This research project builds upon an Advancing Informal STEM Learning (AISL) project (DRL#1114674) that investigated preschoolers' self-directed science, technology, engineering, and mathematics (STEM) related play experiences in outdoor nature-based playscapes. An emerging trend, nature-based playscapes have great potential for exposing young children to STEM-related phenomena, concepts, and processes in a variety of early childhood education settings, including daycare centers, pre-schools, playgrounds, and children's museums. In contrast to traditional playgrounds, playscapes are designed to result in complex, sensory-rich environments in which extensive access to natural materials and resources inspires young children's investigative and exploratory behaviors. This study explores the hypothesis that play in nature provides young children (ages 3-5) with extensive contact with science content and that a play-based curriculum could expand opportunities for STEM learning. This Research-in-Service of Practice project will: 1) design, implement, and evaluate four digital play-based professional development curriculum modules for pre-school educators across multiple partner sites; 2) research the impact of professional training on educators' facilitation of STEM content and activities; 3) examine the impacts of play-based facilitation on young children's understanding of and engagement with STEM; and 4) evaluate the transferability and sustainability of new playscape design principles at three partner sites. This investigation will be led by researchers at the University of Cincinnati in close collaboration with early childhood educators at the Arlitt Center, Cincinnati Nature Center, and two local early childhood organizations that serve children in Head Start programs. The study will use a mixed-methods approach. Data sources include video observations, behavior mapping, teacher self-studies, surveys, interviews, child assessments and children's photo documentation of their experiences. This research project is being funded by the AISL program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. Research that promotes the understanding of how designed play-based natural environments and related instructional approaches support the development of young children's engagement with STEM could lead to new learning theory, pedagogical approaches, and inform the design of effective informal learning experiences. Understanding the affordances of particular components of playscapes with respect to young children, as well as how pre-school educators could productively facilitate young children's engagement with, and understanding of, STEM would be a contribution to the informal STEM field.
Situated within the Advancing Informal STEM Learning program, this Research in Service to Practice award seeks to design, implement, and evaluate an intervention aimed at fostering a culture of productive failure practices. The project responds to a broad concern in educational research and practice: Experiences of failure are frequently so negative that students shut down, lose agency, and develop low self-efficacy and learned helplessness. Surrendering too quickly to obstacles is particularly unfortunate, given evidence that initially "getting it wrong" ultimately breeds deep and sustained learning. In order to learn how students can make the most of productive failure, the proposed project will study how a community of practice that includes middle school youth and their mentors attempts to change its handling of learning obstacles. Building on prior research documenting storytelling practices in an afterschool program, the team now aims to embolden young students' productive practices of failure storytelling in computer science, a field in which experts practice candid, pervasive, and collaborative discourse around errors ("bugs"). Pulling together the domains of narrative analysis, meta-cognitive reflection, and control theories of motivation, within the context of authentic computer-science debugging activity, this study develops a theoretical framework that views productive responses to failure as a discipline-specific process of reflecting as a community on how to locate obstacles, how to construct causal theories about why those obstacles emerged, and how to plan productive responses. A design-based research approach will investigate three questions: (1) What is the impact of the interventions on students and instructors' actions and discourse when they are debugging errors in computer code? (2) What is the impact of the interventions on students and instructors' reflections back on their prior debugging experiences and on failure in general? and (3) What is the impact of the instructor-development efforts on the instructors' capacity to foster students' productive attitudes toward failure? The study focus will be 15 summer and weekend coding workshops with 5th-8th grade students from populations typically under-represented in STEM. The interventions are (a) setting new norms and practices for debugging, (b) instructor education, and (c) coding software that provides students with feedback on their productive struggle. Data sources include video and audio recordings of the learning environment, artifacts produced during the activities, and semi-structured interviews. Measures will capture variations in debugging activities, reflections on debugging, students' ideas about grit and growth mindset, and instructors' struggles and successes with the new curriculum. The empirical results will consist of mixed-methods, micro-longitudinal accounts of how a community of practice works to reform its orientation to failure. The products of this work include empirical knowledge, theory, and curriculum about how learning communities help students develop robust and efficient responses to failure. These will be disseminated through journals, open-source software, and workshops/conferences for researchers and practitioners working with youth afterschool programs. The products may be useful for exploring practices in the classroom. This project is being conducted by the 9 Dots Community Learning Center, UCLA and UC Berkeley.
