A frequently missing element in environmental education programs is a concerted effort by communities, organizations, government, and academic stakeholders to build meaningful partnerships and cultivate informal science learning opportunities via public participation in environmental research. This collaborative approach not only makes scientific information more readily available, it also engages community members in the processes of scientific inquiry, synthesis, data interpretation, and the translation of results into action. This project will build a co-created citizen science program coupled with a peer education model and an extensive communication of results to increase environmental STEM literacy. The project targets historically underrepresented populations that are likely to be disproportionately impacted by climate, water scarcity, and food security. Based upon past needs assessments in the targeted communities, gardens irrigated by harvested rainwater will become hubs for environmental STEM education and research. For this project, gardens irrigated by harvested rainwater will serve as hubs for environmental literacy education efforts. Researchers from the University of Arizona and Sonora Environmental Research Institute will work alongside community environmental health workers, who will then train families residing in environmentally compromised areas (urban and rural) on how to monitor their soil, plant, and harvested water quality. The project aims to: (1) co-produce environmental monitoring, exposure, and risk data in a form that will be directly relevant to the participants' lives, (2) increase the community's involvement in environmental decision-making, and (3) improve environmental STEM literacy and learning in underserved rural and urban communities. The project will investigate and gather extensive quantitative and quantitative data to understand how: (1) participation in a co-created citizen science project enhances a participant's overall environmental STEM literacy; (2) a peer-education model coupled with a co-created citizen science program affects participation of historically underrepresented groups in citizen science; and (3) the environmental monitoring approach influences the participant's environmental health learning outcomes and understanding of the scientific method. In parallel, this project will evaluate the role of local-based knowledge mediators and different mechanisms to communicate results. These findings will advance the fields of informal science education, environmental science, and risk communication. Concomitantly, the project will facilitate the co-generation of a robust dataset that will not only inform guidelines and recommendations for harvested rainwater use, it will build capacity in underserved communities and inform the safe and sustainable production of food sources. This research effort is especially critical for populations in arid and semiarid environments, which account for ~40% of the global land area and are inhabited by one-third of the world's population. This program will be available in English and Spanish and can truly democratize environmental STEM research and policy. 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 STEM learning in informal environments.
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds innovative resources for use in a variety of settings. This proposed effort embraces broad participation by the three Ute tribes, History Colorado, and scientists in the field of archaeology to investigate and integrate traditional ecological knowledge and contemporary Western science. The project will preserve knowledge from the Ute peoples of Colorado and Utah, including traditional technology, ethnobotany, engineering and math. Results from this project will inform educational efforts in similar communities.
This project will build on the long-standing collaborations between History Colorado (HC), the Southern Ute Indian Tribe, Ute Mountain Ute Tribe and Ute Indian Tribe, Uintah & Ouray Reservation, and the Dominguez Archaeological Research Group DARG). HC will implement and evaluate a regional informal learning collaboration focused on Ute traditional and contemporary STEM knowledge serving over 128,000 learners through tribal programs, local history museums and educational networks. This project will advance the understanding of integrated knowledge and the role of Ute people as STEM learners and practitioners. This Informal Science Learning project will increase lifelong STEM learning in rural communities and create a replicable model for collaboration among tribes, history museums, and scientists.
