them; prediction and mitigation of fires in the wildland-urban interface. Turbulence-chemistry interactions:Fundamental understanding of turbulent flow interactions with finite-rate chemical kinetic pathways at high Reynolds and Karlovitz number conditions, including but not limited to: (1) fundamental experiments to generate physico-chemical data to reduce theuncertainty of combustion chemistry and turbulent combustion models; (2)spatially/temporally well-resolved, multi-scale/multi-physics computations;novel approaches of developing embedded multi-scale direct numericalsimulation (DNS) of complex geometries and data-assimilations forincorporating measured data from the state-of-art in situ diagnostic approaches; (3) other innovative approaches on development and validation of predictive computational methods. NOTE: This is an NSF-AFOSR (Air Force Office of Scientific Research) joint funding area. Proposals will be jointly reviewed by NSF and AFOSR using the NSF merit reviewprocess.Actual funding format and agency split for an award(depending on availabilityof funds) will be determined after the proposal selection process. The AFOSR program that participates in this initiative is the program on Energy, Combustion, and Nonequilibrium Thermodynamics. Innovative proposals outside of these specific interest areas may be considered.However, prior to submission, it is recommended that the Principal Investigator contact the program director to avoid the possibility of the proposal being returned without review. INFORMATION COMMON TO MOST CBET PROGRAMS Proposals should address the novelty and/or potentially transformative nature of the proposed work compared to previous work in the field.Also, it is important to address why the proposed work is important in terms of engineering science, as well as to also project the potential impact on society and/or industry of success in the research.The novelty or potentially transformative nature of the research should be included, as a minimum, in the Project Summary of each proposal. The duration of unsolicited proposal awards in CBET is generally up to three years. Single-investigator award budgets typically include support for one graduate student (or equivalent) and up to one month of PI time per year(awards for multiple investigator projects are typically larger). Proposal budgets that are much larger than typical should be discussed with the program director prior to submission. Proposers can view budget amounts and other information from recent awards made by this program via the “What Has Been Funded (Recent Awards Made Through This Program, with Abstracts)” link towards the bottom of this page. Faculty Early Career Development(CAREER)program proposals are strongly encouraged.Award duration is five years.The submission deadline for Engineering CAREER proposals is in July every year. Learn more in the CAREER program description . Proposals for Conferences, Workshops, and Supplements: PIs are strongly encouraged to discuss their requests with the program director before submission of the proposal. Grants forRapid Response Research(RAPID)andEArly-concept Grants for Exploratory Research(EAGER)are also considered when appropriate.Please note that proposals of these types must be discussed with the program director before submission.Grant Opportunities for Academic Liaison with Industry (GOALI)proposals that integrate fundamental research with translational results and are consistent with the application areas of interest to each program are also encouraged. Please note that RAPID, EAGER, and GOALI proposals can be submitted anytime during the year. Details about RAPID, EAGER, and GOALI are available in the Proposal & Award Policies & Procedures Guide (PAPPG), Part 1, Chapter II, Section E: Types of Proposals. Compliance: Proposals that are not compliant with the Proposal & Award Policies & Procedures Guide (PAPPG) will be returned without review.

The National Facilities program supports the operation of national user facilities: National Facilities areresearch facilities with specialized instrumentation available to the scientific research community in general and the materials research community in particular.These facilities provide unique research capabilities that can be located at only a few highly specialized laboratories in the Nation. They provide open user service for scientists and engineers from a broad range of disciplines including biology, chemistry, geosciences, materials research. and physics. Theyinclude facilities and resources for research using high magnetic fields, ultraviolet and x-ray synchrotron radiation, neutron scattering, and nanofabrication. Theyserve as science and technology-related resources and experiences for students. Theyconduct student and teacher education, general public awareness activities, curriculum development, and educational research.