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TEAM MEMBERS:
Melissa ChenDor AbrahamsonNoel EnyedyFrancis SteenDavid DeLiema
resourceprojectProfessional Development, Conferences, and Networks
The purpose of this proposal is to convene scholars at a two-day conference to closely examine validity-related measurement issues, create a guidelines for the field of mathematics education research that addresses key ideas (e.g., validity, validity arguments, evidence for validity and measurement at-scale), and set a clear pathway for scholars to discuss quantitative measurement within mathematics education. Invitees will include a mix of young, older and diverse scholars in mathematics education research. Products include refereed journal articles along with a website.
The workshop will engage the Mathematics Education, Policy, Statistical, Psychometrics and other education research communities in examining and critiquing measurement validity evidence of mathematics education research with the long-term goal of increasing the quality of quantitative inference in mathematics education research (to include improvements in the training of doctoral students).
DATE:
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TEAM MEMBERS:
Jonathan BosticMichele Carney
resourceprojectProfessional Development, Conferences, and Networks
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds efforts that seek 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 achieve these aims by identifying and closely evaluating critical factors and processes that are necessary to effectively broaden access and sustain professional learning (PL) for educational professionals working within informal STEM learning (ISL) settings. The context for this work builds on an evidence-based and nationally field tested professional learning model, Reflecting on Practice (RoP). This model will be refined to provide ISL educators with increased access to a proven PL curriculum via an in-person or blended approach, enhanced localized support, and cultivated regional professional learning communities. There is still little known about the effectiveness of blended PL within informal contexts. The emphasis on greater accessibility to PL is particularly important to the ISL field, given the significant number of informal STEM educators and institutions in underserved and remote locations, often facing disparate and insurmountable challenges in access to high quality STEM professional development. This modular program will not only target a broad range of informal institutions; varying in size, STEM content foci, geographic location and communities served but it is also uniquely designed for institutional customization and adoption, further increasing the likelihood of wide-spread uptake, participation, and engagement. If successful, this broad implementation effort will directly impact over 3,000 informal science educators and professionals in nearly 350 informal STEM learning institutions across the country. The intended theory of action and iterative, design-based implementation approach will be closely monitored, documented and analyzed by an experienced team of external evaluators, using formative and summative evaluative methods. A mixed methods approach will be employed to: (a) examine the effectiveness and accessibility of blended PL and regional PLCs for the ISL field, (b) identify critical design features in blended PL and regional PLCs for impacting educators' practice, (c) determine how PLCs can develop and continue in ISL through looking at what system of support is needed, and (d) ascertain the effective role of the Leaders and Leadership Sites. Data will be collected at all levels - from the RoP directors and PIs, document reviews, interviews and observations with RoP leaders at the six partnering institutions, and surveys with the RoP facilitators (n=700) and informal STEM educator participants (n=2,000). The results of the findings could be instrumental in the development of future frameworks and models designed to broadly disseminate similar professional learning models effectively within ISL contexts.
This project is funded by the Advancing Informal STEM Learning program, which seeks to advance new approaches to, and evidence-based understandings of, the design and development of Science, Technology, Engineering, and Mathematics (STEM) learning in informal environments. Roughly one million refugees resettled in the United States in the past decade, many of whom are school-aged youth. During secondary school, resettled refugee youth are often still developing English language literacy and STEM skills needed for successful postsecondary experiences in the United States. At the same time, these youth bring rich cultural and linguistic resources that they can use as an asset as they grow their STEM skill sets, prepare for future success, and make positive impacts on U.S. society. To promote these assets and engage youth in developing STEM literacy, this after-school program engages these youth in critical STEM literacy development. The project focuses on STEM learning, specifically the relationship between human life and climate, as well as developing youths' STEM identities and agency.