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
Pacific Science Center (Science Center) has been a pillar of science education programming in Seattle, Washington since 1962. Through interactive exhibits, planetarium shows, IMAX movies and outreach, the Science Center works to inspire a lifelong interest in science, math and technology. In 2010, the Science Center joined forces with the National Aeronautics and Space Administration (NASA) through NASA Now: Using Current Data, Planetarium Technology and Youth Career Development to Connect People to the Universe. NASA Now was designed to increase the awareness, knowledge and understanding of
The NISE Network Professional Impacts Summative Evaluation is a longitudinal examination of individual professionals over the final three years of NISE Net funding. This investigation is based on the NISE Network goals for professionals and explores how involvement with NISE Net impacts an individual professional’s sense of community, learning about nano, and use of nano educational products and practices. This evaluation primarily included professional partners who were: (1) Informal Science Educators (ISE): Professionals from science museums and children’s museums implementing informal
The Art of Science Learning Project (AoSL) is a National Science Foundation (NSF)-funded initiative, founded and directed by Harvey Seifter, that uses the arts to spark creativity in science education and the development of an innovative 21st century STEM workforce. This research was guided by three main hypotheses: (1) Arts-based innovation training, compared to traditional innovation training, improves an individuals creative thinking skills including critical thinking, divergent thinking, problem identification, convergent thinking and problem solving; (2) Arts-based innovation training
This project takes an ethnographic and design-based approach to understanding how and what people learn from participation in makerspaces and explores the features of those environments that can be leveraged to better promote learning. Makerspaces are physical locations where people (often families) get together to make things. Some participants learn substantial amounts of STEM content and practices as they design, build, and iteratively refine working devices. Others, however, simply take a trial and error approach. Research explores the affordances are of these spaces for promoting learning and how to integrate technology into these spaces so that they are transformed from being makerspaces where learning happens, but inconsistently, into environments where learning is a consistent outcome of participation. One aim is to learn how to effectively design such spaces so that participants are encouraged and helped to become intentional, reflective makers rather than simply tinkerers. Research will also advance what is known about effective studio teaching and learning and advance understanding of how to support youth to help them become competent, creative, and reflective producers with technology(s). The project builds on the Studio Thinking Framework and what is known about development of meta-representational competence. The foundations of these frameworks are in Lave and Wengers communities of practice and Rogoff's, Stevens et al.'s, and Jenkins et al.'s further work on participatory cultures for social networks that revolve around production. A sociocultural approach is taken that seeks to understand the relationships between space, participants, and technologies as participants set and work toward achieving goals. Engaging more of our young population in scientific and technological thinking and learning and broadening participation in the STEM workplace are national imperatives. One way to address these imperatives is to engage the passions of young people, helping them recognize the roles STEM content and practices play in achieving their own personal goals. Maker spaces are neighborhood spaces that are arising in many urban areas that allow and promote tinkering, designing, and construction using real materials, sometimes quite sophisticated ones. Participating in designing and successfully building working devices in such spaces can promote STEM learning, confidence and competence in one's ability to solve problems, and positive attitudes towards engineering, science, and math (among other things). The goal in this project is to learn how to design these spaces and integrate learning technologies so that learning happens more consistently (along with tinkering and making) and especially so that they are accessible and inviting to those who might not normally participate in these spaces. The work of this project is happening in an urban setting and with at-risk children, and a special effort is being made to accommodate making and learning with peers. As with Computer Clubhouses, maker spaces hold potential for their participants to identify what is interesting to them at the same time their participation gives them the opportunity to express themselves, learn STEM content, and put it to use.
On November 2-3, 2015, the American Society for Engineering Education (ASEE), with funding from the National Science Foundation (NSF), hosted the 2015 NSF Maker Summit, in the Washington, D.C. metro area. Planned in response to a Call to Action issued by the White House after the June 2014 White House Maker Faire, the summit was attended by more than 50 individuals representing five different segments of the Maker community. Its goals were to forge connections across the Maker Movement, envision the future of Making for engineering and education communities, and identify how Makerspaces can be
This poster was presented at the 2016 Advancing Informal STEM Learning (AISL) PI Meeting held in Bethesda, MD on February 29-March 2. How can we come to terms with the complex social impact of new cutting-edge fields like synthetic biology, robotics, genetics and
machine learning? In order to manage these transformative changes, people not only need to understand science and technology, but also to actively participate in shaping a world where our ability to control the building blocks of life and cognition is vastly expanded. The Transmedia Museum will use the interactive, engaging nature of
In 2012, the Conner Prairie Interactive History Park began work on the National Science Foundation-funded Prairie Science project. Its goal: to produce a framework for integrating informal science experiences into exhibitions, interpretation, and programs at historic sites and museums. From the outset, the core project team acknowledged that the task of integrating STEM (Science, Technology, Engineering, and Math) and history learning would challenge the norms of both disciplines and institutions. Conner Prairie is a history museum in Fishers, Indiana, with a long tradition of exploring novel
The Exhibit Designs for Girls’ Engagement (EDGE) project is a three-year Exploratorium-run, NSF-funded, research study aiming to identify the most important design attributes for engaging girls at STEM exhibits. We identified nearly 100 exhibit design attributes that had the potential for better engaging girls. To test those 100 attributes and their relationship to girls’ engagement, we studied more than 300 physics, engineering, math, and perception exhibits at the Exploratorium, the Science Museum of Minnesota, and the Arizona Science Center. The purpose of the EDGE research was to winnow