For nearly 20 years, the UAB Center for Community OutReach Development (CORD) has conducted SEPA funded research that has greatly enhanced the number of minority students entering the pipeline to college and biomedical careers, e.g., nearly all of CORD’s Summer Research Interns since 1998 (>300) have completed/are completing college and most of them are continuing on to graduate biomedical research and/or clinical training and careers. CORD’s programs that focused on high and middle school students have drawn many minority students into biomedical careers, but a low percentage of minority students benefit from these programs because far too many are already left behind academically in grades 4-6, due, at least in part, to a significant drop in science grades between grades 4 and 6, a drop from which most students never recover. A major contributor to this effect is that most grade 4-6 teachers in predominantly minority schools lack significant formal training in science and often are not fully aware of the great opportunities offered by biomedical careers.
In SEEC II, CORD will deliver intensive inquiry-based science training to grade 4-6 teachers, providing them with science content and hands-on science experiences that will afford their student both content and skills that will make them excited about, and competitive for, the advanced courses needed to move into biomedical research careers. SEEC II will also link teachers together across the elementary/middle school divide and bring the teachers together with administrators and parents, who will experience firsthand the excitement that inquiry learning brings and the significant advancement it provides in science and in reading and math. At monthly meetings and large annual celebrations, the parents, teachers and administrators will learn about the opportunities that biomedical careers can provide for the student who is well prepared. They will also consider the financial and educational steps required to ensure that students have the ability to reach these professions.
SEEC II will also expand CORD’s middle school LabWorks and Summer Science Camps to include grade 4-5 students and provide the teachers with professional learning in informal settings. During summer training, in small groups, the teachers will expand one of the inquiry-based science activities that they complete in the training, and they will use these in their classrooms and communicate with the others in their group to perfect these experiences in the school year. Finally, the teachers and grade 4-5 students will develop science and engineering fair-type research projects with which they will compete both on the school level and at the annual meeting. Thus, the students will share with their parents the excitement that science brings. The Intellectual Merit of SEEC II will be to test a model to enhance grade 4-6 teacher development and vertical alignment, providing science content, exposure to biomedical scientists and training in participatory science experiments, thus positioning teachers to succeed. The Broader Impacts will include the translation and testing of a science education model to assist minority students to avoid the middle school plunge and reach biomedical careers.
The employment demands in STEM fields grew twice as fast as employment in non-STEM fields in the last decade, making it a matter of national importance to educate the next generation about science, engineering and the scientific process. The need to educate students about STEM is particularly pronounced in low-income, rural communities where: i) students may perceive that STEM learning has little relevance to their lives; ii) there are little, if any, STEM-related resources and infrastructure available at their schools or in their immediate areas; and iii) STEM teachers, usually one per school, often teach out of their area expertise, and lack a network from which they can learn and with which they can share experiences. Through the proposed project, middle school teachers in low-income, rural communities will partner with Dartmouth faculty and graduate students and professional science educators at the Montshire Museum of Science to develop sustainable STEM curricular units for their schools. These crosscutting units will include a series of hands-on, investigative, active learning, and standards-aligned lessons based in part on engineering design principles that may be used annually for the betterment of student learning. Once developed and tested in a classroom setting in our four pilot schools, the units will be made available to other partner schools in NH and VT and finally to any school wishing to adopt them. In addition, A STEM rural educator network, through which crosscutting units may be disseminated and teachers may share and support each other, will be created to enhance the teachers’ ability to network, seek advice, share information, etc.
Biology has become a powerful and revolutionary technology, uniquely poised to transform and propel innovation in the near future. The skills, tools, and implications of using living systems to engineer innovative solutions to human health and global challenges, however, are still largely foreign and inaccessible to the general public. The life sciences need new ways of effectively engaging diverse audiences in these complex and powerful fields. Bio-Tinkering Playground will leverage a longtime partnership between the Stanford University Department of Genetics and The Tech Museum of Innovation to explore and develop one such powerful new approach.
The objective of Bio-Tinkering Playground is to create and test a groundbreaking type of museum space: a DIY community biology lab and bio-makerspace, complete with a unique repertoire of hands-on experiences. We will tackle the challenge of developing both open-ended bio-making activities and more scaffolded ones that, together, start to do for biology, biotech, and living systems what today’s makerspaces have done for engineering.