The project will develop and implement a community-based afterschool program that provides resettled Burmese refugee youth with STEM learning experiences. By drawing upon youths' experiences, the program will engage youth in learning about climate science and developing digital stories to communicate with broader audiences. To do so, the team will implement a program that builds on principles of responsive teaching, funds of knowledge, and English literacy development in authentic meaning-making contexts. The project will examine how youth expand their STEM knowledge, develop STEM identities and agency, and develop their expertise in communicating about STEM within and beyond their participation in the after-school program. The research team will explore existing and innovative data collection and analysis methods by drawing on principles of ethnography, video ethnography, mediated discourse analysis, and phenomenological and ethnomethodological analysis of interviews. These analyses will document learning over time in informal STEM learning settings. As there is very little prior research on STEM learning in this population, this project will generate knowledge about how to support STEM sense-making and critical STEM literacy. Furthermore, by testing the designed curriculum and building a partnership with a local community organization, the project will build capacity for broadening participation in informal STEM learning practices.
This project had three objectives to build knowledge with respect to advancing Informal STEM Education:
Plan, prototype, fabricate, and document a game-linked design-and-play STEM exhibit for multi-generational adult-child interaction utilizing an iterative exhibit design approach based on research and best practices in the field;
Develop and disseminate resources and models for collaborative play-based exhibits to the informal STEM learning community of practice of small and mid-size museums including an interactive, tangible tabletop design-and-play game and a related tablet-based game app for skateboarding science and technology design practice;
Conduct research on linkages between adult-child interactions and game-connected play with models in informal STEM learning environments.
Linked to these objectives were three project goals:
Develop tools to enable children ages 5-8 to collaboratively refine and test their own theories about motion by exploring fundamental science concepts in linked game and physical-object design challenge which integrates science (Newton’s Laws of Motion) with engineering (iterative design and testing), technology (computational models), and mathematics (predictions and comparisons of speed, distance, and height). [Linked to Objectives 1 & 3]
Advance the informal STEM education field’s understanding of design frameworks that integrate game environments and physical exhibit elements using tangibles and playful computational modeling and build upon the “Dimensions of Success” established STEM evaluation models. [Linked to Objectives 1 & 2]
Examine methods to strengthen collaborative learning within diverse families through opportunities to engage in STEM problem-based inquiry and examine how advance training for parents influences the extent of STEM content in conversations and the quality of interactions between caregivers and children in the museum setting. [Linked to Objectives 1 & 3]
The exhibit designed and created as a result of this grant project integrates skateboarding and STEM in an engaging context for youth ages 5 to 8 to learn about Newton’s Laws of Motion and connect traditionally underserved youth from rural and minority areas through comprehensive outreach. The exhibit design process drew upon research in the learning sciences and game design, science inquiry and exhibit design, and child development scholarship on engagement and interaction in adult-child dyads.
Overall, the project "Understanding Physics through Collaborative Design and Play: Integrating Skateboarding with STEM in a Digital and Physical Game-Based Children’s Museum Exhibit" accomplished three primary goals. First, we planned, prototyped, fabricated, and evaluated a game-linked design-and-play STEM gallery presented as a skatepark with related exhibits for adult-child interaction in a Children's Museum.
Second, we engaged in a range of community outreach and engagement activities for children traditionally underserved in Museums. We developed and disseminated resources for children to learn about the physics of the skatepark exhibit without visiting the Museum physically. For example, balance board activities were made portable, the skatepark video game was produced in app and web access formats, and ramps were created from block sets brought to off-site locations.
Third, we conducted a range of research to better understand adult-child interactions in the skatepark exhibit in the Children's Museum and to explore learning of physics concepts during physical and digital play. Our research findings collectively provide a new model for Children's Museum exhibit developers and the informal STEM education community to intentionally design, evaluate, and revise exhibit set-up, materials, and outcomes using a tool called "Dimensions of Success (DOS) for Children's Museum Exhibits." Research also produced a tool for monitoring the movement of children and families in Museum exhibit space, including time on task with exhibits, group constellation, transition time, and time in gallery. Several studies about adult-child interactions during digital STEM and traditional pretend play in the Museum produced findings about social positioning, interaction style, role, and affect during play.
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TEAM MEMBERS:
Deb DunkhaseKristen MissallBenjamin DeVane
As part of an overall strategy to enhance learning within maker contexts in formal and informal environments, the Innovative Technology Experiences for Students and Teachers (ITEST) and Advancing Informal STEM Learning (AISL) programs partnered to support innovative models for making in a variety of settings through the Enabling the Future of Making to Catalyze New Approaches in STEM Learning and Innovation Dear Colleague Letter. This Early Concept Grant for Exploratory Research (EAGER) will test an innovative approach to bringing making from primarily informal out-of-school contexts into formal science classrooms. While the literature base to support the positive outcomes and impacts of design-based making in informal settings at the K-12 level is emerging, to date, minimal studies have investigated the impacts of making design principles within formal contexts. If successful, this project would not only add to this gap in the literature base but would also present a novel model for bridging the successful engineering design practices of making and tinkering primarily found in informal science education into formal science education classrooms. The model would also demonstrate an innovative, highly interactive way to engage high school students and their teachers in engineering based design principles with immediate real-world applications, as the scientific instruments developed in this project could be integrated directly into science classrooms at relatively minimal costs.
