This annual report presents an overview of Saint Louis Science Center audience data gathered through a variety of evaluation studies conducted during 2015. This report includes information on the Science Center's general public audience demographics and visitation patterns, gives an overview of visitors' comments about their Science Center experience, summarizes major trends observed in the Science Center's tool for tracking educational programs, and presents highlights from a Membership study, a formative evaluation of a new Makerspace exhibition, and program evaluation of a workshop for the
The Cyberlearning and Future Learning Technologies Program funds efforts that will help envision the next generation of learning technologies and advance what we know about how people learn in technology-rich environments. Cyberlearning Exploration (EXP) Projects explore the viability of new kinds of learning technologies by designing and building new kinds of learning technologies and studying their possibilities for fostering learning and challenges to using them effectively. This project brings together two approaches to help K-12 students learn programming and computer science: open-ended learning environments, and computer-based learning analytics, to help create a setting where youth can get help and scaffolding tailored to what they know about programming without having to take tests or participate in rigid textbook exercises for the system to know what they know.
The project proposes to use techniques from educational data mining and learning analytics to process student data in the Alice programming environment. Building on the assessment design model of Evidence-Centered Design, student log data will be used to construct a model of individual students' computational thinking practices, aligned with emerging standards including NGSS and research on assessment of computational thinking. Initially, the system will be developed based on an existing corpus of pair-programming log data from approximately 600 students, triangulating with manually-coded performance assessments of programming through game design exercises. In the second phase of the work, curricula and professional development will be created to allow the system to be tested with underrepresented girls at Stanford's CS summer workshops and with students from diverse high schools implementing the Exploring Computer Science curriculum. Direct observation and interviews will be used to improve the model. Research will address how learners enact computational thinking practices in building computational artifacts, what patters of behavior serve as evidence of learning CT practices, and how to better design constructionist programming environments so that personalized learner scaffolding can be provided. By aligning with a popular programming environment (Alice) and a widely-used computer science curriculum (Exploring Computer Science), the project can have broad impact on computer science education; software developed will be released under a BSD-style license so others can build on it.
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TEAM MEMBERS:
Shuchi GroverMarie BienkowskiJohn Stamper
We asked science centers and museums to share their best pieces of advice and most important lessons learned regarding the following: 1) selecting topics and activities for out-of-school time programs, 2) partnering with afterschool providers and other community partners, 3) meeting the needs of underserved communities in out-of-school time programs, and 4) running successful camps or programs during school vacations.
In the 11 years since the inception of the Science Minors and Achievers program, the Museum of Science and Industry (MSI), Chicago, has had plenty of anecdotal evidence that this out-of-school time program has a meaningful impact on its participants. Word of mouth was the strongest driver of recruitment, and teens were open with staff about other aspects of their lives. These and other characteristics suggested a deep connection between teens and the program. As the program grew in popularity and size, the museum wanted to see whether these informal observations survived more rigorous scrutiny
This project will advance efforts of the Innovative Technology Experiences for Students and Teachers (ITEST) program to better understand and promote practices that increase students' motivations and capacities to pursue careers in fields of science, technology, engineering, or mathematics (STEM) by producing empirical findings and/or research tools that contribute to knowledge about which models and interventions with K-12 students and teachers are most likely to increase capacity in the STEM and STEM cognate intensive workforce of the future.
The LinCT (Linking Educators, Youth, and Learners in Computational Thinking) project at the Science Museum of Minnesota (SMM) will engage female teachers-in-training and youth from underrepresented demographics in immersive technology experiences and STEM education. LinCT will guide teachers to develop their understanding and use of technology in the classroom, as well as prepare youth for a future where technology plays a key role in a wide range of professional opportunities. The project aims to inspire teachers and youth to see the possibilities of technological competencies, as well as why the incorporation of technology can build meaningful learning experiences and opportunities for all learners. The LinCT program model offers learning and application experiences for participating teachers and youth and provides an introduction of technological tools used in SMM educational programs and professional development on approaches for engaging all learners in STEM. Both groups will provide instruction in SMM technology-based Summer Camps, reaching 1,000 young people every year. In each following school year, project educators will develop and deliver technology-based programs to nearly 1,000 under-served and underrepresented elementary students. The project will allow teachers and youth to deliver exciting and engaging technology-based programs to nearly 4,000 diverse young learners. As a result, all participants in this project will be better equipped to incorporate technology in their future careers.
