Brokering Youth Pathways was created to share tools and techniques around the youth development practice of “brokering” or connecting youth to future learning opportunities and resources.
This toolkit shares ways in which various out-of-school educators and professionals have approached the challenge of brokering. It provides a framework, practice briefs and reports that focus on a particular issue or challenge and provide concrete examples, as well as illustrate how project partners partners worked through designing new brokering routines in partnership with a research team.
This project will develop culturally responsive making and makerspaces with Indigenous communities in Arizona and Utah. The investigators will work in and with these communities to design maker activities utilizing technologies that complement existing cultural practices where the communities are located. This will be done by addressing the following research questions: 1) How does the design of a community makerspace located at a community college on tribal lands differ from the design of a mobile makerspace that travels between tribal communities? What are the affordances and constraints of each model?; 2) How do high-low tech making activities implemented in these two distinct makerspaces support culturally responsive making and STEM learning in American Indian communities?; and 3) How do these new makerspaces and activities impact youth, teacher, and community conceptions of and interest in STEM learning?
By leveraging heritage craft practices, Indigenous technologies, and a mixture of high-low tech tools and materials, this project will expand the range of available maker activities and broaden our definitions of making to encompass craft practices and Indigenous technologies, which are often excluded from the maker literature and makerspaces. Through the design and development of local and mobile makerspace models serving American Indian communities, knowledge of how to design makerspaces that meet community needs and foster STEM learning will be generated. In terms of broader impact, the project will diversify making activities and makerspaces in ways that allow broadened participation in making for underserved American Indian communities. A key project goal is to critically explore making as a democratizing practice that can broaden Indigenous communities' access to and participation in STEM learning. This project is a part of NSF's Maker Dear Colleague Letter (DCL) portfolio (NSF 15-086), a collaborative investment of Directorates for Computer & Information Science & Engineering (CISE), Education and Human Resources (EHR) and Engineering (ENG).
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TEAM MEMBERS:
Bryan BrayboyYasmin KafaiKristin SearleBreanne Litts
This project will make synthetic biology activities accessible to high school students and teachers by providing them with an authentic but safe context to learn. These activities will also broaden their understanding and perspectives about how synthetic biology and bioengineering is used in personal, health, and food production contexts as well as raise their interest in STEM. The design of bioMAKERlab will generate an educational version of an existing professional-grade lab for synthetic biology to promote safe production, accessibility, and affordability for high schools and community colleges interested in integrating such wetlab activities into their curriculum.
Most current efforts to broaden access to maker activities for K-12 students have focused on developing collaborative fabrication workspaces (fablabs) involving 3D printers, laser cutters, and other digital and traditional tools. This project will develop and implement bioMAKERlab, an innovative wetlab starter kit and activities that will enable high school students and teachers to engage in synthetic biology by building genetic circuits that let microorganisms change color, smell, and shape. In synthetic biology, participants make their own DNA--gene by gene--and then grow their designs into real applications by inserting them into microorganisms to develop different traits and characteristics provided by the genes. The project will involve students from a Philadelphia public high school and young people participating in weekend workshops at The Franklin Institute, a Philadelphia-based science museum.
This project is a part of NSF's Maker Dear Colleague Letter portfolio (NSF 15-086), a collaborative investment of Directorates for Computer & Information Science & Engineering, Education and Human Resources, and Engineering.
While the term 'failure' brings to mind negative associations, there is a current focus on failure as a driver of innovation and development in many professional fields. It is also emerging from prior research that for STEM professionals and educators, failure plays an important role in designing and making to increase learning, persistence and other noncognitive skills such as self-efficacy and independence. By investigating how youth and educators attend to moments of failure, how they interpret what this means, and how they respond, we will be better able to understand the dynamics of each part of the experience. The research team will be working with youth from urban, suburban and rural settings, students from Title I schools or who qualify for free/reduced-price lunches, those from racial and ethnic minority groups, as well as students who are learning English as a second language. These youth are from groups traditionally underrepresented in STEM and in making, and research indicates they are more likely to experience negative outcomes when they experience failure.