A combined Design Challenge Learning, making, and tinkering approach was chosen because of its demonstrated effectiveness at fostering confidence, creative capacity, and problem solving skills as well as engaging participants of diverse backgrounds. This educational model can potentially better keep pace with the emerging and quickly evolving landscape of biotech to better prepare young people for STEM careers and build the next generation of biotech and biomedical innovators.
Experience development will be conducted using an iterative design process that incorporates prototyping and formative evaluation to land on a final cohort of novel, highly-vetted Bio-Tinkering Playground experience. In the end, the project will generate a wealth of resources and learnings to share with the broader science education field. Thus, the impacts of our foundational work can extend well beyond the walls of The Tech as we enable other educators and public institutions around the world to replicate our model for engagement with biology.
Citizen science is a form of Public Participation in Scientific Research (PPSR) in which the participants are engaged in the scientific process to support research that results in scientifically valid data. Opportunities for participation in real and authentic scientific research have never been larger or broader than they are today. The growing popularity and refinement of PPSR efforts (such as birding and species counting studies orchestrated by the Cornell Lab of Ornithology) have created both an opportunity for science engagement and a need for more research to better implement such projects in order to maximize both benefits to and contributions from the public.
Towards this end, Shirk et al. have posted a design framework for PPSR projects that delineates distinct levels of citizen scientist participation; from the least to the highest level of participation, these categories are contract, contribute, collaborate, co-create, and colleagues. The distinctions among these levels are important to practitioners seeking to design effective citizen science programs as each increase in citizen science participation in the scientific process is hypothesized to have both benefits and obstacles. The literature on citizen science models of PPSR calls for more research on the role that this degree of participation plays in the quality of that participation and related learning outcomes (e.g., Shirk et al., 2012; Bonney et al., 2009). With an unprecedented interest in thoughtfully incorporating citizen science into health-based studies, citizen science practitioners and health researchers first need a better understanding of the role of culture in how different communities approach and perceive participation in health-related studies, the true impact of intended educational efforts from participation, and the role participation in general has on the scientific process and the science outcome.
Project goal to address critical barrier in the field: Establish best practices for use of citizen science in the content area of human health-based research, and better inform the design of future projects in PPSR, both in the Denver Museum of Nature & Science’s Genetics of Taste Lab (Lab), and importantly, in various research and educational settings across the field.
Aims
Understand who currently engages in citizen science projects in order to design strategies to overcome the barriers to participation that occur at each level of the PPSR framework, particularly among audiences underrepresented in STEM.
Significantly advance the current knowledge regarding how citizen scientists engage in, and learn from, and participate in the different levels of the PPSR framework.
Determine the impact that each stage of citizen science participation has on the scientific process.
Children Investigating Science with Parents and Afterschool (CHISPA) was a collaboration between the Phillip and Patricia Frost Museum of Science, UnidosUS (formerly National Council of La Raza), and the ASPIRA Association that took place from 2014-18. CHISPA sought to address the disparity in science achievement among Latino and non-Latino children through local-level partnerships between science museums in metropolitan areas with growing Latino populations and UnidosUS and ASPIRA affiliate organizations serving the same communities through afterschool programs.
Partners included the
The New Jersey Historical Commission (NJHC) initiated the Understanding Communities Study with the goal to better understand how New Jersey history and history organizations can be more inclusive for all. NJHC contracted RK&A for the first phase of the study to conduct focus groups with members of Hispanic and Latino communities in New Jersey. NJHC plans to expand the study to other communities in the future. The New Jersey Center for Hispanic Policy, Research and Development served as advisors in the project.
With support from NJHC partners, RK&A conducted three focus groups with
The National Building Museum (NBM) contracted RK&A to evaluate Creative-in-Residence (CIR), a program that invites visual and performing artists to NBM for short-term residencies to create original work that promotes engagement with the built environment. The study goal was to consider future implications for the CIR program based on the most recent CIR iteration (a January 2019 dance performance inviting visitors to explore NBM’s historic building) and past program iterations.
How did we approach this study?
