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The National Workforce Diversity Pipeline Program (NWDP) seeks to address health disparities among racial and ethnic minorities by supporting networks of institutions focused on, and with demonstrated commitment and capacity to establish pipeline programs to increase minority and disadvantaged students' (Appendix A) awareness of and pursuit in the areas of health care and behavioral health and increase the availability of STEM education programs.

RGK Foundation awards grants in the broad areas of Education, Community, and Health/Medicine. The Foundation's primary interests within Education include programs that focus on formal K-12 education (particularly mathematics, science and reading), teacher development, literacy, and higher education.

AAAS offers fellowships in nine programmatic areas. Specific host offices and assignments vary from year to year. Congressional Diplomacy, Security& Development Energy, Environment & Agriculture Health, Education & Human Services Big Data & Analytics Judicial Branch Roger Revelle Fellowship in Global Stewardship AAAS Overseas Fellowships at USAID Missions (limited eligibility) Global Health & Development Fellowships (limited eligibility)

The purpose of this Funding Opportunity Announcement (FOA) is to provide opportunities for eligible small business concerns (SBCs) to submit STTR grant applications to develop interactive digital media science, technology, engineering and mathematics (STEM) resources that address student career choice and health and medicine topics for: (1) pre-kindergarten to grade 12 (P-12) students and pre- and in-service teachers ("Teachers") or (2) Informal science education (ISE), i.e., outside the classroom, audiences. Interactive digital media (IDM) are defined as products and services on digital computer-based systems which respond to the user's actions by presenting content such as text, moving image, animation, video, audio, and video games. There is a large body of evidence that IDM technology has the potential to support learning in a variety of contexts from primary and secondary schools, to universities, adult education and workplace training. IDM is widely used to train, educate, and encourage behavioral changes in a virtual world format where progressive learning, feedback on success and user control are combined into an interactive and engaging experience. It is anticipated that this STTR FOA will facilitate the translation of new or existing health and medicine-based, P-12 STEM curricula and museum exhibits into educational Interactive Digital Media STEM (IDM STEM) resources that will provide a hands-on, inquiry-based and learning-by-doing experience for students, teachers and the community.

1. STEM Education: Grants support education programs that improve knowledge and literacy with a focus in the areas of science, technology, engineering and math among students, teachers, and the general public. 2. Environmental Sustainability: Grants support programs with the goal of preserving or restoring land, air, water, or biodiversity. 3. Community Safety and Vitality: Grants support programs that aim to improve the overall quality of life within a community by supporting initiatives that enhance safety and public well-being. Safety, health and wellness are vitally important to Westinghouse; our community commitment does not start and stop at the workplace door, but safety, health and wellness continue at home and in our community.

The goal of this NIEHS undergraduate research education R25 program is to support educational activities that enhance the diversity of the biomedical, behavioral and clinical research workforce in the environmental health sciences. To this end, this funding opportunity announcement (FOA) encourages the development of creative educational activities with a primary focus on research experiences for undergraduates at the junior and senior level.

The National Institutes of Health (NIH) seeks input on the restructuring of the NIH grant application instructions. We invite comments from any interested parties. We encourage feedback from PD/PIs, Administrative Offices, Offices of Sponsored Programs, Systems Administrators, and any other parties that rely on our application submission information.

This Funding Opportunity Announcement (FOA) solicits grant applications from institutions/organizations to serve as the Coordination Center (CC) for the Programs to Increase Diversity Among Individuals Engaged in Health-Related Research (PRIDE). This FOA runs parallel with a separate FOA that solicits applications for eight Summer Institutes (See RFA-HL-14-021). The Summer Institutes are designed to enable junior faculty and postdoctoral scientists transitioning into academic faculty positions, from underrepresented backgrounds, to further develop their research skills and knowledge to enhance their career development as faculty members and scientists.

NSF has long supported transformative research in artificial intelligence (AI) and machine learning (ML). The resulting innovations offer new levels of economic opportunity and growth, safety and security, and health and wellness. At the same time, broad acceptance of large-scale deployments of AI systems relies critically on their trustworthiness which, in turn, depends upon the collective ability to ensure, assess, and ultimately demonstrate the fairness, transparency, explainability, and accountability of such systems. Importantly, the beneficial effects of AI systems should be broadly available across all segments of society. NSF and Amazon are partnering to jointly support computational research focused on fairness in AI, with the goal of contributing to trustworthy AI systems that are readily accepted and deployed to tackle grand challenges facing society. Specific topics of interest include, but are not limited to transparency, explainability, accountability, potential adverse biases and effects, mitigation strategies, validation of fairness, and considerations of inclusivity. Funded projects will enable broadened acceptance of AI systems, helping the U.S. further capitalize on the potential of AI technologies.

