Little scholarly investigation of chemistry outreach carried out by undergraduate students in schools and communities has occurred despite widespread practice and monetary investment by large national and international organizations. This study provides the first investigation of these fairly uncharted waters by characterizing expected outcomes of outreach events, the types of activities and chemistry content widely practiced, and how outreach practitioners evaluate the success of events. Results from an open-ended survey deployed nationally to college students and faculty/staff members
Physical science and engineering remain the least diverse of all STEM fields---with regard to women, underrepresented minorities, and persons with disabilities---across all levels of STEM education and training. SCI-STEPS is an NSF INCLUDES Design and Development Launch Pilot that will address this persistent challenge by developing a complete end-to-end pipeline (or system of pathways) from the beginning of college to the PhD, and then into the workforce. Many isolated efforts to broaden participation have shown promise, but they have not produced big enough impact. SCI-STEPS represents a concerted set of coordinated interventions---consciously facilitated, systemically linked, and purposefully disseminated. SCI-STEPS represents a broad regional network among major research universities, Historically Black Colleges and Universities, comprehensive universities, community colleges, national labs, and major scientific organizations. The goal of the network is to ensure that underrepresented individuals in the physical sciences and engineering can get from their starting point in STEM higher education---freshmen at 2-year or 4-year college---through the higher education pathways leading to an appropriate terminal degree and employment in the STEM workforce.
Women, underrepresented minorities, and persons with disabilities collectively represent the majority of college-age individuals entering higher education with an expressed interest in physical science and engineering. A growing body of research indicates that academic and social integration may be even more influential than academic abilities for retention of students. Thus, interventions aimed at stemming the losses of these individuals must ultimately be aimed at changing the system---including unwelcoming institutional climates, racial/ethnic/gender stereotyping, a lack of mentors with whom to identify, and evaluation methods that emphasize conformity over individual capabilities---rather than changing the individual. The SCI-STEPS pilot focuses effort on institutional readiness for implementation of best practice interventions at four key junctures: (i) college freshman to sophomore; (ii) undergraduate to graduate; (iii) PhD to postdoc; and (iv) postdoc to workforce.The pilot will proceed in three steps: (1) a planning phase, (2) development of an initial end-to-end pathways model with four Juncture Transition teams, and (3) scale-up of the SCI-STEPS "network of networks" with all initial partners. By addressing these objectives through a collective impact framework and embedded research, this pilot will demonstrate how best-practice interventions at each pathway juncture can be dovetailed and scaled up across a broad range of institutional types and across a large but distinct geographical area. Addressing these objectives will thus also serve to advance Broadening Participation efforts at a national scale, by suggesting the forms of institutional partnerships and best-practices that may inform other alliances in other STEM disciplines and/or different regional areas.
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TEAM MEMBERS:
Keivan StassunNicole JosephKelly Holley-BockelmannWilliam RobinsonRoger Chalkley
Lack of diversity in science and engineering education has contributed to significant inequality in a workforce that is responsible for addressing today's grand challenges. Broadening participation in these fields will promote the progress of science and advance national health, prosperity and welfare, as well as secure the national defense; however, students from underrepresented groups, including women, report different experiences than the majority of students, even within the same fields. These distinctions are not caused by the students' ability, but rather by insufficient aspiration, confidence, mentorship, instructional methods, and connection and relevance to their cultural identity. The long-term vision of this project is to amplify the impact of a successful broadening participation model at the University of Maine, the Stormwater Research Management Team (SMART). This program trains students and mentors in using science and engineering skills and technology to research water quality in their local watershed. Students engage in numerous science and technology fields: engineering design, data acquisition, analysis and visualization, chemistry, environmental science, biology, and information technology. Students also connect with a diversity of professionals in water and engineering in government, private firms and non-profits. SMART has augmented the traditional science and engineering classroom by engaging students in guided mentored apprenticeships that address community problems.
Technical
This pilot project will form a collaborative and define a strategic plan for scale-up to a national alliance to increase the long-term success rate of underrepresented minority students in science, engineering, and related fields. The collaborative of multiple and varied organizations will align to collectively contribute time and resources to a pre-college educational pathway. There are countless isolated programs that offer short-term interventions for underrepresented and minority students; however, there is lack of organizational coordination for aligning current program offerings, sharing best practices, research results or program outcomes along the education to workforce pathway. The collaborative activities will focus on the transition grades (e.g., 4-5, 8, and high school) and emphasize relationships among skills, confidence, culture and future careers. Collaborative partners will establish a centralized infrastructure in each location to coordinate recruiting of invested community leaders, educators, and parents, around a common agenda by designing, deploying and continually assessing a stormwater-themed project that addresses their location and demographic specific needs. This collaborative community will consist of higher education faculty and students, K-12 students, their caregivers, mentors, educators, stormwater districts, state and national environmental protection agencies, departments of education, and other for-profit and non-profit organizations. The collaborative will address the need for research on mechanisms for change, collaboration, and negotiation regarding the greater participation of under-represented groups in the science and technology workforce.