The intellectual merit of this project centers on establishing a baseline understanding of how failure in making is triggered and experienced by youth, what role educators play in the process, and what can be done to increase persistence and learning, rather than failure being an end-state. The research team will investigate these issues through the use of qualitative and quantitative research methods. In particular, the team will design and evaluate the effectiveness of interventions on increasing the abilities of youth and educators in noticing and responding to failures and increasing positive (e.g., resilience) outcomes. Research sites are selected because they will allow collection of data on youth from a wide range of backgrounds. The research team will also work to test and revise their hypothesized model of the influence of factors on persistence through failures in making. This project is a part of NSF's Maker Dear Colleague Letter (DCL) portfolio (NSF 15-086), a collaborative investment of Directorates for Computer & Information Science & Engineering (CISE), Education and Human Resources (EHR) and Engineering (ENG).
This Research in Service to Practice project, a collaboration of Pepperdine University and the New York Hall of Science, will establish a network of STEM-related Media Making Clubs comprised of after-school students aged 12 - 19 and teachers in the U.S. and in three other countries: Kenya, Namibia and Finland. The media produced by the students may include a range of formats such as videos, short subject films, games, computer programs and specialized applications like interactive books. The content of the media produced by the students will focus on the illustration and teaching of STEM topics, where the shared media is intended to help other students become enthused about and learn the science. This proposal builds on the principal investigator's previous work on localized media clubs by now creating an international network in which after-school students and teachers will collaborate at a distance with other clubs. The central research questions for the project pertain to three themes at the intersection of learning, culture and collaboration: the impact of participatory teaching, virtual networks, and intercultural, global competence. The research will combine qualitative, cross-cultural and big data methods. Critical to the innovation of the project, the research team will also develop a network assessment tool, adapting epistemic network analysis methods to the needs of this initiative. This work is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments.
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TEAM MEMBERS:
Eric HamiltonKatherine McMillanPriya Mohabir
This project by California State University San Marcos and their collaborators will expand and continue to innovate on a pilot Mobile Making program with the goal of developing a sustainable, regional model for serving underserved, middle-school aged youth in twelve after-school programs in the San Diego region. Evaluation of the current Mobile Making program has documented positive impacts on participants' interest, self-efficacy, and perception of the relevance of Making/STEM in everyday life, and led to a model for engaging underserved youth in Making. The work will focus on implementing the program model sustainably at greater capacity by increasing the number of undergraduate activity leaders, after-school sites, and level of community engagement. The expanded Mobile Making program is expected to engage ~1800 middle school youth at 12 local school sites, with activities facilitated by ~1020 undergraduate CSU-SM STEM majors. The sites are in ethnically diverse and economically disadvantaged neighborhoods, with as many as 90% of students at some sites qualifying for free or reduced price lunch. The undergraduate facilitators are drawn from CSU-SM's diverse student body, which includes 44% underrepresented minorities. Outcomes are expected to include increases in the youth participants' interest, self-efficacy, and perception of the relevance of Making/STEM in everyday life. Positive impacts on the undergraduate facilitators will include broadened technical skills, increased leadership and 21st century skills, and increased lifelong interest in STEM outreach/informal science education. The program is designed to achieve sustainability through innovative means such as involving undergraduate facilitators via Community Service Learning (rather than paid positions), and increased community engagement via development and support of a community of practice including local after-school providers, teachers, Makers, and University members. Evaluation of the program outcomes and lessons learned are expected to result in a comprehensive model for a sustainable, university-based after-school Making program with regional impact in underserved communities. Dissemination to other regions will be leveraged via CSU-SM's membership in the California State University (CSU) system, yielding a potential statewide impact. The support of the CSU Chancellor's Office and input from a CSU implementation group will ensure the applicability of the model to other regional university settings, identify common structural barriers and solutions, and increase the probability of secondary implementations. This work is funded by the Advancing Informal STEM Learning (AISL) program, which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments.