The ASPB Education Foundation seeks proposals from ASPB members to support education and outreach activities that advance knowledge and appreciation of plant biology. The Foundation was established in 1995 with the main goal of enhancing public awareness and understanding of the role of plants in all areas of life. To this end, the Foundation supports education and outreach projects (i.e., NOT science research projects) that enrich and promote youth, student, and general public understanding of the: Importance of plants for the sustainable production of medicine, food, fibers, and fuels; Critical role plants play in sustaining functional ecosystems in changing environments; Latest developments in plant biotechnologies, including genetic modifications that improve the quality and disease- and stress-resistance of crops; Discoveries made in plants that have led to improved human health and wellbeing; and Range of careers related to plant biology or available to plant biologists.

The U.S. Embassy in Australia invites Australian organizations and individuals to submit proposals for funding of programs that increase mutual understanding between the U.S. and Australia and promote the bilateral relationship. Topic areas eligible for funding include: entrepreneurship and innovation; U.S. policies, society, culture and values; cultural diversity; academic integration and advancement; civic participation; countering violent extremism; global challenges such as climate change, clean energy, promotion of STEM, human rights, economic development, health, LGBTI issues, and marginalized populations. Most grants funded are in the $5,000 to $15,000 range, though proposals for higher amounts will be considered if the project is of particular value to advancing the U.S.-Australia relationship. Proposals that include cost sharing by the applicant or another relevant organization are encouraged.

Leidos will match high-scoring, unfunded National Institutes of Health (NIH) proposals with private biomedical foundations and/or industries seeking to fund promising research. Foundations will have access to peer-reviewed research proposals that directly relate to their funding priorities, industry will have access to a rich pipeline of early stage and translational research proposals that align with its priorities, while applicants with strong research proposals will be provided with a second opportunity to secure funding. The foundations, industries, applicants, and NIH all will benefit from this synergy.

A well-prepared, innovative science, technology, engineering and mathematics (STEM) workforce is crucial to the Nation's health and economy. Indeed, recent policy actions and reports have drawn attention to the opportunities and challenges inherent in increasing the number of highly qualified STEM graduates, including STEM teachers. Priorities include educating students to be leaders and innovators in emerging and rapidly changing STEM fields as well as educating a scientifically literate populace; both of these priorities depend on the nature and quality of the undergraduate education experience. In addressing these STEM challenges and priorities, the National Science Foundation invests in research-based and research-generating approaches to understanding STEM learning; to designing, testing, and studying curricular change; to wide dissemination and implementation of best practices; and to broadening participation of individuals and institutions in STEM fields. 

A well-prepared, innovative science, technology, engineering and mathematics (STEM) workforce is crucial to the Nation's health and economy. Indeed, recent policy actions and reports have drawn attention to the opportunities and challenges inherent in increasing the number of highly qualified STEM graduates, including STEM teachers. Priorities include educating students to be leaders and innovators in emerging and rapidly changing STEM fields as well as educating a scientifically literate populace. Both of these priorities depend on the nature and quality of the undergraduate education experience. In addressing these STEM challenges and priorities, the National Science Foundation invests in evidence-based and evidence-generating approaches to understanding STEM learning; to designing, testing, and studying instruction and curricular change; to wide dissemination and implementation of best practices; and to broadening participation of individuals and institutions in STEM fields. The goals of these investments include: increasing the number and diversity of STEM students, preparing students well to participate in science for tomorrow, and improving students' STEM learning outcomes.The Improving Undergraduate STEM Education (IUSE) program invites proposals that address immediate challenges and opportunities that are facing undergraduate STEM education, as well as those that anticipate new structures (e.g. organizational changes, new methods for certification or credentialing, course re-conception, cyberlearning, etc.) and new functions of the undergraduate learning and teaching enterprise. The IUSE program recognizes and respects the variety of discipline-specific challenges and opportunities facing STEM faculty as they strive to incorporate results from educational research into classroom practice and work with education research colleagues and social science learning scholars to advance our understanding of effective teaching and learning. Toward these ends the progr

A well-prepared STEM workforce capable of innovation is crucial to the Nation's health and economy. The Committee on Science, Technology, Engineering, and Mathematics Education (CoSTEM) under the National Science and Technology Council (NSTC) has developed a five-year strategic plan in support of science, technology, engineering, and mathematics (STEM) education. Among the strategic objectives identified in the plan is a call for broader implementation of effective instructional practices and advances in education. To challenge NSF researchers to think beyond their research results and toward broader adoption of STEM education and learning innovations, NSF's Innovation Corps Teams Program (I-Corps Teams - a description of which can be found in the I-Corps Teams solicitation) will encourage proposals that take discoveries and promising practices from education research and development and promote opportunities for widespread adoption, adaptation, and utilization. I-Corps for Learning (I-Corps L) Teams will receive support - in the form of mentoring and funding - to accelerate innovation in learning that can be successfully scaled, in a sustainable manner. Getting the best evidence-based practices out to potential adopters where those practices can benefit large numbers of students or learners, rather than just in a few classrooms or informal learning organizations, requires an entrepreneurial approach. There are a number of analogous elements between trying to bring product discoveries to market and getting learning innovations into broad practice that NSF can leverage to help promote widespread use of promising educational learning practices. Through I-Corps L, the tools of science can benefit education researchers by helping them to identify approaches that are effective in STEM teaching and learning. To be eligible to pursue funding, proposers must have received a prior award from NSF (in a STEM education field relevant to the proposed innovation) that is