Through a multi-phased design and implementation model, high school students and their teachers will engage deeply in making design principles through the design and development of their own scientific instruments using Arduino-compatible hardware and software. The first phase of the project will reflect a more traditional making experience with up to twenty high school students and their teachers participating in an after-school design making club, in this case, focused on the development and testing of scientific instrument prototypes. During the second phase of the project, the first effort to transpose the after school making experience to a more formalized experience will be tested with up to eight students selected to participate in two week summer research internships focused on scientific instrument design and development through making at Northwestern University. A two-day summer teacher workshop will also be held for high school teachers participating in the subsequent pilot study. The collective insights gleaned from the after school program, student internships, and teacher workshop will culminate to inform the full implementation of the formal classroom pilot study. The third and final phase will coalesce months of iterative, formative research, design and development, resulting in a comprehensive pilot investigation in up to seven high school physics classrooms.
Using a multi-phased, mixed methods exploratory design-based research approach, this 18-month EAGER will explore several salient research questions: (a) How and to what extent does the design & making of scientific instrumentation serve as useful tasks for learning important science and engineering knowledge, practices, and epistemologies? (b) How engaging is this making activity to learners of diverse abilities and prior interests? What can be generalized to other types of making activities? (c) How accessible is the Arduino hardware and coding environment to learners? What combination of hardware and software materials and tools best support accessibility and learning in this type of digital making activity? and (d) What types of scaffolding (for students and teachers) are required to support the effective use of maker materials and activities in a classroom setting? Structured interviews, artifacts, video recordings from visor cameras, student design logs, logfiles, and ethnographic field notes will be employed to garner data and address the research questions. Given the early stage of the proposed research, the dissemination of the findings will be limited to a few select journals, teacher forums and workshops, and professional conferences.
This EAGER is well-poised to directly impact up to 125 high school physics students (average= 25 students/class), approximately 7 high school physics teachers, 6-8 high school summer interns, nearly 20 high school students participating in the after-school design making club, and indirectly many more. The results of this EAGER could provide the basis and evidence needed to support a more robust, expanded future investigation to further substantiate the findings and build the case for similar efforts to bring making into formal science education contexts.
As part of an overall strategy to enhance learning within maker contexts in formal and informal environments, the Innovative Technology Experiences for Students and Teachers (ITEST) and Advancing Informal STEM Learning (AISL) programs partnered to support innovative models in Making poised to catalyze new approaches in STEM learning and innovation. Employing a novel design and development approach, this Early Concept Grant for Exploratory Research (EAGER) will test the feasibility of integrating Making concepts with real world micro-manufacturing engineering principles within the context of intense, multi-year team apprenticeship experiences for high school students. The apprenticeship model is particularly novel, as current Making research and experiences predominately take place in afterschool and summer programs for up to 25 youth. The proposed apprenticeships will require a two year commitment by a small cohort of Texas high school students, which will provide an opportunity to examine the feasibility and impact of the effort longitudinally. The cohort will learn to think critically, solve problems, and work together as a Making Production Team (MPT) in a customized makerspace in their high school, constructing engineering-based science kits for implementation in a local elementary school. Not only will the students enhance their content knowledge while developing design and development skills but the students will also receive stipends which will address two very practical needs for the targeted high need population - employment and workforce development. Few, if any, efforts currently serve the targeted population through the contextualization of Making within a supply chain management and micro-manufacturing framework that extends the Making experience by integrating the student designed products into elementary classrooms. As such, this project will contribute to essentially unexplored areas of Making research and development.