The LinCT project will investigate effective approaches for broadening the participation of underrepresented populations by providing female pre-service teachers and female youth with opportunities to lead programming at the Science Museum of Minnesota (SMM). Over three years, the LinCT project will employ 8-12 female teachers-in-training [Teacher Tech Cadres (TTC)] and 12-24 female youth [Youth Teaching Tech Crews (Y-TTC)] from demographics that are underrepresented in STEM fields. The integration of these groups will result in relationships fostered within an educational program, where all participants are learners and teachers, mentors and mentees. The results of this unique program model will be assessed through the experiences of this focused professional learning and teaching community. The LinCT research study will focus on three aspects of the project. First, it will seek to understand how the teachers-in-training and youth experience the project model's varied learning environments. Next, the study will explore how the TTC's and the Y-TTC's motivation, confidence, and self-efficacy with integrating technology across educational settings change because of the program. Finally, the study will seek to understand the lasting aspects of culture, training, and community building on SMM's internal teams and LinCT partner institutions (University of St. Catherine's National Center for STEM Elementary Education and Metropolitan State University's School of Urban Education).
The Center for the Advancement of Informal Science Education defines informal STEM education as “lifelong learning in science, technology, engineering, and math (STEM) that takes place across a multitude of designed settings and experiences outside of the formal classroom.” The design of an informal experience can vary widely. On one end of the spectrum are free-choice learning experiences, where participants determine what they want to learn, when they want to do it, and how and with whom they want to study. On the opposite end of the spectrum is nonformal learning, which includes any
The lack of equitable access to science learning for marginalized groups is now a significant concern in the science education community (Bell et al. 2009). In our commitment to addressing these concerns, we (the HERP Project staff) have spent four years exploring different ways to increase diverse student participation in our informal science programs called herpetology research experiences (HREs). We wanted the demographics of participants to mirror the racial, ethnic, cultural, linguistic, and socioeconomic demographics of the areas where our HREs are held. To achieve this, project staff
The “Fourth Industrial Revolution” is transforming the world of work. Just as it happened with the technologies of the steam, electricity and computer revolutions, digital technologies are now becoming pervasive and reshaping all parts of the global economy. The computing industry’s rate of job creation in the U.S. is now three times the U.S. national average. This rapid expansion of the computing workforce means that computing skills – with coding at the core – are the most sought-after skills in the American job market.
Yet amid this boom, research by Accenture and Girls Who Code shows
Northern Michigan University's Center for Native American Studies and the Office of Diversity and Inclusion will lead this Design and Development Launch Pilot about culturally inclusive K-16 STEM education for American Indian and Native Alaskan (AIAN) students. This project was created in response to the NSF Inclusion across the Nation of Communities of Learners of Underrepresented Discoverers in Engineering and Science (NSF INCLUDES) program solicitation (NSF 16-544). The INCLUDES program is a comprehensive national initiative designed to enhance U.S. leadership in science, technology, engineering and mathematics (STEM) discoveries and innovations focused on NSF's commitment to diversity, inclusion, and broadening participation in these fields. The INCLUDES Design and Development Launch Pilots represent bold, innovative ways for solving a broadening participation challenge in STEM.
The full participation of all of America's STEM talent is critical to the advancement of science and engineering for national security, health and prosperity. Our nation is advancing knowledge and practices to address the undergraduate STEM achievement and the graduation gap between NAAIs and non-native Americans. This project, the NSF INCLUDES: Indigenous Women Working Within the Sciences (IWWS), has the potential to advance knowledge, instructional pedagogy and practices to improve the performance of NAAI high school students and undergraduate students in STEM.
