Browse grants

Dept of the Army -- Materiel Command · Amount varies

**PLEASE REVIEW FULL SPECIAL NOTICE** Funding Opportunity Title: Low-Cost Chip-Scale Atomic Clock (LC CSAC) Funding Instrument Type: Technology investment agreement The aim of this Special Notice under the ARL BAA (W911NF-17-S-0003), under Grants.gov Opportunity W911NF-17-S-0003-SPECIALNOTICE-LC-CSAC, is to fund a team or multiple teams to design, manufacture, and deliver a battery-powered atomic clock that achieves identical (or better) size, weight, and power (SWaP) and performance to the commercially available chip-scale atomic clock (CSAC) with a selling price goal of < $300/unit in high volume. Precise timing is critical for numerous Army applications such as navigation, communications, surveillance, and synchronization of sensors and systems. Assured PNT solutions currently rely on acquiring GPS signals, which may not be readily available in increasingly contested environments. Commercially available silicon MEMS and quartz oscillators (TCXO, OCXO) are unable to provide GPS holdover in the event of a GPS outage, except for high-end OCXOs that may be considered large and power hungry for certain applications. To ease reliance on GPS, long-holdover clocks with SWaP-C appropriate for various DoD platforms are necessary to enable mission-critical functions even in contested environments. Current high-performance atomic clocks (maser, laser-cooled cesium fountain) serve as standards and are large, expensive, and require regular monitoring and exquisite environmental control. Since the early 2000s, the chip-scale atomic clock (CSAC) has been developed and successfully matured into a commercial product with DARPA and industry investment. While an Army/Air Force/OSD Manufacturing Technology effort further reduced the manufacturing cost1, the current selling price is still prohibitive for high-volume, low-SWaP DoD platforms. There is an opportunity to leverage the many advances in MEMS, photonics, and atomic physics over the past two decades to develop state-of-the-art, high-performance, battery-powered atomic clocks with improved manufacturability, significantly reduced cost, and improved performance. This special notice seeks proposals from one or more for-profit firms in accordance with 32 CFR 37.210. A consortium, led by a for-profit firm, is also encouraged. Points of Contact: Jonathan Hoffman jonathan.e.hoffman.civ@mail.mil Jenna Chan Jenna.f.chan.ctr@mail.mil

Department of Commerce · $0–$300K

UPDATED NOTICE - PLEASE READ: April 6, 2023 EDA is excited to announce the launch of its new grants management platform: the Economic Development Grants Experience (EDGE). EDGE was developed to streamline the application and grants management process by implementing a single platform with increased transparency, improved user experience, higher data quality, and more efficiency throughout the entire grant lifecycle. As of April 6th, 2023, applications can no longer be submitted on Grants.gov, and will ONLY be accepted through EDGE. To apply in EDGE, please go to: sfgrants.eda.gov . More information on how to apply is provided in the full NOFO. Please note that the above does not apply for Partnership Planning applications . For more information, please reach out to your point of contact. Program Description: EDA makes planning and local technical assistance investments to support economic development, foster job creation, and attract private investment in economically distressed areas of the United States. Under the Planning program, EDA makes Partnership Planning, Short-Term Planning, and State Planning awards to eligible recipients to create and implement regional economic development plans designed to build capacity and guide the economic prosperity and resiliency of an area or region. More specifically, EDA makes Partnership Planning investments to designated planning organizations (i.e., District Organizations) serving EDA-designated Economic Development Districts and to Indian Tribes to facilitate the development, implementation, revision, or replacement of Comprehensive Economic Development Strategies (CEDS), which articulate and prioritize the strategic economic goals of recipients’ respective regions. EDA also makes Short-Term and State Planning awards for economic development planning activities that guide the eventual creation and retention of high-quality jobs, particularly for the unemployed and underemployed in the Nation’s most economically distressed regions. Under the Local Technical Assistance program, EDA makes awards to strengthen the capacity of local or State organizations, institutions of higher education, and other eligible entities to undertake and promote effective economic development programs through projects such as feasibility studies, impact analyses, disaster resiliency plans, and project planning. *Please note: While the published Notice of Funding Opportunity (available under "Related Documents") states that the ED900A form and the SF424B form are both required for a complete application, these forms are no longer required and have therefore been removed from the package template.

