This document is the final evaluation report for the project, which focuses both on formative evaluation of the collaborative+interdisciplinary presentation creation process and summative evaluation of audience learning outcomes.
Research shows that algebra is a major barrier to student success, enthusiasm and participation in STEM for under-represented students, particularly African-American students in under-resourced high schools. Programs that develop ways to help students master algebra concepts and a belief that they can perform algebra may lead to more students entering engineering careers. This project will provide an online engineering program to support 9th and 10th grade Baltimore City Public Schools students, a predominantly low-income African-American cohort, to develop concrete goals of becoming engineers. The goals of the program are to help students with a growing interest in engineering to maintain that interest throughout high school. The project will also support students aspire to an engineering career. The project will develop in students an appreciation of requisite courses and skills, and increase self-efficacy in mathematics. The project will also develop a replicable model of informal education capable of reinforcing the mathematical foundations that students learn during the school day. Additionally, the project will broaden participation in engineering by being available to students during out-of-school time and by having relaxed entrance criteria compared to existing opportunities in supplemental engineering curricula. The project is a collaboration between the Baltimore City Public Schools, Johns Hopkins University Applied Physics Laboratory, Northrop Grumman Corporation, and Expanded School-Based Mental Health programs to support students both during and after participation. The project will benefit society by providing skills that will allow high school students to become members of tomorrow's highly trained STEM workforce.
The research will test whether an informal, scaffolded online algebra-for-engineering program increases students' mastery and self-efficacy in mathematics. The research will advance knowledge regarding informal education by applying Social Cognitive Career Theory as a framework for measuring program impact. The theoretical framework will aid in identifying mechanisms through which students with interest in engineering might persist in maintaining this interest through high school via algebra skill mastery and increased self-efficacy. The project will recruit 200 youth from the Baltimore City Public Schools to participate in the project over three years. Qualitative data will be collected to assess how student and school socioeconomic factors impact implementation, student engagement, and outcomes. The research will answer the following questions: 1) What effect does program participation have on math mastery? 2) What direct and indirect effects do program completion and supports have on students' mathematics self-efficacy? 3) What direct and indirect effects do program components have on engineering career goals by the end of the program? 4) What direct and indirect effects does math self-efficacy have on career goals? 5) To what extent are the effects of program participation on engineering career goals mediated by math self-efficacy and engineering interest? 6) How do school factors relate to the implementation of the program? 7) What socioeconomic-related factors relate to the regularity and continuation of student participation in the program? The quantitative methods of data analysis will employ descriptive and multivariate statistical methods. Qualitative data from interviews will be analyzed using an emergent approach and a coding scheme guided by theoretical constructs. Project results will be communicated to scholars and practitioners. The team will also share information through school newsletters and parent communication through Baltimore City Public Schools.
This project is funded by the Innovative Technology Experiences for Students and Teachers (ITEST) program, which supports projects that build understandings of practices, program elements, contexts and processes contributing to increasing students' knowledge and interest in science, technology, engineering, and mathematics (STEM) and information and communication technology (ICT) careers.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Underrepresented minorities (URMs) are less than 10% of engineering faculty, despite comprising nearly a third of the nation's population. A common explanation for their disproportionate representation, at the engineering faculty level, is related to a lack of access to effective mentorship from other faculty. This NSF INCLUDES Design and Development Launch Pilot project will expand a new mentoring and advocacy-networking paradigm to bring together two stakeholder groups: (1) underrepresented minorities (URMs) who are engineering faculty and (2) well-regarded (primarily non-URM) emeriti/retired engineering faculty. A previously-funded NSF project found that this mentor-mentee pairing was viewed favorable by both parties and beneficial, particularly by the URM engineering faculty. Because of these results, the investigators proposed to scale, test, and evaluate the approach on a broader scale by creating national infrastructural network partners to help increase capacity to serve a greater number of URM engineering faculty and to introduce tele-mentoring and training models to serve URM faculty who work in remote geographical locations with very little access to mentors.