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TEAM MEMBERS:
Mohamed MusaviVenkat BhethanabotlaCary JamesVemitra WhiteLola Brown
The CSMC-OMSI Partnership for Public Engagement (COPPE) project was developed to establish a strong and long-lasting partnership between the Center for Sustainable Materials Chemistry (CSMC) and the Oregon Museum of Science and Industry (OMSI). Through participation in this project, COPPE researchers and OMSI educators sought a deeper understanding of each other's profession while simultaneously developing a suite of Informal Science Education (ISE) outreach programs that engage the public in new and enduring ways. These new ISE platforms were developed to enhance public awareness in the areas
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TEAM MEMBERS:
Oregon Museum of Science and IndustryAnne Sinkey
American Chemical Society President Bassam Z. Shakhashiri appointed and charged this Commission to undertake a wholesale review of graduate education in the chemical sciences over a yearlong period. This document is a compact rendition of the Commission's final report, emphasizing only main conclusions and recommendations. The Commission judges that the sate of graduate education in the chemical sciences is healthy in many respects, but has not kept pace with the significant changes in the world's economic, social, and political environment since the end of World War II, when the current
We a have full slate of programs including science academies for underrepresented high school and middle school students; Large programs for the public including holiday lectures, stars of materials science lectures, materials science and nano days for the public; Teacher development programs including Research Experience for Teachers and Teachers as Scholars; Research Experience for Undergraduates; Graduate Summer School on Condensed Matter; and many other programs.
The PhET Interactive Simulations group at the University of Colorado is expanding their expertise of physics simulations to the development of eight-to-ten simulations designed to enhance students' content learning in general chemistry courses. The simulations are being created to provide highly engaging learning environments which connect real life phenomena to the underlying science, provide dynamic interactivity and feedback, and scaffold inquiry by what is displayed and controlled. In a second strand of the project, a group of experienced faculty participants are developing and testing lecture materials, classroom activities, and homework, all coordinated with well-established, research-based teaching methods like clicker questions, peer instruction, and/or tutorial-style activities, to leverage learning gains in conjunction with the simulations. The third strand of the project focuses on research on classroom implementation, including measures of student learning and engagement, and research on simulation design. This strand is establishing how specific characteristics of chemistry sim design influence engagement and learning, how various models of instructional integration of the sims affect classroom environments as well as learning and engagement, and how sim design and classroom context factors impact faculty use of sims. To ensure success the project is basing sim design on educational research, utilizing high-level software professionals (to ensure technically sophisticated software, graphics, and interfaces) working hand-in-hand with chemistry education researchers, and is using the established PhET team to cycle through coding, testing, and refinement towards a goal of an effective and user friendly sim. The collection of simulations, classroom materials, and faculty support resources form a suite of free, web-based resources that anyone can use to improve teaching and learning in chemistry. The simulations are promoting deep conceptual understanding and increasing positive attitudes about science and technology which in turn is leading to improved education for students in introductory chemistry courses both in the United States and around the world.
The Physics and Chemistry Education Technology (PhET) Project is developing an extensive suite of online, highly-interactive simulations, with supporting materials and activities for improving both the teaching and learning of physics and chemistry. There are currently over 70 simulations and over 250 associated activities available for use from the PhET website (http://phet.colorado.edu). These web-based resources are impacting large number of students. Per year, there are currently over 4 million PhET simulations run online and thousands of full website downloads for offline use of the simulations. The goal is that this widespread use of PhET's research-based tools and resources will improve the education of students in physics and chemistry at colleges and high schools throughout the U.S. and around the world. This PhET project combines a unique set of features. First, the simulation designs and goals are based on educational research. Second, using a team of professional programmers, disciplinary experts, and education research specialists enables the development of simulations involving technically-sophisticated software, graphics, and interfaces that are highly effective. Third, the simulations embody the predictive visual models of expert scientists, allowing many interesting advanced concepts to become widely accessible and revealing their relevance to the real world. And finally, the project is actively involved in research to better understand how the design and use of simulations impacts their effectiveness - e.g. investigating questions such as "How can these new technologies promote student understanding of complex scientific phenomena?" and "What factors inhibit or enhance their use and effectiveness?".
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TEAM MEMBERS:
Katherine PerkinsMichael DubsonNoah FinkelsteinRobert ParsonCarl Weiman