U.S. National Science Foundation · Amount varies

The NSF Engineering Directorate (ENG) has launched a multi-year initiative, theProfessional Formation of Engineers, to create and support an innovative and inclusive engineering profession for the 21 st century. Professional Formation of Engineers (PFE) refers to the formal and informal processes and value systems by which people become engineers. It also includes the ethical responsibility of practicing engineers to sustain and grow the profession in order to improve quality of life for all peoples. The engineering profession must be responsive to national priorities, grand challenges, and dynamic workforce needs; it must be equally open and accessible to all. Professional Formation of Engineers includes, but is not limited, to: Introductions to the profession at any age; Development of deep technical and professional skills, knowledge, and abilities in both formal and informal settings/domains; Development of outlooks, perspectives, ways of thinking, knowing, and doing; Development of identity as an engineer and its intersection with other identities; and Acculturation to the profession, its standards, and norms. The goal of the Research in the Formation of Engineers (RFE) program is to advance our understanding of professional formation. It seeks both to deepen our fundamental understanding of the underlying processes and mechanisms that support professional formation and to demonstrate how professional formation is or can be accomplished. Ultimately RFE aims to transform the engineer-formation system, and thus the impact of proposed projects on this system must be described. Principal Investigators (PIs) should provide a roadmap detailing how they envision the proposed research will eventually broadly impact practice within the engineer-formation system, even if these activities are not within the scope of the submitted proposal. In order to accomplish its goals, RFE welcomes proposals in two categories: Research Projects, and Design and Development Projects. Research Projects address fundamental questions of professional formation, while Design and Development Projects provide new approaches to achieving professional formation. Additional details are provided below. Projects in both categories should address the iterative cycle in which research questions that advance understanding are informed by practice and the results of research are, in turn, translated into practice. In other words, proposals should explain how the research results will travel, translate, transfer, or scale. Successful projects identify specific target audiences, effective communication channels, and novel partnerships to ensure effective propagation and scaling. Proposal titles should begin with either &ldquo;Research:&rdquo; or &ldquo;Design and Development:&rdquo; as appropriate. Research Projects Research proposals are particularly welcome in the following areas: Research that addresses lifelong learning by the engineering workforce. Research on the impact of engineering education research. Proposals addressing this topic could investigate questions such as: How can we measure the impacts of engineering education research? What are effective strategies for scaling reforms? How can we translate knowledge from research to practice? What are the roles of technologies, networks and communities in achieving impact? RFE does not support efficacy, effectiveness, or scale-up studies for specific interventions. Research that addresses culture change in engineering education. Included in this topic are investigations of normative cultures of engineering at any level in the engineering education ecosystem and how these cultures may disadvantage certain groups. Research that addresses engineering formation at the two-year college level in both formal and informal settings. Research that addresses engineering formation at the graduate education level in both formal and informal settings. Research that investigates engineering in P-12 settings. Research in this area could include understanding of approaches to engineering in P-12, how to develop engineering ways of thinking, or the relationship between practices within the sciences and mathematics and engineering thinking. Research on the transitions between education levels, e.g., from high school to two-year college, high school to four-year college/university, two-year college to four-year college/university, undergraduate to graduate school, education settings to the workforce or professoriate, etc. Research that addresses the relationship between engineering and the public. Proposals addressing this topic could consider the social impact of engineering solutions, citizen engineering, education of an informed public, etc. Research that develops or adapts novel methodologies and frameworks appropriate for studying the professional formation of engineers, and especially minoritized, marginalized, or underserved populations. Research that addresses ways in which new technologies (such as artificial intelligence and machine learning) are changing engineering education. Research to transform engineering education so that all students encounter environmental and social sustainability principles as an integrated part of their education and are equipped with the tools needed to incorporate these principles into their future research, careers, and innovations. Proposals submitted to the Research Projects category should have clear research questions informed by an appropriate theoretical framework and a research design that includes sampling, data collection, and data analysis methods. This category will not support proposals that seek funding primarily to develop tools, curriculum, or laboratories, or that seek to implement classroom innovations that have already been shown to be effective in engineering. The program will evaluate the value of proposals by considering the impact and the cost. Research track projects that are small, exploratory, or speculative are especially encouraged. Larger Research track projects should have a correspondingly larger impact. Design and Development Projects RFE supports Design and Development projects (see https://www.nsf.gov/publications/pub_summ.jsp?ods_key=nsf13126 ) that seek to develop and test new approaches in the following areas related to engineering education : Graduate education. Undergraduate education in new engineering technologies and environmental sustainability. Transitions between education levels, for example high school to two-year college, high school to four-year college/university, two-year college to four-year college/university, undergraduate to graduate school, education settings to the workforce or professoriate, etc. P-12, especially approaches to develop engineering thinking, or providing links between engineering, science, and mathematics. Proposals in this category should propose the design and development of new approaches that are informed by existing literature and theory. There should be clear objectives and the evaluation plan should be designed to determine if those objectives have been met. Projects cannot be solely demonstration projects but must add to the engineering education literature to inform future work.

