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).
As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program supports new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This project will meet this goal through rigorous research and the broad implementation of an environmental science literacy professional development and learning program for informal educators and youth engaged in outdoor science programs (OSP). With growing support from the literature and the Next Generation Science Standards (NGSS), much attention has been placed on creating and leveraging interdisciplinary science learning opportunities beyond science classrooms. As such, an estimated 300 residential OSPs currently exist in the United States. Unfortunately, the informal educators often charged with facilitating these deep and impactful science learning experiences often lack robust formal training in evidenced-based, age-appropriate environmental science content knowledge and pedagogy specific for the youth in their programs. This issue is often more pronounced in under-resourced and under-served programs and communities. This project will directly address these pervasive challenges in the field by not only providing much needed science focused professional development and resources to informal educators but also by specifically targeting and training informal leaders and educators serving youth in predominately rural areas, low-income communities, and underrepresented communities.
Approximately 200 OSP leaders at 100 OSPs around the country will participate in a week-long, intensive training in the professional development model at one of five regional residential leadership institutes. OSP leaders will then redeliver the training to the approximately 1,500 OSP educators/field instructors in their home institutions. The OSP educators/field instructors will then use what they learn through the professional development to facilitate the environmental science learning program (i.e., curriculum, field experiences, resources, pedagogy) to over 1 million youth (grades 3-8) enrolled in their residential outdoor science programs. In addition, a rigorous implementation study, efficacy study and evaluation will be conducted. The implementation study will investigate: (a) Which of the professional learning model practices were implemented and (b) What successes and challenges the programs faced implementing the model. The mixed methods efficacy study will explore: (a) if outdoor science programs contribute to the development of science learning activation and environmental literacy? and (b) what are the features of these experiences that are correlated with increases in science learning activation and environmental literacy. Approximately 25-35 youth will be randomly selected from each of 50 randomly selected sites to participate in the efficacy study. The data and findings from the research and evaluation produced by this project will contribute to a relatively sparse knowledge and research base specific to youth efficacy and implementation processes and practices across nearly 1/3 of the estimated 300 existing residential outdoor science programs in the United States.
NASA’s Science Mission Directorate (SMD) explores the Earth, the Sun, our solar system, the galaxy and beyond through four SMD divisions: Earth Science, Heliophysics, Planetary Science and Astrophysics. Alongside NASA scientists, teams of education and public outreach (EPO) specialists develop and implement programs and resources that are designed to inspire and educate students, teachers, and the public about NASA science.
The L.C. Bates Museum will provide 1,700 rural fourth grade students and their families museum-based STEAM (Science, Technology, Engineering, Art, and Mathematics) educational programming including integrated naturalist, astronomy, and art activities that explore Maine's environment and its solar and lunar interactions. The project will include a series of eight classroom programs, family field trips, TV programs, family and classroom self-guided educational materials, and exhibitions of project activities including student work. By bringing programs to schools and offering family activities and field trips, the museum will be able to engage an underserved, mostly low-income population that would otherwise not be able to visit the museum. The museum's programming will address teachers' needs for museum objects and interactive explorations that enhance student learning and new Common Core science curriculum objectives, while offering students engaging learning experiences and the opportunity to develop 21st century leadership skills.
This briefing paper reports findings from the Youth Access & Equity in Informal Science Learning (ISL) project,
a UK-US researcher-practitioner partnership funded by the Science Learning+ scheme. Our project focuses on young people aged 11-14 primarily from under-served and non-dominant communities and includes researchers and practitioners from a range of ISL settings: designed spaces (e.g. museums, zoos), community-based (e.g. after school clubs) and everyday science spaces (e.g. science media).