The Marine Geology and Geophysics Core Program supports research on all aspects of the geology and geophysics of the present ocean basins and margins, as well as those of the Great Lakes. The Program supports science that includes: Structure, composition, tectonics, and evolution of the oceanic lithosphere Paleoceanography, paleoclimate, and sea level change Submarine volcanology, petrology and geochemistry of the oceanic crust and upper mantle lithosphere Marine hydrogeology, water-rock interaction, seeps and gas hydrates Hydrothermal venting and in situ fluid processes, and associated geochemistry Geochemical indicators of life operating below the seafloor Marine sedimentology, stratigraphy, sediment transport, and diagenesis Mid-ocean ridge spreading, back-arc rifting, transform processes, and ocean island/seamount formation and evolution Submarine components of subduction zone systems and passive margins Marine geohazards (e.g., earthquakes, faulting, mass wasting, geological aspects of tsunamis) Coastal processes (e.g., geological aspects of hurricanes, sea-level change, erosion, offshore deposition) The Marine Geology and Geophysics Program supports acquisition of new field data and the leveraging of and/or synthesis of existing data. The program supports analytical and laboratory experimental projects, methods development, and modeling. All activities should have relevance to and advance the understanding of marine geoscience processes. The Program interfaces with NSF programs across the Geosciences and across the Agency. For proposals that cross between Programs, proposers should contact the relevant Programs to seek guidance on submission.

The Engineering for Civil Infrastructure (ECI) program supports fundamental research in geotechnical, structural, materials, architectural, and coastal engineering. The ECI program promotes research that can shape the future of the nation’s physical civil infrastructure and that can contribute to climate change adaptation and mitigation, and hazards and disaster resilience. Types of civil infrastructure that the ECI program considers include, but are not limited to, buildings, residential construction, earth and earth retaining structures, and components of flood protection systems; water, waste disposal, and wastewater systems; energy infrastructure (excluding nuclear); and transportation systems (excluding pavements). Both disciplinary and convergent research that can address the challenges of physical civil infrastructure to be resilient and sustainable over its service lifetime are of particular interest. Broader impacts of ECI research include fostering community welfare for an equitable and prosperous nation and promoting environmentally friendly, circular economy policies. The ECI program supports research that advances knowledge on the behavior of physical civil infrastructure subjected to and interacting with the natural environment during construction; under service and long-term conditions, including increased demands due to climate change adaptation and other emerging stressors; and under conditions caused by single or multiple extreme hazard events (extreme weather, windstorms, earthquakes, tsunamis, storm surges, landslides, and fire, including wildland-urban interface fire). The ECI program also supports research on geomaterials and infrastructure materials utilized in load-bearing systems as well as in non-structural systems. Of particular interest is experimental and analytical/computational research to advance the fundamental understanding of coupled multi-physics, multi-scale (spatial and temporal), multi-functional behavior of these materials and their intended use in civil infrastructure. The ECI program supports research on civil infrastructure that contributes to the National Science Foundation’s role in the National Earthquake Hazards Reduction Program (NEHRP) and the National Windstorm Impact Reduction Program (NWIRP). Principal Investigators are encouraged to leverage NSF’s investments in the Natural Hazards Engineering Research Infrastructure (NHERI) experimental, computational modeling and simulation, and data resources ( https://www.designsafe-ci.org/ ) in their research to accelerate advances needed for reducing the impacts of natural hazards on civil infrastructure. The NHERI Science Plan ( https://www.designsafe-ci.org/facilities/nco/science-plan/ ) offers a range of research topics that could benefit from the use of NHERI resources and are relevant to the ECI program. The ECI program does not support research that addresses natural resource exploration or recovery, investigates blasts and explosions, develops sensor and measurement technologies, or focuses on hazard characterization. The ECI program only supports fundamental research topics for civil infrastructure with a strong grounding in theory. Topics which fall within the mission for research and/or development of other federal and state agencies are appropriate for the ECI program only when addressing fundamental scientific questions. Research on natural hazard characterization is supported through programs in the NSF Directorate for Geosciences. Proposers are actively encouraged to email a one-page project summary to the ECI Program Officers before submitting a full proposal for guidance on whether the proposed research topic falls within the scope of the ECI program; this guidance especially should be requested for multi-disciplinary research proposals, proposals for which research and/or development on the subject civil infrastructure(s) are also supported by other federal and state agencies, and proposals that consider civil infrastructure not listed above.