U.S. National Science Foundation · Amount varies

The Communications, Circuits, and Sensing-Systems (CCSS) Program supports innovative research in circuit and system hardware and signal processing techniques. CCSS also supports system and network architectures for communications and sensing to enable the next-generation cyber-physical systems (CPS) that leverage computation, communication, and sensing integrated with physical domains. CCSS invests in micro- and nano-electromechanical systems (MEMS/NEMS), physical, chemical, and biological sensing systems, neurotechnologies, and communication & sensing circuits and systems. The goal is to create new complex and hybrid systems ranging from nano- to macro-scale with innovative engineering principles and solutions for a variety of applications including but not limited to healthcare, medicine, environmental and biological monitoring, communications, disaster mitigation, homeland security, intelligent transportation, manufacturing, energy, and smart buildings. CCSS encourages research proposals based on emerging technologies and applications for communications and sensing such as high-speed communications of terabits per second and beyond, sensing and imaging covering microwave to terahertz frequencies, personalized health monitoring and assistance, secured wireless connectivity and sensing for the Internet of Things, and dynamic-data-enabled autonomous systems through real-time sensing and learning. Areas managed by CCSS Program Directors (please contact Program Directors listed in the CCSS staff directory for areas of interest): RF Circuits and Antennas for Communications and Sensing RF Communications and Sensing Technologies from kHz to THz Antennas and Wave Propagation for Communications and Sensing Circuits and Systems for Secured Communications and Sensing Trusted Microelectronic Circuits RF Biomedical Applications and Remote Sensing Bio-mimetic Circuits and Systems Dynamic-data-enabled Reconfigurable RF Subsystems through Sensing and Machine Learning Wireless Energy Transfer and RF Energy Harvesting Communication Systems and Signal Processing Wireless, Optical, and Hybrid Communications and Networking Full-duplex, massive MIMO, mm-Wave, and THz communications Spectrum Access and Sharing Integrated Sensing, Communication, and Computational Systems Signal Processing, image processing, and Compressive Sampling Cyber Physical Systems and Hardware-controlled Secured Communications Dynamic-data-enabled Communication Systems through Sensing and Machine Learning Quantum Communication Systems Dynamic Bio-Sensing Systems Micro, Nano, and Bio Systems (MEMS/NEMS) Chemical, Biological, and Physical Diagnostics Sensors, Actuators, and Electronic Interfaces Ultra-Low Power Wearable and Implantable Sensing Systems Dynamic-data-enabled Reconfigurable Sensing Systems Personalized Health Monitoring Systems through Sensing and Machine Learning Neuroengineering and Brain-Inspired Concepts and Designs

U.S. National Science Foundation · Amount varies

The Biosensing program is part of the Engineering Biology and Health cluster, which also includes 1) the Biophotonics program; 2) the Cellular and Biochemical Engineering program; 3) the Disability and Rehabilitation Engineering program; and 4) the Engineering of Biomedical Systems program. The Biosensing program supports fundamental engineering research in the monitoring, identification and/or quantification of biological analytes and phenomena using innovations that exist at the intersection of engineering, life sciences, and information technology. Projects submitted to the program must advance both engineering and life sciences. The Biosensing program encourages proposals that, in addition to advancing biosensing technology, address critical sensor needs in biomedical research, public health, food safety, agriculture, forensics, environmental protection, and homeland security. Proposals are especially encouraged in areas of critical need: sensing technologies that can enable monitoring and surveillance of the environment and/or individuals for novel infectious agents; platform technologies that can readily be modified as soon as new agents are detected, sequenced, and/or otherwise characterized to enable rapid deployment of sensors in clinics and the environment; and adaptive and/or multiplex sensing technologies that can help the nation prevent the spread of the next global pandemic. Major areas of interest for the program include: Novel signal transduction principles and mechanisms that enable sensitive and specific biosensors, suitable for measurements in multiple areas; Design of novel biorecognition elements and appropriately designed transducing systems to enable adaptable and/or reconfigurable operating parameters in response to environmental changes or application needs at levels of device, system, or data analysis; Development of adaptive and/or evolvable biosensing systems for detection of novel target analytes or analytes under novel conditions; Novel synthetic biology approaches for the development of cell-free and cell-based biosensors; and Combining biosensors with artificial intelligence (AI) methods to improve sensor specificity and response time. Innovative ideas outside of the above 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. The Biosensors program does not encourage proposals addressing circuit design for signal processing and amplification, computational modeling, and microfluidics for sample separation and filtration. Medical imaging-based measurements are outside of the scope of the program interests. Proposals that rely heavily on descriptive approaches are given lower priority. Proposals for optimizing and/or utilizing established methods for specific applications should be directed to programs focused on the application of sensor technology. NOTE: Projects related to water and/or soil quality may be jointly supported with the Environmental Engineering program (CBET 1440). Photonic devices with medical imaging and/or optogenetics should be submitted to the Biophotonics program (CBET 7236). Applications of devices for tissue engineering or organ-on-chip systems should be submitted to the Engineering of Biomedical Systems program (CBET 5345). Basic chemical/biochemical sensing mechanisms should be submitted to the Chemical Measurement and Imaging program (CMI 6880) in the Division of Chemistry. Proposals for dynamic biosensing systems, including circuit design for signal/data processing and amplification, and sensing systems through communication and machine learning should be submitted to the Communications, Circuits, and Sensing-Systems program (CCSS 7564) in the Division of Electrical, Communications, and Cyber Systems. 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.