The project will use a multi-phased phenomenological, mixed method research design to gain greater understanding of the ways in which the URM faculty and emeriti faculty experience the opportunities afforded by the project. Further, the investigators plan to collect data to examine how project participants perceive and experience conventional, direct communications (e.g., telephone calls, e-mail, and in-person meetings)through the mentoring process versus the use of Embodied Conversational Agents (ECAs), anthropomorphic interface agents that engage a user in real-time dialogue by using verbal-nonverbal channels to emulate the in-person experience. This project has the potential to broaden participation in the engineering professoriate and opens up new possibilities for supporting URM engineering faculty.
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TEAM MEMBERS:
Comas HaynesValerie ConleySylvia MendezKinnis GoshaRosario Gerhardt
Worldwide, four million people participate in geocaching--a game of discovering hidden treasures with GPS-enabled devices (including smart phones). Geocachers span all ages and tend to be interested in technology and the outdoors. To share information about the Montana Climate Assessment (MCA), an NSF-funded scientific report, Montana State University created a custom trackable geocaching coin featuring the MCA Website and logo. We then recruited volunteers to hide one coin in each of Montana’s 56 counties. Volunteer geocachers enthusiastically adopted all 56 counties, wrote blogs and social media posts about the coins, and engaged local Scout troops and schools. Other geocachers then found and circulated the coins while learning about Montana’s climate. One coin has traveled nearly 4,000 miles; several have visited other states and Canada. 95% of the volunteers said the project made them feel more connected to university research, and they told an average of seven other people about the project. Nearly all of the participants were unfamiliar with the Montana Climate Assessment prior to participating. The geocaching educational outreach project included several partnerships, including with Geocaching Headquarters in Seattle (a.k.a. “Groundspeak”); Cache Advance, Inc., an environmentally friendly outdoor gear company; and Gallatin Valley Geocachers. An advisory board of geocachers helped launch the project.
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TEAM MEMBERS:
Suzi TaylorRay CallawayM.J. NehasilCathy Whitlock
Charles Darwin is largely unknown and poorly understood as a historical figure. Similarly, the fundamental principles of evolution are often miss-stated, misunderstood, or entirely rejected by large numbers of Americans. Simply trying to communicate more facts about Darwin, or facts supporting the principles of evolution is inadequate; neither students nor members of the public will care or retain the information. On the contrary, building facts into a one-on-one conversational narrative creates an memorable opportunity to learn. Here, we create a digital-media, self-guided question and answer
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TEAM MEMBERS:
David J. LampeBrinley KantorskiJohn Pollock
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. This project will develop and test intergenerational science media resources for parents that are participating in adult education programs and their young children. The materials will build on the research-based and successful children's television program, Fetch with Ruff Ruffman. The target audience includes parents enrolled in adult education programs who lack a high school diploma or are in English as a Second Language classes. These resources will support parents' engagement in science activities with their children both in the adult education settings as well as at home. Adult and family educators will receive professional development resources and training to support their integration of the parent/child activities. Project partners include the National Center for Families Learning, Kentucky Educational Television, and Alabama Public Television,
The goals of the Ruff Family Science project are to: (1) investigate adult education settings that feature an intergenerational learning model, in order to learn about the unique characteristics of adults and families who are enrolled in these programs; (2) examine the institutional circumstances and educator practices that support joint parent/child engagement in science; (3) iteratively develop new prototype resources meet the priorities and needs of families and educators involved in intergenerational education settings; and (4) develop the knowledge needed to create a fuller set of materials in the future that will motivate and support diverse, low-income parents to investigate science with their children. The research strategy is comprised of three main components: Phase 1: Needs Assessment: Determine key motivations and behaviors common to adult education students who are also parents; surface obstacles and assets inherent in these parents' current practices; and examine the needs and available resources for supplementing parents' current engagement in family science learning. Phase 2: Prototype Development: Iteratively develop two prototype Activity Sets, along with related educator supports and training materials, designed to promote joint parent-child engagement with English and Spanish-speaking families around physical science concepts. Phase 3: Prototype Field Test: Test how the two refined prototype Activity Sets work in different educational settings (adult education, parent education, and parent and child together time). Explore factors that support or impede effective implementation. Sources of data for the study include observations of adult and parent education classes using an expert interview protocol, focus groups, adult and family educator interviews, and parent surveys.