To hear a variety of perspectives on CIR, RK&A conducted in-depth telephone
The National Building Museum contracted RK&A to conduct an evaluation Investigating Where We Live (IWWL), a long-running program that has brought together creative youth in the Washington, D.C. area every summer since 1996 to explore, document, and interpret the local built environment. The study goal was to examine program strengths and challenges to help NBM strategically plan for the program’s future.
How did we approach this study?
To hear a variety of perspectives on the program, RK&A conducted in-depth telephone interviews with a number of stakeholders with different
The purpose of the Science Center Public Forums project was to engage citizens with NOAA data about climate-related hazards, resilience strategies, and related policies. Forum modules about four climate-related hazards were created, and used as a part of forum programs at eight museums around the US. Evaluation findings are structured around three themes: 1) learning, 2) interest, engagement, and attitudes, and 3) educator outcomes. Data showed high levels of prior knowledge about environmental hazards and interactions between human and natural systems; resilience efforts; and the ways science
Informal learning institutions, such as science centers and museums, are well-positioned to broaden participation in engineering pathways by providing children from underrepresented groups with motivational, self-directed engineering design experiences. Though many informal learning institutions offer opportunities for young visitors to engage in engineering activities, little is known about the specific features of these activities that support children's motivation in engineering design processes such as problem scoping, testing, and iteration. This project will address this gap and advance foundational knowledge by identifying features of engineering design activities, as implemented within an informal setting, which support underrepresented children's engineering motivation and persistence in engineering tasks. Researchers at New York Hall of Science (NYSCI) will observe children interacting with families and museum educators as they engage in different engineering design activities in NYSCI's Design Lab, an exhibition space devoted to hands-on exploration of engineering design. They will also survey and interview the children and their caregivers about these experiences. Analyses of these data sources will result in a description of features of design activities foster motivation and task persistence in engineering design. Findings will be disseminated nationally to other informal learning institutions, which in turn can use the knowledge generated from this project to create motivational, research-based, field-tested engineering design experiences for young visitors, especially for children from underrepresented groups. The experiences may encourage children to further pursue engineering pathways, resulting in a diversified engineering workforce with the potential to drive and sustain national innovation and global technological leadership.
This project uses the framework of goal orientation, defined as learners' self-reflection of why and how they engage in tasks, to understand whether, how, and why underrepresented 7-12-year-olds engage in engineering design activities in an informal learning institution. Though previous research has suggested that goal orientation is strongly, positively related to learning and motivation in formal settings such as schools, research in informal settings has not robustly accounted for the role of goal orientation in participants' engagement with learning tasks in these unique learning environments. To better understand how children's goal orientations contribute to their motivation in engineering in informal learning institutions, researchers will answer the following research questions: (1) What are underrepresented children's goals and goal orientations while participating in engineering design activities in an informal setting? (2) What contextual factors--including facilitation strategies, materials, task relevance, and social interactions with family members--may support or discourage the adoption of different goal orientations? (3) How do goal orientations relate to children's learning experience in the engineering design activities and the likelihood that they will test and iterate their solutions? These questions will be answered through a mixed-method research study conducted with approximately 200 families, with children aged 7-12, recruited from underrepresented groups. Semi-structured clinical interviews, conducted with 20% of the children and their caregivers, as well as observations and surveys gathered from all families, will provide information on the children's goal orientation and engagement as they relate to specific engineering design activities. Qualitative content analyses and multilevel structural equation modeling will result in findings that will be disseminated widely to other institutions of informal learning. Ultimately, this project will generate new empirical knowledge regarding the features of engineering design activities in informal learning environments that increase engineering engagement and motivation among underrepresented children, thereby broadening participation in engineering pathways.
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.