U.S. National Science Foundation · Amount varies

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 &mdash; physical, virtual, or a combination of both &mdash; 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.

Headquarters · $0

Notice

U.S. Mission to the United Nations · $5K–$15K

The United States Mission to the United Nations and Other International Organizations in Geneva advances U.S. policy at more than 100 international organizations in Geneva. The U.S. Mission engages daily on issues as diverse as humanitarian assistance, global health, international trade, peace and security, arms control, and human rights. The Program: The United States Mission in Geneva is accepting project proposals for its fiscal year 2020 Small Grants Program. The Small Grants Program permits individuals, non-government organizations, think tanks, and government and academic institutions to seek funding for projects that promote U.S. policy priorities in the multilateral sphere. All programs must include a U.S. element or connection. Awards will be made to successful applicants subject to the availability of appropriated funds. Programs can include, but are not limited to, academic and professional lectures or panel discussion; exhibitions and cultural programs; professional and academic exchanges; professional development workshops and training; or public awareness campaigns. Priority Program Areas: Though all submitted projects will be considered for funding, we are currently giving priority to projects that highlight: Human rights, including protection of human rights defenders Freedom of religion or belief Promoting peace and security Public-private partnerships Preserving core UN values Promoting transparency, accountability, and efficiency in the UN system Further details about the program and how to apply at the following link: https://geneva.usmission.gov/annual-program-statement/

U.S. National Science Foundation · $300K–$800K

The Infrastructure Innovation for Biological Research Program (Innovation) supports research to design novel or greatly improved research tools and methods that advance contemporary biology in any research area supported by the Directorate forBiological Sciences at NSF. The Innovation Program focuses on research infrastructure that is broadly applicable to researchers in three programmatic areas: Bioinformatics, Instrumentation, and Research Methods. Infrastructure supported by this program is expected to advance biological understanding by improving scientists&rsquo; abilities to manipulate, control, analyze, or measure critical aspects of biological systems, which can be essential for addressing important fundamental research questions. Proposals submitted to these programmatic areas can do one of three things to advance or transform research in biology: develop novel infrastructure, significantly redesign existing infrastructure, or adapt existing infrastructure in novel ways. Projects are expected to have a significant application to one or more biological science questions and have the potential to be used by a community of researchers beyond a single research team. Please refer to the descriptions of individual programmatic areas for detailed guidance on what is supported through this solicitation (see links below).

National Park Service · $1–$32.3K

To provide research, technical assistance, and educational opportunities to partners and the national parks in the National Capital Region and Service wide. Unless otherwise specified herein, the terms and conditions as stated in the CW CESU Agreement will apply to this Task Agreement.

National Park Service · Up to $55.7K

*Task agreement already awarded to SCA for the work described.

National Park Service · Amount varies

The objective of this Task Agreement is to support and stimulate work and/or education and training opportunities for young adults through collaborative participation in natural resource research and inventory and monitoring for the parks of the Mojave Desert Network.

U.S. Mission to Australia · $5K–$15K

Proposals should be submitted via email to the Public Affairs Section of the U.S. Embassy: PASGrantsAustralia@state.gov. Post's grant proposal forms can be found at the link below. Please include as many specific details as possible, including a project timeline and a description of how the U.S. Embassy would be involved and acknowledged in conjunction with the project. Please include a detailed budget, as well as information about cost sharing by other entities.

Idaho Field Office · $0

DOE is seeking information, comments, feedback, and recommendations from interested parties to determine what capabilities supporting research, training and technology demonstration are of highest interest to the nuclear energy research community.All responses are to be made at NEUP.gov per the attached instructions.