The Operations Engineering (OE) program supports fundamental research on advanced analytical methods for improving operations in complex decision-driven environments. Analytical methods include, but are not limited to, deterministic and stochastic modeling, optimization, decision and risk analysis, data science, and simulation. Methodological research is highly encouraged but must be motivated by problems that have potential for high impact in engineering applications. Application domains of particular interest to the program arise in commercial enterprises (e.g., production/manufacturing systems and distribution of goods, delivery of services), the public sector/government (e.g., public safety and security), and public/private partnerships (e.g., health care, environment and energy). The program also welcomes operations research in new and emerging domains and addressing systemic societal or technological problems. The OE program particularly values cross-disciplinary proposals that leverage application-specific expertise with strong quantitative analysis in a decision-making context. Proposals for methodological research that are not strongly motivated by high-potential engineering applications are not appropriate for this program. PIs are encouraged to send any program inquiries to both Program Directors.

The Facility and Instrumentation Request Process (FIRP) solicitation describes the mechanism by which the research community can propose projects that require access to instrumentation and facilities sponsored by the Facilities for Atmospheric Research and Education (FARE) Program in the Division of Atmospheric and Geospace Sciences (AGS). FARE provides funding to a variety of organizations to make specialized instrumentation and facilities available to the atmospheric science research community through the Lower Atmosphere Observing Facilities (LAOF) and the Community Instruments and Facilities (CIF) programs. FIRP allows for parallel evaluation of intellectual merit and broader impacts along with the feasibility of the proposed project. All proposals to AGS that require the use of FARE-sponsored assets must be submitted through this solicitation. The FIRP solicitation offers three proposal submission tracks based on the type and purpose of the request: Track 1 - Education and Outreach. Track 2 - Single Facility Request. Track 3 - Field Campaigns. Preference for funding will be given to proposals submitted to programs in the Division of Atmospheric and Geospace Sciences (AGS) in the Geosciences Directorate (GEO). If you are planning to submit a proposal to a program outside AGS, including NSF-wide or Directorate-wide solicitations, please contact the FARE program director, Shree Mishra at fare@nsf.gov to discuss the timelines, review process, and budget request for the use of FARE assets.

The Mechanics of Materials and Structures program supports fundamental research in mechanics as related to the behavior of deformable solid materials and structures under internal and external actions. The program supports a diverse spectrum of research with emphasis on transformative advances in experimental, theoretical, and computational methods. Submitted proposals should clearly emphasize the contributions to the field of mechanics. Proposals related to material response are welcome, including, but not limited to, advances in fundamental understanding of deformation, fracture, and fatigue as well as contact and friction. Proposals that relate to structural response are also welcome, including, but not limited to, advances in the understanding of nonlinear deformation, instability and collapse, and wave propagation. Proposals addressing mechanics at the intersection of materials and structures, such as, but not limited to, meta-materials, hierarchical, micro-architectured and low-dimensional materials are also encouraged. Proposals that explore and build upon advanced computing techniques and tools to enable major advances in mechanics are particularly welcome. For example, proposals incorporating reduced-order modeling, data-driven techniques, and/or stochastic methods with a strong emphasis on validation are encouraged. Also welcome are proposals addressing data analytics for deformation or damage response deduction from large experimental and computational data sets. Similarly, proposals that explore new experimental techniques to capture deformation and failure information for extreme ranges of loading or material behavior are also encouraged. Finally, experimental and computational methods that address information across multiple length and time scales, potentially involving multiphysics considerations are also welcome. Proposals with a focus on buildings and civil infrastructure system are welcome in CMMI and should be submitted to the program on Structural and Architectural Engineering Materials (SAEM). Proposals addressing processing and mechanical performance enhancements should be submitted to the Materials Engineering and Processing (MEP) program. Investigators with proposals focused on design methodological approaches and theory enabling the accelerated development and insertion of materials should consider the Design of Engineering Material Systems (DEMS) program. Lastly, investigators with interest in developing a combined theoretical and experimental approach to accelerate materials discovery and development should direct their proposals to the Designing Materials to Revolutionize and Engineer Our Future (DMREF) opportunity. Proposers are actively encouraged to email a one-page project summary to MOMS@nsf.gov before full proposal submission to determine if the research topic falls within the scope of the MOMS program.