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
Nationally, there is tremendous interest in enhancing participation in science, technology, engineering, and mathematics (STEM). Providing rich opportunities for engagement in science and engineering practices may be key to developing a much larger cadre of young people who grow up interested in and pursue future STEM education and career options. One particularly powerful way to engage children in such exploration and playful experimentation may be through learning experiences that call for tinkering with real objects and tools to make and remake things. Tinkering is an important target for research and educational practice for at least two reasons: (1) tinkering experiences are frequently social, involving children interacting with educators and family members who can support STEM-relevant tinkering in various ways and (2) tinkering is more open-ended than many other kinds of building experiences (e.g., puzzles, making a model airplane), because it is the participants' own unique questions and objectives that guide the activity. Thus, tinkering provides a highly accessible point of entry into early STEM learning for children and families who do not all share the same backgrounds, circumstances, interests, and expertise. This Research-in-Service to Practice project is funded by the Advancing Informal STEM Learning (AISL) program which seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. The project will take place in the Tinkering Lab exhibit at Chicago Children's Museum. The research will investigate how reflective interactions between parents and children (ages 6-8) during tinkering activities ultimately impact child engagement in STEM. Design-based research (DBR) is well-suited to the iterative and contextually-rich process of tinkering. Using a DBR approach, researchers and museum facilitators will be trained to prompt variations of simple reflection strategies at different time points between family members as a way to strengthen children's engagement with, and memory of these shared tinkering events. Through progressive refinement, each cycle of testing will lead to new hypotheses that can be tested in the subsequent round of observations. The operationalization of study constructs and their measurement will come organically from families' activities in the Tinkering Lab and will be developed in consultation with members of the advisory board. Data collection strategies will include observation and interviews; a series of coding schemes will be used to make sense of the data. The research will result in theoretical and practical understanding of ways to enhance STEM engagement and learning by young children and their families through tinkering. A diverse group of at least 350 children and their families will be involved. The project will provide much needed empirical results on how to promote STEM engagement and learning in informal science education settings. It will yield useful information and resources for informal science learning practitioners, parents, and other educators who look to advance STEM learning opportunities for children. This research is being conducted through a partnership between researchers at Loyola University of Chicago and Northwestern University and museum staff and educators at the Chicago Children's Museum.
The range of contemporary "emerging" technologies with far-reaching implications for society (economic, social, ethical, etc.) is vast, encompassing such areas as bioengineering, robotics and artificial intelligence, genetics, neuro and cognitive sciences, and synthetic biology. The pace of development of these technologies is in full gear, where the need for public understanding, engagement and active participation in decision-making is great. The primary goal of this four-year project is to create, distribute and study a set of three integrated activities that involve current and enduring science-in-society themes, building on these themes as first presented in Mary Shelley's novel, Frankenstein, which will be celebrating in 2018 the 200th anniversary of its publication in 1818. The three public deliverables are: 1) an online digital museum with active co-creation and curation of its content by the public; 2) activities kits for table-top programming; and 3) a set of Making activities. The project will also produce professional development deliverables: workshops and associated materials to increase practitioners' capacity to engage multiple and diverse publics in science-in-society issues. The initiative is funded by the Advancing Informal STEM Learning (AISL) program, which 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 by Arizona State University and their museum and library collaborators around the country will examine the hypothesis that exposing publics to opportunities for interactive, creative, and extensive engagement within an integrated transmedia environment will foster their interest in science, technology, engineering and mathematics (STEM), develop their 21st century skills with digital tools, and increase their understanding, ability, and feelings of efficacy around issues in science-in-society. These three distinct yet interlocking modes of interaction provide opportunities for qualitative and quantitative, mixed-methods research on the potential of transmedia environments to increase the ability of publics to work individually and collectively to become interested in and involved with science-in-society issues.