A well-prepared, innovative science, technology, engineering and mathematics (STEM) workforce is crucial to the Nation's health and economy. Indeed, recent policy actions and reports have drawn attention to the opportunities and challenges inherent in increasing the number of highly qualified STEM graduates, including STEM teachers. Priorities include educating students to be leaders and innovators in emerging and rapidly changing STEM fields as well as educating a scientifically literate populace. Both of these priorities depend on the nature and quality of the undergraduate education experience. In addressing these STEM challenges and priorities, the National Science Foundation invests in evidence-based and evidence-generating approaches to understanding STEM learning; to designing, testing, and studying instruction and curricular change; to wide dissemination and implementation of best practices; and to broadening participation of individuals and institutions in STEM fields. The goals of these investments include: increasing the number and diversity of STEM students, preparing students well to participate in science for tomorrow, and improving students' STEM learning outcomes.

A well-prepared, innovative science, technology, engineering and mathematics (STEM) workforce is crucial to the Nation's health and economy. Indeed, recent policy actions and reports have drawn attention to the opportunities and challenges inherent in increasing the number of highly qualified STEM graduates, including STEM teachers. Priorities include educating students to be leaders and innovators in emerging and rapidly changing STEM fields as well as educating a scientifically literate populace. Both of these priorities depend on the nature and quality of the undergraduate education experience. In addressing these STEM challenges and priorities, the National Science Foundation invests in evidence-based and evidence-generating approaches to understanding STEM learning; to designing, testing, and studying instruction and curricular change; to wide dissemination and implementation of best practices; and to broadening participation of individuals and institutions in STEM fields. The goals of these investments include: increasing the number and diversity of STEM students; preparing students well to participate in science for tomorrow;, and improving students' STEM learning outcomes.

Communities in the United States (US) and around the world are entering a new era of transformation in which residents and their surrounding environments are increasingly connected through rapidly-changing intelligent technologies. This transformation offers great promise for improved wellbeing and prosperity but poses significant challenges at the complex intersection of technology and society. The goal of the NSF Smart and Connected Communities (S&CC) program solicitation is to accelerate the creation of the scientific and engineering foundations that will enable smart and connected communities to bring about new levels of economic opportunity and growth, safety and security, health and wellness, and overall quality of life. For the purposes of this solicitation, communities are defined as having geographically-delineated boundaries-such as towns, cities, counties, neighborhoods, community districts, rural areas, and tribal regions-consisting of various populations, with the structure and ability to engage in meaningful ways with proposed research activities. A "smart and connected community" is, in turn, defined as a community that synergistically integrates intelligent technologies with the natural and built environments, including infrastructure, to improve the social, economic, and environmental well-being of those who live, work, or travel within it.

A well-prepared, innovative science, technology, engineering and mathematics (STEM) workforce is crucial to the Nation's health and economy. Indeed, recent policy actions and reports have drawn attention to the opportunities and challenges inherent in increasing the number of highly qualified STEM graduates, including STEM teachers. Priorities include educating students to be leaders and innovators in emerging and rapidly changing STEM fields as well as educating a scientifically literate populace. Both of these priorities depend on the nature and quality of the undergraduate education experience. In addressing these STEM challenges and priorities, the National Science Foundation invests in evidence-based and evidence-generating approaches to understanding STEM learning; to designing, testing, and studying instruction and curricular change; to wide dissemination and implementation of best practices; and to broadening participation of individuals and institutions in STEM fields. The goals of these investments include: increasing the number and diversity of STEM students; preparing students well to participate in science for tomorrow; and improving students' STEM learning outcomes. NSF’s Improving Undergraduate STEM Education (IUSE) initiative, launched in Fiscal Year 2014, supports a coherent set of investments to address immediate challenges and opportunities that are facing undergraduate STEM education, as well as those that anticipate new structures (e.g. organizational changes, new methods for certification or credentialing, course re-conception, cyberlearning, etc.) and new functions of the undergraduate learning and teaching enterprise.

A well-prepared, innovative science, technology, engineering and mathematics (STEM) workforce is crucial to the Nation's health and economy. Indeed, recent policy actions and reports have drawn attention to the opportunities and challenges inherent in increasing the number of highly qualified STEM graduates, including STEM teachers. Priorities include educating students to be leaders and innovators in emerging and rapidly changing STEM fields as well as educating a scientifically literate populace. Both of these priorities depend on the nature and quality of the undergraduate education experience. In addressing these STEM challenges and priorities, the National Science Foundation invests in evidence-based and evidence-generating approaches to understanding STEM learning; to designing, testing, and studying instruction and curricular change; to wide dissemination and implementation of best practices; and to broadening participation of individuals and institutions in STEM fields. The goals of these investments include: increasing the number and diversity of STEM students; preparing students well to participate in science for tomorrow; and improving students' STEM learning outcomes.