The Mind, Machine, and Motor Nexus (M3X) program supports fundamental research that enables intelligent engineered systems and humans to engage in bidirectional interaction in a physics-based environment, to enhance and ensure safety, productivity, and well-being. For the purpose of this program an intelligent engineered system is a human-designed system — physical, virtual, or a combination of both — that interacts with its environment to achieve specific goals. These systems collect data, analyze it to make informed decisions, and take actions that enhance safety, efficiency, and well-being. They may operate autonomously or collaboratively with humans, adapting their actions based on the data they collect. A key requirement for the M3X program is that these systems must function within a physics-based environment, whether physical or virtual, where interactions exhibit recognizable physical behaviors, such as those associated with gravity, friction, force, and inertia. Intelligent engineered systems are becoming increasingly integrated into our daily lives, interacting with humans across diverse environments and through different modalities (for example, visual, haptic, auditory). M3X aims to deepen the understanding of such interactions, particularly in complex and dynamic settings such as elder care, disaster response, and dynamic workplaces. The program encourages explorations into the physical or cognitive principles that enable or constrain human-machine collaboration, advancing foundational theories, interaction modeling, and technological innovations that enhance adaptability, efficiency, and intuitiveness. Proposals submitted to the M3X program must clearly articulate how the proposed work advances knowledge of bidirectional interactions between humans and intelligent engineered systems. Examples include robots assisting in disaster response, smart environments that learn user preferences, and virtual reality-based rehabilitation technologies that simulate plausible physics. While proposals are not required to address all aspects of the interaction, they must propose significant contributions to at least one of the following areas: Conceptual Frameworks and Theoretical Modeling Development of new conceptual, mathematical, or computational frameworks that provide structured approaches to understanding and analyzing the bidirectional interaction between humans and engineered systems. These frameworks serve as formalized models or methodologies that guide research in areas such as cognition, perception, and behavior of both humans and intelligent engineered systems during their interactions. Additionally, these computational frameworks facilitate the modeling of safe operating conditions in dynamic task environments and the identification of theoretical limits of cognitive and physical performance capabilities during interaction. Dynamic Interaction Analysis and Simulation Investigation of emerging and established bidirectional interaction phenomena in physical, virtual, or hybrid environments. Potential topics may include learning, co-adaptation, cooperation, competition, and multi-scale interaction. The program also welcomes novel experimental paradigms to evaluate processes and performance. Innovative Technologies for Enhanced Interaction Development of methods, tools, and technologies to enable novel or improved forms of bidirectional interaction, guided by hypotheses and interaction-driven requirements. Potential topics may include creating meaningful task environments (physical, virtual, or hybrid); designing new modalities and interfaces for interaction; developing advanced evaluation, measurement, and instrumentation methods; testbeds, and improving real-time integration of multi-modal sensorimotor data. The M3X program strongly encourages proposals that aim to establish new perspectives and paradigms across one or more of the three areas listed above . To ensure strong alignment with M3X objectives, Principal Investigators are encouraged to submit a one-page Project Summary to M3X@nsf.gov for feedback from Program Directors.

The Engineering Design and Systems Engineering (EDSE) program supports fundamental research that advances design science and/or systems science through the creation of new knowledge about the design of engineered artifacts. Engineered artifacts include, but are not limited to, devices, products, processes, platforms, materials, organizations, systems, and systems of systems. The program focuses on design as a system, in which designers, the artifacts they create, the methods they use to create them, and the environment in which this occurs are all subject to rigorous scientific inquiry, along with the interactions among these elements. The EDSE program strongly encourages proposals that embrace the multidisciplinary nature of design and supports well-defined collaborations of experts in design science and/or systems science with experts in other domains, including (but not limited to) the social, behavioral, computational, and natural (biological and physical) sciences. Competitive proposals will be firmly grounded in theory, will demonstrate the potential of the proposed work to improve design, and will include a plan to rigorously assess the performance and effectiveness of the proposed research methods across all domains involved. In particular, the EDSE program supports fundamental contributions in areas that include but are not limited to design representation; design optimization; design validation; mechanism design; robotics and intelligent system design; design of engineered materials systems; design cognition; design collaboration; data science and artificial intelligence in design; design in under-resourced communities; immersive design; and design at extreme scales and in extreme environments. Prospective investigators are encouraged to discuss their research ideas with the Program Director in advance of proposal preparation and submission.