The State University of New York (SUNY) and the New York Academy of Sciences (NYAS) are collaborating to implement the SUNY/NYAS STEM Mentoring Program, a full scale development project designed to improve the science and math literacy of middle school youth. Building upon lessons learned through the implementation of national initiatives such as NSF's Graduate STEM Fellows in K-12 Education (GK-12) Program, university initiatives such as the UTeach model, and locally-run programs, this project's goals are to: 1) increase access to high quality, hands-on STEM programs in informal environments, 2) improve teaching and outreach skills of scientists in training (graduate and postdoctoral fellows), and 3) test hypotheses around scalable program elements. Together, SUNY and NYAS propose to carry out a comprehensive, systemic science education initiative to recruit graduate students and postdoctoral fellows studying science, technology, engineering, and mathematics (STEM) disciplines at colleges and universities statewide to serve as mentors in afterschool programs. SUNY campuses will partner with a community-based organization (CBO) to place mentors in afterschool programs serving middle school students in high-need, low-resource urban and rural communities. Project deliverables include a three-credit online graduate course for mentor training, six pilot sites, a best practices guide, and a model for national dissemination. The online course will prepare graduate and postdoctoral fellows to spend 12-15 weeks in afterschool programs, introducing students to life science, earth science, mathematics and engineering using curriculum modules that are aligned with the New York State standards. The project design includes three pre-selected sites (College of Nanoscale Science & Engineering at the University of Albany, SUNY Institute of Technology, and SUNY Downstate Medical Center) and three future sites to be selected through a competitive process, each of which will be paired with a CBO to create a locally designed STEM mentoring program. As a result, a minimum of 192 mentors will provide informal STEM education to 2,880 middle school students throughout New York State. The comprehensive, mixed-methods evaluation will address the following questions: 1) Does student participation in an afterschool model of informal education lead to an increase in STEM content knowledge, attitudes, self-efficacy, and interest in pursuing further STEM education and career pathways? 2) Do young scientists who participate in the program develop effective teaching and mentoring skills, and develop interest in teaching or mentoring career options that result in STEM retention? 3) What are the attributes of an effective STEM afterschool program and the elements of local adaptation and innovation that are necessary to achieve a successful scale-up to geographically diverse locations? 4) What is the role of the afterschool model in delivering informal STEM education? This innovative model includes a commitment to scale across the 64 SUNY campuses and 122 Councils of the Girl Scouts of the USA, use an online platform to deliver training, and place scientists-in-training in informal learning environments. It is hypothesized that as a result of greater access to STEM education in an informal setting, participating middle school youth will develop increased levels of STEM content knowledge, self-efficacy, confidence in STEM learning, and interest in STEM careers. Scientist mentors will: 1) gain an understanding of the context and characteristics of informal science education, 2) develop skills in mentoring and interpersonal communication, 3) learn and apply best practices of inquiry instruction, and 4) potentially develop interest in teaching as a viable career option. It is anticipated that the project will add to the research literature in several areas such as the effectiveness of incentives for graduate students; the design of mentor support systems; and the structure of pilot site programs in local communities. Findings and materials from this project will be disseminated through presentations at local, regional, and national conferences, publications in peer-reviewed journals focused on informal science education, and briefings sent to more than 25,000 NYAS members around the world.
Mission to Mars engages 6th-8th grade students in the science, engineering and careers related to Mars exploration. The program is led by the Museum of Science and Industry, Chicago, and includes as partners Challenger Learning Centers in Woodstock, IL, Normal IL and three NASA Centers (Jet Propulsion Laboratory, Marshall Space Flight Center, and Johnson Space Center). The project aims to:
Link, via videoconference, urban and rural middle school students from low income communities in an exploration of space science
Develop and launch programs that showcase NASA Center research
Enrich middle school curricula and promote learning about NASA’s space missions with experiences that inspire youth to pursue in NASA-related STEM careers.
Programs and products produced include:
3 videoconference program scenarios that highlight research being conducted at NASA Centers
Pre- and post-event curriculum materials designed for middle school classrooms
Teacher professional development workshops
Communication support for NASA professionals
iPad apps utilized during the program
Since the program launched five years ago, Mission to Mars has served 7,676 students. MSI seeks to provide opportunities for all learners, and works to remove barriers to participation in high-quality science learning experiences. Mission to Mars allows MSI to engage more Chicago Public Schools (where 86% of students are economically disadvantaged) in real and relevant science experiences that may lead to STEM careers.
As MSI’s CP4SMP grant comes to an end, the Museum has committed to continued delivery of the program through 2 Mission to Mars Learning Labs, offered to 6-8th grade school groups visiting on field trips. Live videoconferencing with JPL and Johnson will occur during roughly half of the sessions. Our Challenger Learning Center partners will integrate Mission to Mars activities, materials and iPad apps into their own Mars-themed programs. Together these efforts extend the transformative hands-on science experiences developed under the Mission to Mars grant to a whole new audience of middle school students and teachers.