U.S. National Science Foundation · Amount varies

The Geospace Cluster (GC) in the Division of Atmospheric and Geospace Sciences (AGS) supports fundamental and solutions-oriented research, technology development and education related to the Earth's near-space environment (including the mesosphere, thermosphere, ionosphere, exosphere, magnetosphere and radiation belts) and the inner heliosphere and solar atmosphere. The GC advances knowledge of the Sun--Earth system, including how various parts of the system are coupled through dynamical, electrodynamical and chemical processes. The GC supports research on the societal impacts of these processes including space weather and upper atmosphere climate change, with the aim of increasing resilience to such natural hazards. The GC supports research that uses ground-based or space-based observational facilities and instruments as well as data centers and a broad range of theoretical, modeling, observational, data analyses and laboratory activities. General research topics that are supported by the GC include, but are not limited to: Aeronomy, including studies of wave dynamics, ionization, recombination, chemical reaction, photo emission and transport of energy and momentum within and between the mesosphere, thermosphere and ionosphere of the Earth; how this global system is coupled to the stratosphere below and magnetosphere above; and the plasma physics of phenomena manifested in the coupled ionosphere-magnetosphere system. Magnetospheric physics, including studies of the magnetosphere, or the cavity carved out of the solar wind by the Earth's magnetic field, its energization by the solar wind and population by solar and ionospheric sources; waves and instabilities in such natural plasmas; the origin of planetary electric fields; the origin of geomagnetic storms and substorms; and the coupling among the radiation belts, magnetosphere, ionosphere and atmosphere. Solar-terrestrial physics, including how energy generation and eruptive processes occur in the solar atmosphere and how energy and momentum are transported within the Sun-Earth system; solar dynamo, solar activity cycle and magnetic flux emergence; eruptive activity including solar flares and coronal mass ejections; solar wind heating, solar energetic particles and interactions with cosmic rays; solar wind/magnetosphere boundary; and helioseismology. Space weather and space climate, including solar or terrestrial drivers of space weather; observations and modeling of the integrative geospace system that could lead to better predictive capabilities of the time-varying space environment; and characterization of space weather impacts on critical infrastructure and technological systems. Proposals to the GC are welcome at any time. However, the following solicitations in support of specific geospace science and community efforts have target dates or deadlines. They also may have PI and/or Institution restrictions. Please refer to the solicitation documents for further details: The Coupling, Energetics, and Dynamics of Atmospheric Regions (CEDAR) targeted research program aims to understand the behavior of the Earth's atmospheric regions from the middle atmosphere upward through the thermosphere and ionosphere into the exosphere in terms of coupling, energetics, chemistry and dynamics on regional and global scales. The Geospace Environment Modeling (GEM) targeted research program supports investigations of the physics of the Earth's magnetosphere and the coupling of the magnetosphere to the atmosphere and solar wind, including for making accurate predictions of the geospace environment. The Solar, Heliospheric, and Interplanetary Environment (SHINE) targeted research program supports enhanced understanding of and predictive capabilities for the processes by which energy in the form of magnetic fields and particles are produced by the Sun and/or accelerated in interplanetary space and on the mechanisms by which these fields and particles are transported to the Earth through the inner heliosphere. The Faculty Development in geoSpace Science (FDSS) solicitation integrates topics in geospace science, including solar and space physics and space weather research, into natural sciences, engineering or related departments at U.S. institutions of higher education. The solicitation also stimulates the development of undergraduate or graduate programs or curricula to train the next generation of leaders in geospace science. The Geospace Cluster participates in other AGS, GEO and NSF programs and solicitations including but not limited to: Distributed Array of Small Instruments (DASI) ECosystem for Leading Innovation in Plasma Science and Engineering (ECLIPSE) AGS encourages and inspires scientific leaders by investing in the atmospheric and geospace sciences, enhancing educational opportunities and experiences and supporting faculty and researchers at all career stages. The Division expects that proposers will integrate education, outreach and dissemination activities into their research plans in compliance with NSF Broader Impacts Merit Review criteria. AGS invites proposals that include plans for workforce development, educational and outreach activities, open science initiatives and efforts to broaden participation and encourage diverse talent in the atmosphere and geospace sciences. Furthermore, AGS encourages proposals from all institutions, including Minority Serving Institutions, Emerging Research Institutions and institutions in EPSCoR jurisdictions. The Proposal & Award Policies & Procedures Guide (PAPPG) provides the instructions for submitting proposals to AGS. Additionally, Chapter II.F of the PAPPG defines "Other Types of Proposals," including community-building proposals such as Conference, Travel or Planning Proposals and special categories of proposals, such as Rapid Response Research (RAPID) and EArly-concept Grants for Exploratory Research (EAGER). Proposals that are not compliant with the PAPPG will be returned without review. The following sections highlight specific NSF-, GEO-, or AGS-wide solicitations that may be relevant to the AGS Community. Please be aware that solicitations are frequently updated, so make sure that you are looking at the most recent version. Career Development AGS Postdoctoral Research Fellowship (AGS-PRF) : The AGS-PRF program supports researchers (also known as Fellows) for up to 24 months at the institution of their choice. The program is intended to recognize beginning investigators of significant potential and provide them with research experience that will broaden perspectives, facilitate interdisciplinary interactions, and establish them in leadership positions within the AGS community. Faculty Early Career Development Program (CAREER) : The CAREER program supports early career (assistant professor-level) faculty who have the potential to serve as academic role models in research and education and to lead advances for their department or organization. Awards are 5 years long and must integrate research and education. Mid-Career Advancement (MCA) : The MCA program provides opportunities for scientists and engineers at the associate professor rank (or equivalent) to substantively enhance and advance their research program through synergistic partnerships. Capacity Development EMpowering BRoader Academic Capacity and Education (EMBRACE) : The EMBRACE program supports research and educational efforts at "non-R1" institutions, including non-R1 minority serving institutions (MSIs), two-year colleges (2YCs), primarily undergraduate institutions (PUIs), and emerging research (ERIs) and master's level institutions. Historically Black Colleges and Universities Excellence in Research (HBCU - EiR) : The HBCU-EiR program supports research at public and private historically Black colleges and universities to strengthen research capacity and promote engagement with NSF. Facilitating Research at Primarily Undergraduate Institutions (RUI and ROA): RUI awards support PUI faculty in research that engages them in their professional field(s), build capacity for research at their home institution, and support the integration of research and undergraduate education. ROA awards similarly support PUI faculty research, but these awards typically allow faculty to work as visiting scientists at research-intensive organizations where they collaborate with other NSF-supported investigators. Instrumentation and Facilities Major Research Instrumentation : The MRI program supports requests for up to $4 million from NSF for the development or acquisition of multi-user research instruments that are critical to the advancement of science and engineering. Mid-scale Research Infrastructure-1 : The MSRI-1 program supports the design and implementation of research infrastructure--including equipment, cyberinfrastructure, large-scale datasets and personnel--whose total project costs exceed the NSF Major Research Instrumentation program limit but are under $20 million. Mid-scale Research Infrastructure-2 : The MSRI-2 program supports the implementation of research infrastructure--including equipment, cyberinfrastructure, large-scale datasets and personnel--whose total project costs fall between $20 million and $100 million.