This project team will work to: (1) pilot activities and coursework to train K-16 STEM educators about American Indian inclusive methods and materials, (2) to provide AIAN high school students with STEM college preparatory experience using inclusive STEM practices, and (3) to provide a cohort of female AIAN high school students additional university experiences and mentors as these students transition to postsecondary education. Activities include a five-day summer educators institute for 40 K-16 STEM educators, an additional weekend workshop for 20 K-16 STEM educators, a summer STEM academy for 96 AIAN high school students, a STEM weekend workshop for female AIAN high school students, and a mentoring program for AIAN high school students.
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TEAM MEMBERS:
April LindalaJessica CruzMartin Reinhardt
The Mississippi Alliance for Women in Computing (MAWC) project will identify factors that influence and motivate female students and female African American students in Mississippi to enroll and persist in an undergraduate engineering- or science-based computing major. There is a particular need for programming that is inclusive of women and women of color who are from the southern region of the United States. These students typically have less access to extracurricular activities that encourage computing, and are less likely to visualize themselves in a computing major or career. This proposed research is to help girls to know that computer science exists and what jobs in computer science are available with a degree in computer science. A rich environment exists in Mississippi for an alliance focused on building co-curricular and mentorship opportunities. A scalable pipeline model, expandable to a Southern Alliance for Women in Computing (SAWC), will be developed with three major objectives: to attract women and women of color to computing, to improve retention rates of women in undergraduate computing majors, and to help postsecondary women make the transition to the computing workforce. Activities to support these objectives include: scaling the National Center for Women and Information Technology Aspirations in Computing award program in Mississippi, expanding scholarships for Aspirations winners, expanding student-led computing outreach programs, establishing a Mississippi Black Girls Code chapter, informing and collaborating with the Computer Science for Mississippi initiative, creating a summer bridge and living-learning community for women in computing majors, and increasing professional development opportunities for women in computing through conferences, lunch and learn meetings, job shadowing, and internships.
The project will analyze whether the co-curricular activities of MAWC lead to computing self-efficacy and ultimately female students selecting to pursue and persist in computing majors and careers. In order to understand student participation and efficacy changes, data collection for this research will be through demographic and background surveys administered to women entering an undergraduate engineering- or science-based computing major at a university in Mississippi and student surveys and evaluations in MAWC-sponsored programs. Using discriminate analysis methods, specific research questions to be addressed are: 1) Which pre-collegiate experiences influenced them to enroll, 2) Which stakeholders influenced these girls in their decision-making process, and 3) What programs are effective in impacting their persistence in the major. Predictor variables for each respective research question are: pre-collegiate experiences, stakeholders, and programs. Outcome variables are: (a) a female undergraduate student with no involvement with MAWC programming, (b) MAWC activity participant, or (c) a MAWC participant having graduated with a bachelor?s degree in a STEM major. Results will complement published longitudinal research on the gendered and raced dimensions of computing literacy acquisition in Mississippi as well as research on effective CS role model programming.
Developing and maintaining a diverse, innovative workforce in the fields of science, technology, engineering and math (known as STEM) is critical to American competitiveness in the world, but national surveys report a current and future shortage of highly qualified STEM professionals in the US. One problem creating this shortage is that more than half of all college students who declare a major in STEM fields drop out or change their majors in the first two years of their post-secondary education. This problem is particularly acute for first generation college students. If we could increase the STEM degree completion rate by just 25%, we would make up 75% of the additional workforce needed over the next decade.
Our project aims to increase the STEM persistence of first generation college students and focuses on rural students in West Virginia. Project partners including scientists from National Labs, college faculty, local school system staff, informal educators, State Department of Education officials, and West Virginia college students will collaborate to develop summer and academic year activities that support young undergraduates majoring in STEM. Activities that we will pilot include early opportunities to do science research, academic year courses that develop science, math and communication skills, and the formation of Hometown STEM Ambassadors; undergraduate STEM students that encourage younger students back in their hometown schools. We will study the impact of these activities on students' persistence in STEM majors.
Our Project is called FIRST TWO: Improving STEM Persistence in the First Two Years of College (FIRST TWO).
Technical Details:
During the Development Launch Project, partners will create and pilot components of two courses that will confer college credit to students in two and four year schools. Each course will have as its center piece a research and development internship. By the end of the Project Development Pilot, FIRST TWO course modules will be integrated into courses the State, and be transferable between community colleges and four-year schools.