"Have You Spotted Me? Learning Lessons by Looking for Ladybugs" is an innovative citizen science project that targets children from Native American, rural, farming, and disadvantaged communities. While most citizen science efforts target teens and adults, this project enables youth ages 5-11 to contribute to the development of a major ladybug database. Adult mentors in youth programs introduce children to topics such as ladybugs, invasive species, biodiversity, and conservation. Youth not affiliated with a program may participate independently. Project deliverables include a self-contained education program, an Internet portal and project website, a dedicated corps of volunteers, and the largest, accessible biological database ever developed. The database is made more reliable by utilizing records accompanied by an identifiable data image as a certified data point. Partners include the NY State 4-H, South Dakota State 4-H, Migrant Worker Children's Education Program, Cayuga Nature Center, Seneca Nation Department of Education Summer Programs, Seneca Nation Early Childhood Learner Centers After School Program, and the Onondaga Nation After School Program. Strategic impact will be realized through the creation of a citizen science project that provides hands-on interactions, field experiences, and accessible data that creates unique learning opportunities for youth. It is estimated that nearly 10,000 youth will be impacted by this work.
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TEAM MEMBERS:
John LoseyLeslie AlleeLouis HeslerMichael CatanguiJohn Pickering
This report is the result of a two-year study that sought to provide a sustained, coherent, and proactive effort to identify and develop the future science, technology, engineering, and math (STEM) innovators in the United States. The report puts forth several policy recommendations, including: increasing K-12 access to accelerated coursework and enrichment programs; offering more “above-level tests,” especially in economically disadvantaged urban and rural areas; holding schools, and perhaps districts and states, accountable for the performance of the top students at each grade level; and
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National Science BoardNational Science Board
This article is a report of the impact assessment of two outreach programs to primary schools run by the Botswana National Museum. The oldest of the programs, Zebra-on-Wheels was officially launched in 1980 and has involved all the primary schools in the country at least twice. The study aimed to establish the impact of the two programs and make recommendations for possible improvements. Thirty-eight schools throughout Botswana participated in the study. Teachers in these schools were interviewed and classroom observation sessions were carried out. Teachers’ observations about the two programs
In this paper, Volker Kirchberg of the University of Lueneburg and Basica Research Institute analyses catchment areas to better understand museums' greater impacts. The author defines these areas as not only a function of distance of the the potential visitors' residence to the venue but also a function of socio-demographic structures of residential areas.
The MyDome project will bring 3D virtual worlds for group interaction into planetaria and portable domes. Advances in computing have evolved the planetarium dome experience from a star field and pointer presentation to a high-resolution movie covering the entire hemispherical screen. The project will further transform the dome theater experience into an interactive immersive adventure. MyDome will develop scenarios in which the audience can explore along three lines of inquiry: (1) the past with archeological reconstructions, (2) the present in a living forest, and (3) the future in a space station or colony on Mars. These scenarios will push the limits of technology in rendering believable environments of differing complexity and will also provide research data on human-centered computing as it applies to inquiry and group interactions while exploring virtual environments. The project proposes to engage a large portion of the population, with a special emphasis on the underserved and under-engaged but very tech-savvy teenage learner. Research questions addressed are: 1. What are the most engaging and educational environments to explore in full-dome? 2. What on-screen tools and presentation techniques will facilitate interactions? 3. What are the limitations for this experience using a single computer, single projector mirror projection system as found in the portable Discovery Dome? 4. Which audiences are best served by exploration of virtual hemispherical environments? 5. How large can the audience be and still be effective for the individual learner? What techniques can be used to provide more people with a level of control of the experience and does the group interaction enhance or diminish the engagement of different individuals? 6. What kind of engagement can be developed in producing scientific and climate awareness? Does experiencing past civilizations lead to more interest in other cultures? Does supported learning in the virtual forest lead to greater connection to and understanding of the real forest? Does the virtual model space experience excite students and citizens about space exploration or increase the understanding of the Earth's biosphere? The broader impacts of the project are (1) benefits to society from increasing public awareness and understanding of human relationships with the environment in past civilizations, today?s forests and climate change, and potential future civilizations in space and on Mars; (2) increasing the appeal of informal science museums to the tech-savvy teenage audience, and (3) significant gains in awareness of young people in school courses and careers in science and engineering. The partners represent a geographically diverse audience and underserved populations that include rural (University of New Hampshire), minority students (Houston Museum of Natural Science) and economically-distressed neighborhoods (Carnegie Museum of Natural History). Robust evaluation will inform each program as it is produced and refined, and will provide the needed data on the potential for learning in the interactive dome environment and on the optimal audience size for each different type of inquiry.
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TEAM MEMBERS:
Annette SchlossKerry HandronCarolyn Sumners