U.S. National Science Foundation · Amount varies

The Advanced Manufacturing (AM) program supports the fundamental research needed to revitalize American manufacturing to grow the national prosperity and workforce, and to reshape our strategic industries. The AM program accelerates advances in manufacturing technologies with emphasis on multidisciplinary research that fundamentally alters and transforms manufacturing capabilities, methods and practices. Advanced manufacturing research proposals should address issues related to national prosperity and security, and advancing knowledge to sustain global leadership. Areas of research, for example, include manufacturing systems; materials processing; manufacturing machines; methodologies; and manufacturing across the length scales. Researchers working in the areas of cybermanufacturing systems, manufacturing machines and equipment, materials engineering and processing, and nanomanufacturing are encouraged to transcend and cross domain boundaries. Interdisciplinary, convergent proposals are welcome that bring manufacturing to new application areas, and that incorporate challenges and approaches outside the customary manufacturing portfolio to broaden the impact of America&rsquo;s advanced manufacturing research. Proposals of all sizes will therefore be considered as justified by the project description. Investigators are encouraged to discuss their ideas with AM program directors well in advance of submission at AdvancedManufacturing@nsf.gov .

Rural Business-Cooperative Service · $1.5K–$500K

REAP Renewable Energy Systems and Energy Efficiency Improvement Program.Refer to Application Package AND Application Instruction links to obtain all necessary forms for a complete application.Contact State Energy Coordinators with questions: http://www.rd.usda.gov/files/RBS_StateEnergyCoordinators.pdf

U.S. National Science Foundation · Amount varies

The Energy, Power, Control, andNetworks (EPCN) Program supports innovative research in modeling, optimization, learning, adaptation, and control of networked multi-agent systems, higher-level decision making, and dynamic resource allocation, as well as risk management in the presence of uncertainty, sub-system failures, and stochastic disturbances. EPCN also invests in novel machine learning algorithms and analysis, adaptive dynamic programming, brain-like networked architectures performing real-time learning, and neuromorphic engineering. EPCN&rsquo;s goal is to encourage research on emerging technologies and applications including energy, transportation, robotics, and biomedical devices & systems. EPCN also emphasizes electric power systems, including generation, transmission, storage, and integration of renewable energy sources into the grid; power electronics and drives; battery management systems; hybrid and electric vehicles; and understanding of the interplay of power systems with associated regulatory & economic structures and with consumer behavior. Areas managed by Program Directors (please contact Program Directors listed in the EPCN staff directory for areas of interest): Control Systems Distributed Control and Optimization Networked Multi-Agent Systems Stochastic, Hybrid, Nonlinear Systems Dynamic Data-Enabled Learning, Decision and Control Cyber-Physical Control Systems Applications (Biomedical, Transportation, Robotics) Energy and Power Systems Solar, Wind, and Storage Devices Integration with the Grid Monitoring, Protection and Resilient Operation of Grid Power Grid Cybersecurity Market design, Consumer Behavior, Regulatory Policy Microgrids Energy Efficient Buildings and Communities Power Electronics Systems Advanced Power Electronics and Electric Machines Electric and Hybrid Electric Vehicles Energy Harvesting, Storage Devices and Systems Innovative Grid-tied Power Electronic Converters Learning and Adaptive Systems Neural Networks Neuromorphic Engineering Systems Data analytics and Intelligent Systems Machine Learning Algorithms, Analysis and Applications

U.S. National Science Foundation · Amount varies

TheElectrochemical Systemsprogram is part of the Chemical Process Systems cluster, which also includes: 1) theCatalysisprogram; 2) theInterfacial Engineeringprogram; and 3) theProcess Systems, Reaction Engineering, and Molecular Thermodynamicsprogram. The goal of theElectrochemical Systemsprogram is to support fundamental engineering science research that will enable innovative processes involving electrochemistry or photochemistry for the sustainable production of electricity, fuels, chemicals, and other specialty and commodity products. Processes utilizing electrochemistry or photochemistry for sustainable energy and chemical production must be scalable, environmentally benign, reduce greenhouse gas production, and utilize renewable resources. Research projects that stress fundamental understanding of phenomena that directly impact key barriers to improved system or component-level performance (for example, energy