An innovative component of FIRST TWO is the creation of Hometown STEM ambassadors--students who participate in both courses will be prepared to mentor their peers, and also conduct outreach in their home school districts. They will make presentations to hometown K-12 students, and will discuss STEM college readiness issues with local education leaders. We believe reconnecting post-secondary students with their home communities and providing place-based relevance to their STEM education will have a positive impact on their persistence, as well as the added benefit of encouraging K-12 students to envision themselves as future STEM professionals.
FIRST TWO will:
- integrate early experience in STEM internships, online communities of practice and STEM skills development into a discovery-based "principles of research and development" college seminar for first year students;
- sustain engagement through a second service learning course, called STEM Leadership that will develop communication and mentoring skills and produce peer mentors who will mentor younger students, join in the efforts to change the STEM education experience at their schools, and conduct outreach in their hometown communities during the students? second year and third years.
- secure state-wide adoption and transferability of these courses, or course materials, and ultimately scale the program across the Appalachian region and to other states with large rural student populations.
- collaborate with National Labs to determine the feasibility of a National STEM Persistence Alliance partnering National Lab internship programs with 2 and 4-year schools who serve FGC students.
Finally, there are many studies that inquire into the factors that correlate with post-secondary retention in general, and with STEM attrition specifically but few that focus on rural students. FIRST TWO will fully articulate a rigorous educational research project aimed at advancing understanding of the factors affecting rural students' entry into and persistence in STEM career pathways. This research will study the impact FIRST TWO program components make on rural FGC students' persistence in STEM majors. Instruments will be developed and validated that test the components proposed in FIRST TWO interventions. As we scale the program to a larger Alliance, so will the research study scale, providing a unique opportunity to inform the education community about the rural students' experience.
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TEAM MEMBERS:
Sue HeatherlyKaren ONeilErica Harvey
Utah Valley University (UVU) with partners Weber State University (WSU) and American Indian Services (AIS) are implementing UTAH PREP (PREParation for STEM Careers) to address the need for early preparation in mathematics to strengthen and invigorate the secondary-to-postsecondary-to-career STEM pipeline. As the preliminary groundwork for UTAH PREP, each partner currently hosts a PREP program (UVU PREP, WSU PREP, and AIS PREP) that identifies low-income, under-represented minority, first-generation, and female students entering seventh grade who have interest and aptitude in math and science, and involves them in a seven-week, three-year summer intensive program integrating STEM courses and activities. The course content blends skill-building academics with engaging experiences that promote a clear understanding of how mathematical concepts and procedures are applied in various fields of science and engineering. Courses are enhanced through special projects, field trips, college campus visits, and the annual Sci-Tech EXPO. The purpose of the program is to motivate and prepare participants from diverse backgrounds to complete a rigorous program of mathematics in high school so that they can successfully pursue STEM studies and careers, which are vital to advancing the regional and national welfare.
UTAH PREP is based on the TexPREP program that originated at the University of Texas at San Antonio and which was named as one of the Bright Spots in Hispanic Education by the White House Initiative on Educational Excellence for Hispanics in 2015. TexPREP was adapted by UVU for use in Utah for non-minority serving institutions and in regions with lower minority populations, but with great academic and college participation disparity. With NSF funding for a two-year pilot program, the project partners are building UTAH PREP through a networked improvement community, collective impact approach that, if demonstrably successful, has the ability to scale to a national level. This pilot program's objectives include: 1) creating a UTAH PREP collaboration with commitments to a common set of objectives and common set of plans to achieve them; 2) strengthening existing PREP programs and initiating UTAH PREP at two or three other institutions of higher education in Utah, each building a sustainable local support network; 3) developing a shared measurement system to assess the impact of UTAH PREP programs, adaptations, and mutually reinforcing activities on students, including those from groups that are underrepresented in STEM disciplines; and 4) initiating a backbone organization that will support future scaling of the program's impact.
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TEAM MEMBERS:
Daniel HornsAndrew StoneVioleta Vasilevska