American Indian and Alaska Native communities continue to disproportionately face significant environmental challenges and concerns as a predominately place-based people whose health, culture, community, and livelihood are often directly linked to the state of their local environment. With increasing threats to Native lands and traditions, there is an urgent need to promote ecological sustainability awareness and opportunities among all stakeholders within and beyond the impacted areas. This is especially true among the dozens of tribes and over 50,000 members of the Coast Salish Nations in the Pacific Northwest United States. The youth within these communities are particularly vulnerable. This Innovations in Development project endeavors to address this serious concern by implementing a multidimensional, multigenerational model aimed at intersecting traditional ecological knowledge with contemporary knowledge to promote: (a) environmental sustainability awareness, (b) increased STEM knowledge and skills across various scientific domains, and (c) STEM fields and workforce opportunities within Coast Salish communities. Building on results from a prior pilot study, the project will be grounded on eight guiding principles. These principles will be reflected in all aspects of the project including an innovative, culturally responsive toolkit, curriculum, museum exhibit and programming, workshops, and a newly established community of practice. If successful, this project could provide new insights on effective mechanisms for not only promoting STEM knowledge and skills within informal contexts among Coast Salish communities but also awareness and social change around issues of environmental sustainability in the Pacific Northwest.
Over a five-year period, the project will build upon an extant curriculum and findings codified in a pilot study. Each aspect of the pilot work will be refined to ensure that the model established in this Innovations and Development project is coherent, comprehensive, and replicable. Workshops and internships will prepare up to 200 Coast Salish Nation informal community educators to implement the model within their communities. Over 2,500 Coast Salish Nation and Swinomish youth, adults, educators, and elders are expected to be directly impacted by the workshops, internships, curriculum and online toolkit. Another 300 learners of diverse ages are expected to benefit from portable teaching collections developed by the project. Through a partnership with the Washington State Burke Natural History Museum, an exhibit and museum programming based on the model will be developed and accessible in the Museum, potentially reaching another 35,000 people each year. The project evaluation will assess the extent to which the following expected outcomes are achieved: (a) increased awareness and understanding of Indigenous environmental sustainability challenges; (b) increased skills in developing and implementing education programs through an Indigenous lens; (c) increased interest in and awareness of the environmental sciences and other STEM disciplines and fields; and (d) sustainable relationships among the Coast Salish Nations. A process evaluation will be conducted to formatively monitor and assess the work. A cross cultural team, including a recognized Coast Salish Indigenous evaluator, will lead the summative evaluation. The project team is experienced and led by representatives from the Swinomish Indian Tribal Community, Oregon State University, Garden Raised Bounty, the Center for Lifelong STEM Learning, the Urban Indian Research Institute, Feed Seven Generations, and the Burke Museum of Natural History and Culture.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.
Research on how museum staff are trained continues to emerge. Training varies considerably across institutions and typically includes observations, shadowing, and trial and error. While museum educators put high value on increasing visitor-centered participatory experiences, engagement based on acquisition-based theories of learning is still common among floor staff, even after training. Facilitating learning about science, technology, engineering, and mathematics (STEM) topics in ways that support visitors in constructing their own understanding is difficult, especially since floor staff/facilitators may be working simultaneously with children and adults of a range of ages, backgrounds, and goals. This project will advance understanding of how to facilitate open-ended learning experiences in ways that engage visitors in practices that align with the STEM disciplines. The project will result in an evidence-based facilitation framework and training modules for training informal science educators. The work is grounded in constructivist theories of learning and identity work and focuses on visitors constructing understanding of STEM topics through active engagement in the practices of STEM. This model also results in learning experiences in informal settings that are mutually reinforcing with the goals of schools. This research is being conducted through an established researcher-practitioner partnership between MOXI, the Wolf Museum of Exploration + Innovation and the University of California at Santa Barbara (UCSB).
The two primary goals of the work are to (1) enable visitors to better engage in STEM practices (practice-based learning) and (2) investigate the role of training in helping facilitators develop the practice-based facilitation strategies needed to support visitors' learning. STEM content in this study is physical science. Prior work resulted in two tools that constitute part of a facilitation framework (a practices-by-engagement matrix and three facilitation pathways) which help educators identify appropriate goals based on how the visitor is engaging with exhibits. The development of the final tool in the framework, facilitation strategies, and the refinement of the first two tools will be done using a design-based implementation research (DBIR) approach. Data collection and analysis will be directed and completed by research-practitioner teams of UCSB graduate students (researchers) and MOXI educators (practitioners); MOXI educators will be both participants and researchers. Data collection activities include: video data using point-of-view cameras worn by visitors and educators; interviews of educators and visitors; observations of the training program; and educator reflections. In the final year, a small field test will be done at six sites, representing different types of museums. Interviews and reflections comprise the data collection at the field sites.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.