efficiency, product yield, process intensification) are encouraged. Processes for energy storage should address fundamental research barriers for renewable electricity storage applications, for transport propulsion, or for other applications that could have impact towards climate change mitigation. For projects concerning energy storage materials, proposals should involve testable hypotheses that involve device or component performance characteristics that are tied to fundamental understanding of transport, kinetics, or thermodynamics. Advanced chemistries beyond lithium-ion are encouraged. Proposed research on processes utilizing electrochemistry or photochemistry should be inspired by the need for economic and impactful conversion processes. All proposal project descriptions should address how the proposed work, if successful, will improve process realization and economic feasibility and compare the proposed work against current state of the art. Highly integrated multidisciplinary projects are encouraged. When appropriate, collaborations with industrial technologists are encouraged through GOALI proposals. Collaborative projects with an integrated experimental and theoretical approach are also encouraged. Topics of interest include electrochemical energy storage and electrochemical production/conversion systems. Radically new battery systems can move the U.S. more rapidly toward a more sustainable transportation future and to greater renewable electricity production penetration. High-energy density and high-power density batteries suitable for transportation and renewable energy storage applications are of primary interest. Advanced systems involving metal anodes, solid-state electrolytes, nonaqueous systemsbeyond lithium, aqueous systems beyond lithium,and multivalent chemistries are encouraged. Research activities focused on commercially available systems such as lead-acid and nickel-metal hydride batteries or lithium-ion batteries for medical or consumer electronics applications will not be considered by this program. Novel electrochemical and photochemical systems and processes for the production of chemicals and high-value products are encouraged. Emphasis is placed on those systems that improve process intensification and process modularization with accompanying benefits in energy efficiency and environmental footprint. Additional fundamental science topics of interest to this program include the study of: advanced fuel cell systems or fuel cell components for transportation propulsion or grid energy storage applications; flow batteries for stationary energy storage applications including alternative redox chemistries (e.g., organic, inorganic, organometallic, macromolecular) and operating strategies (e.g., redox-mediation, suspensions); and photocatalytic or photoelectrochemical processes and devices for the splitting of water into hydrogen gas or for the reduction of carbon dioxide to liquid or gaseous fuels. Projects that largely focus on developing fundamental understanding of the catalytic reaction mechanisms and structure-function relationships may be more appropriate as submissions to the CBET Catalysis program (CBET 1401). Projects submitted to the Electrochemical Systems program are expected to develop fundamental, molecular-level understanding of the key chemical reaction and transport phenomena barriers to improved system-level performance. 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. Referrals to other programs within NSF: Proposals that focus on electric-field driven separations such as dielectrophoresis should be directed to theInterfacial Engineeringprogram (CBET 1417). Proposals that focus on thermal management of energy storage devices and systems should be submitted to theThermal Transport Processesprogram (CBET 1406). Proposals that focus on improving device and system performance of primarily organic, inorganic, and hybrid photovoltaic (PV) technologies, including perovskites, may be more appropriate as submissions to the Electronics, Photonics, and Magnetic Devices program in Engineering's Division of Electrical, Communications, and Cyber Systems (ECCS 1517). PV materials proposals that focus on the material science may be considered in the Division of Materials Research of the Directorate for Mathematical and Physical Sciences. Proposals that focus on the generation of thermal energy by solar radiation should be directed to theThermal Transport Processesprogram (CBET 1406). 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 principal investigator 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 &ldquo;What Has Been Funded (Recent Awards Made Through This Program, with Abstracts)&rdquo; 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 theProposal & Award Policies & Procedures Guide(PAPPG), Part 1, Chapter II, Section E: Types of Proposals. COMPLIANCE: Proposals which are not compliant with the Proposal & Award Policies & Procedures Guide (PAPPG) will be returned without review.