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. The goal of this project is to make 21st century quantum science comprehensible and engaging to non-expert informal adult learners. This project has strong potential to add new knowledge about the public's perception and understanding of quantum physics. This scientific content is often difficult for informal audiences to grasp, and there are relatively few accessible learning resources for a non- professional audience. The development of this online, interactive resource with short animations, graphics, and simulations has strong potential to fill this gap. It will develop a visually driven online resource to engage non-expert audiences in understanding the basics of quantum physics. The web design will be modular, incorporating many multimedia elements and the structure will be flexible allowing for future expansion. All content would be freely available for educational use. There is potential for extensive reach and use of the resources by informal adult learners online as well as learners in museums, science centers, and schools. Project partners are the Joint Quantum Institute at the University of Maryland and the National Institute of Standards and Technology, College Park. An independent evaluation of the project will add new knowledge about informal learners' perceptions and/or knowledge about quantum science and technology. An initial needs assessment via focus groups with the general public will be designed to find out more about what they already know about quantum physics topics and terminology, as well as what they want to know and what formats they prefer (games, simulations, podcasts, etc.). In person user testing will be used with early versions of the project online resource using a structured think-aloud protocol. Later in year 1 and 2, online focus groups with the general public will be conducted to learn what they find engaging and what they learned from the content. Iterative feedback from participants during the formative stage will guide the development of the content and format of the online resources. The Summative Evaluation will gather data using a retrospective post-survey embedded with a pop-up link on the Atlas followed by interviews with a subset of online users. Google Analytics will be used to determine the breadth and depth of their online navigation, what resources they download, and what websites they visit afterward. A post-only survey of undergraduate and graduate students who participated in resource development will focus on changes in students' confidence around their science communication skills and level of quantum physics understanding.
This poster was presented at the 2016 Advancing Informal STEM Learning (AISL) PI Meeting held in Bethesda, MD on February 29-March 2. The United States is facing a crisis: not enough students are being trained in the areas of science, technology, engineering and mathematics (STEM) to support and foster economic growth. In response, the State University of New York (SUNY) and the New York Academy of Sciences (The Academy) are collaborating to train SUNY graduate students and post-doctoral fellows to deliver mentoring and STEM content to underserved middle-school children in afterschool programs
The Mabee Library at MidAmerica Nazarene University will create a Center for Games and Learning, which will be used to incorporate games in higher education curricula and academic life, with the goal of promoting skills such as collaboration, critical thinking, and strategic thinking. A cohort of faculty members will incorporate games into selected courses, and evaluations will be performed to assess the acquisition of skills through gaming. Following the dissemination of these findings, the Center for Games and Learning will remain as a pioneering campus resource for future faculty to incorporate in their courses.
In this article, I review recent findings in cognitive neuroscience in learning, particularly in the learning of mathematics and of reading. I argue that while cognitive neuroscience is in its infancy as a field, theories of learning will need to incorporate and account for this growing body of empirical data.
This poster was presented at the 2014 AISL PI Meeting in Washington, DC. This project seeks to improve public engagement in climate communication by broadcast meteorologists, using scientific methods to identify probable causes for their skepticism and/or reticence, and to test the efficacy of proposed solutions.
The authors of this article discuss three pedagogical approaches, learning community, community of practice and community learning, and analyse their significance for knowledge acquisition and construction in higher education. The authors also explore the roles of technology in creating adequate environments for educators to implement teaching practices supported by these approaches and explain, through an illustrative course example, how technology and teaching methods can be used together to promote interaction among learners and help them achieve course goals.