Six high school students from high poverty, underserved Texas communities along the Texas-Mexico border (colonias) will be selected for the Making Production Team (MPT). In Years 1 and 2, the students will meet regularly during the academic school year and over the summer with Texas A & M University undergraduates, graduate students, and the project team to learn key aspects of Making and manufacturing (i.e., ideation, prototyping, design, acquisition, personnel, and production) through hands-on making activities and direct instruction. Concurrently, a research study will be conducted to explore: (a) the actualization of the model in an underserved community, (b) the effectiveness of problem-based learning to train students in the model, and (c) STEM knowledge and self-concept. Data will be collected from multiple sources. An adapted version of the Academic Self-Description Questionnaire will be administered to the students to assess their STEM technical knowledge and skills as well as their self-concept in relation to STEM domains. Remote and in person interviews will be conducted with the students to track the evolution of the primary dependent variables, STEM learning and self-concept, over time. Program facilitators and partners will be interviewed to examine the feasibility of the making experience within the given context and for the targeted students. Finally, the students' diary reflections, products, and video recordings of their work sessions will also be examined. Time-series quantitative tests and in-depth qualitative methods will be used to analyze the data.
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TEAM MEMBERS:
Francis QuekSharon Lynn ChuMalini NatarajarathinamMathew Kuttolamadom
resourceprojectProfessional Development, Conferences, and Networks
The Center for Advancement of Informal Science Education (CAISE) is a National Science Foundation (NSF) funded resource center, working in cooperation with the NSF Advancing Informal STEM Learning (AISL) program to build and advance the informal STEM education field. CAISE continues the work it began in 2007--serving professional audiences in informal STEM learning, which includes those working in science centers and museums, zoos and aquariums, parks, botanical gardens and nature centers, events and festivals, libraries, making and tinkering spaces, media (TV, radio, film, social), cyberlearning and gaming, and youth, community, and out-of-school time programs.
What We Do:
CAISE seeks to characterize, highlight, and connect quality, evidence-based informal STEM learning work supported by a diversity of federal, local, and private funders by providing access to over 8,000 (and growing) resources that include project descriptions, research literature, evaluation reports and other documentation on the InformalScience.org website. In addition, CAISE convenes inquiry groups, workshops and principal investigator meetings designed to facilitate discussion and identify the needs and opportunities for informal STEM learning.
In this award, CAISE is also tasked with advancing and better integrating the professional fields of informal STEM learning and science communication by (1) broadening participation in these fields, (2) deepening links between research and practice, and (3) building capacity in evaluation and measurement. These activities are being undertaken by cross-sector task forces of established and emerging who will be responsible for conducting field-level analyses, engaging stakeholders, and creating roadmaps for future efforts. CAISE is also building on existing communication channels for dissemination to the larger field, and through the InformalScience.org website. An External Review Board and Inverness Research are providing oversight of CAISE's program activities and evaluation of the center.
Who We Are:
CAISE operates as a network of core staff housed at the Association of Science-Technology Centers (ASTC) in Washington, D.C. and co-principal investigators and other collaborators at academic institutions and informal STEM education (ISE) organizations across the U.S. Other key collaborators are the American Association for the Advancement of Science's Center for Public Engagement with Science, the National Informal STEM Education Network, and Arizona State University.
Nurture Nature Center recently completed a 2 year project to develop a 6 Degrees of Connection educational program, supported by a grant from NASA’s CP4SMP. The program focuses on earth science concepts and the cross-cutting theme of interconnectedness, using personal relevance as a hook to capture students’ interest and motivate them to pursue STEM experiences and careers.
Over the course of two years, students, interns, and teachers were engaged to help develop a SOS program with an associated arts-based creative activity. An iterative program design process based on student and teacher evaluations resulted in the 6 Degrees of Connectionprogram which discusses earth systems connections involving the sun, space weather, and ozone; transportation, atmosphere and acid rain; climate change; and marine debris. The program is purposefully interactive and multi-disciplinary - students are encouraged to consider the cascading effects related to the production and transportation of their clothing during an interactive activity using the SOS, an arts-based activity after the SOS program helps participants visualize and physically diagram their connections to global issues, and students learn about STEM careers from clips of STEM professionals discussing the ways their work is tied to various human and earth systems.
We are pleased to share more about the project, the evaluation, and program materials on our website here http://nurturenaturecenter.org/6-degrees-of-connection-understanding-the-interconnectedness-of-earth-systems/.