U.S. National Science Foundation · Amount varies

TheEnvironmental Sustainability program is part of theEnvironmental Engineering and Sustainabilitycluster together with 1) theEnvironmental Engineeringprogram and 2) theNanoscale Interactionsprogram. The goal of theEnvironmental Sustainabilityprogram is to promote sustainable engineered systems that support human well-being and that are also compatible with sustaining natural (environmental) systems. These systems provide ecological services vital for human survival. Research efforts supported by the program typically consider long time horizons and may incorporate contributions from the social sciences and ethics. The program supports engineering research that seeks to balance society's need to provide ecological protection and maintain stable economic conditions. There are five principal general research areas that are supported. Circular Bioeconomy Engineering:This area includes research that enables sustainable societal use of food, energy, water, nitrogen, phosphorus, and materials, with the reduction and eventual elimination of fossil fuel combustion that lacks carbon capture. The program encourages research that helps build the raw material basis for the functioning of society principally on biomass, drawing heavily on sustainable agriculture and forestry. Additionally, material flows must reduce or preferably eliminate waste, with an emphasis on closed-loop or &ldquo;circular&rdquo; processing. Industrial ecology:Topics of interest include advancements in modeling such as life cycle assessment, materials flow analysis, net energy analysis, input/output economic models, and novel metrics for measuring sustainable systems. Innovations in industrial ecology are encouraged. Green engineering:Research is encouraged to advance the sustainability of manufacturing processes, green buildings, and infrastructure. Many programs in the Engineering Directorate support research in environmentally benign manufacturing or chemical processes. The Environmental Sustainability program supports research that would affect more than one chemical or manufacturing process or that takes a systems or holistic approach to green engineering for infrastructure or green buildings. Improvements in distribution and collection systems that will advance smart growth strategies and ameliorate effects of growth are research areas that are supported by Environmental Sustainability. Innovations in management of storm water, recycling and reuse of drinking water, and other green engineering techniques to support sustainability may also be fruitful areas for research. Ecological engineering:Proposals should focus on the engineering aspects of restoring ecological function to natural systems. Engineering research in the enhancement of natural capital to foster sustainable development is encouraged. Earth systems engineering:Earth systems engineering considers aspects of large-scale engineering research that involve mitigation of greenhouse gas emissions, adaptation to climate change, and other global concerns. All proposed research should be driven by engineering principles, and be presented explicitly in an environmental sustainability context. Proposals should include involvement in engineering research of at least one graduate student, as well as undergraduates. Incorporation of aspects of social, behavioral, and economic sciences is welcomed. NOTE: Water treatment, air pollution (both outdoor and indoor), soil remediation, and solid waste treatment proposals are to besubmitted to theEnvironmental Engineeringprogram (CBET 1440). Innovative proposals outside the scope of the four core areas mentioned above 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. For proposals that call for research to be done on regions that are outside of the United States, an explanation must be presented of the potential benefit of the research for the United States. 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 &ldquo;What Has Been Funded (Recent Awards Made Through This Program, with Abstracts)&rdquo; 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.