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This program has been archived.


Improving Undergraduate STEM Education


CONTACTS
Name Email Phone Room
Myles  G. Boylan mboylan@nsf.gov (703) 292-4617   
Connie  K. Della-Piana cdellapi@nsf.gov (703) 292-5309   
Katherine  J. Denniston kdennist@nsf.gov (703) 292-8496   
Don  L. Millard dmillard@nsf.gov (703) 292-4620   


PROGRAM GUIDELINES

PD 14-7513

Important Information for Proposers

A revised version of the NSF Proposal & Award Policies & Procedures Guide (PAPPG) (NSF 22-1), is effective for proposals submitted, or due, on or after October 4, 2021. Please be advised that, depending on the specified due date, the guidelines contained in NSF 22-1 may apply to proposals submitted in response to this funding opportunity.


DUE DATES

Archived


SYNOPSIS

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. The goals of these investments include: increasing student retention in STEM, to prepare students well to participate in science for tomorrow, and to improve students' STEM learning outcomes.

Recognizing disciplinary differences and priorities, NSF's investment in research and development in undergraduate STEM education encompasses a range of approaches. These approaches include: experiential learning, assessment/metrics of learning and practice, scholarships, foundational education research, professional development/institutional change, formal and informal learning environments, and undergraduate disciplinary research. Both individually and integrated in a range of combinations, these approaches can lead to outcomes including: developing the STEM and STEM-related workforce, advancing science, broadening participation in STEM, educating a STEM-literate populace, improving K-12 STEM education, encouraging life-long learning, and building capacity in higher education.

The Division of Undergraduate Education (DUE), in collaboration with other NSF directorates, continues to support research and development leading to and propagating interventions that improve both the quality and quantity of STEM graduates.  A number of recent publications provide guidance.  For example, the President's Council of Advisors on Science and Technology (PCAST) report, Engage to Excel, recommends widespread adoption of empirically validated teaching practices that engage students in "active learning," as an important means to enhance retention of STEM majors. Other recommendations include increased use of discovery-based laboratories and course-based research. The National Research Council report, Discipline-based Education Research: Understanding and Improving Learning in Undergraduate Science and Engineering, provides an analysis of effective practices and a research agenda for continuing to build the knowledge base on how to improve undergraduate STEM education. The Common Guidelines for Education Research and Development offer guidance on building the evidence base in STEM learning. Research and development efforts that increase our understanding of effective undergraduate STEM teaching and learning provide the foundation for building the STEM workforce of tomorrow and improving scientific literacy.

Recognizing that the preparation of a globally-competitive workforce, including future teachers, and a scientifically literate populace requires excellent STEM education, DUE supports the improvement of the undergraduate STEM education enterprise through funding research on design, development, and wide-spread implementation of effective STEM learning and teaching knowledge and practice, as well as foundational research on student learning. DUE supports projects that build on both fundamental research in undergraduate STEM education and prior research and development that provide theoretical and empirical justification for the proposed efforts. Proposals should describe projects that build on available evidence and theory, and that will generate evidence and build knowledge.

NSF accepts unsolicited proposals to support projects that address immediate challenges and opportunities facing undergraduate STEM education, as well as those that anticipate new structures and functions of the undergraduate learning and teaching enterprise. In addition, NSF accepts unsolicited proposals for developing Ideas Labs in biology, engineering, and geosciences that will bring together relevant disciplinary and education research expertise to produce research agendas that address discipline-specific workforce development needs.


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