People of color who live in low income, urban communities experience lower levels of educational attainment than whites and continue to be underrepresented in science at all educational and professional levels. It is widely accepted that this underrepresentation in science is related, not only to processes of historical exclusion and racism, but to how science is commonly taught and that investigating authentic, relevant science questions can improve engagement and learning of underrepresented students. Approaching science in these ways, however, requires new teaching practices, including ways of relating cross-culturally. In addition to inequity in science and broader educational outcomes, people of color from low income, urban communities experience high rates of certain health problems that can be directly or indirectly linked to mosquitoes. Recognizing that undertaking public health research and preventative outreach efforts in these communities is challenging, there is a critical need for an innovative approach that leverages local youth resources for epidemiological inquiry and education. Such an approach would motivate the pursuit of science among historically-excluded youth while, additionally, involving pre-service, in-service, and informal educators in joint participatory inquiry structured around opportunities to learn and practice authentic, ambitious science teaching and learning.
Our long-term goal is to interrupt the reproduction of educational and health disparities in a low-income, urban context and to support historically-excluded youth in their trajectories toward science. This will be accomplished through the overall objective of this project to promote authentic science, ambitious teaching, and an orientation to science pursuits among elementary students participating in a university-school-community partnership promise program, through inquiry focused on mosquitoes and human health. The following specific aims will be pursued in support of the objective:
1. Historically-excluded youth will develop authentic science knowledge, skills, and dispositions, as well as curiosity, interest, and positive identification with science, and motivation for continued science study by participating in a scientific community and engaging in the activities and discourses of the discipline. Teams of students and educators will engage in community-based participatory research aimed at assessing and responding to health and well-being issues that are linked to mosquitoes in urban, low-income communities. In addition, the study of mosquitoes will engage student curiosity and interest, enhance their positive identification with science, and motivate their continued study.
2. Informal and formal science educators will demonstrate competence in authentic and ambitious science teaching and model an affirming orientation toward cultural diversity in science. Pre-service, in-service, and informal educators will participate in courses and summer institutes where they will be exposed to ambitious teaching practices and gain proficiency, through reflective processes such as video study, in adapting traditional science curricula to authentic science goals that meet the needs of historically excluded youth.
3. Residents in the community will display more accurate understandings and transformed practices with respect to mosquitoes in the urban ecosystem in service of enhanced health and well-being. Residents will learn from an array of youth-produced, culturally responsive educational materials that will be part of an ongoing outreach and prevention campaign to raise community awareness of the interplay between humans and mosquitoes.
These outcomes are expected to have an important positive impact because they have potential for improving both immediate and long-term educational and health outcomes of youth and other residents in a low-income, urban community.
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TEAM MEMBERS:
Katherine Richardson BrunaLyric Colleen Bartholomay
Science Club Summer Camp (SC2) is a practicum-based teacher professional development program for elementary school teachers, aligned to the recently released Next Generation Science Standards (NGSS). It seeks to address well-described gaps in the scientific training of elementary teachers that threaten the effective implementation of NGSS and interrupt development of early youth science skills. We offer that the best way to prepare a future STEM and biomedical workforce is to help improve NGSS-aligned instruction at the K-5 level.
SC2 uses an integrated approach to train Chicago Public School teachers and youth in the nature of science. An interdisciplinary team of scientists, master science teachers, NGSS experts, and youth development staff will collaborate to incorporate the NGSS Disciplinary Core Ideas (DCIs), Crosscutting Concepts, and science and engineering practices into both out-of-school time learning at a summer camp and academic year instruction. Program participants will also learn about NGSS connections to health and biomedicine through interactions with practicing scientists, visits to research labs, and inquiry into health phenomena.
Over the course of the program, we will train 64 teachers and more than 2000 youth in authentic science and health practices. A multi-faceted evaluation plan will assess the impact of our program on teacher beliefs, knowledge, and understanding of the NGSS, and the degree to which their training results in changes to their instructional practice. Additionally, we will help teachers design critical NGSS-aligned assessment tools as measures of student learning. These instruments will provide early evidence on the connections between NGSS-aligned instruction and deeper student learning.
In addition to addressing the acute need for NGSS-aligned teacher professional development strategies, and high quality summer learning opportunities for disadvantages youth, it is our expectation that this “dual use” approach will serve as a model for future teacher professional development programs that seek to bridge learning in formal and informal environments and strengthen academic-community partnerships.