RISES (Re-energize and Invigorate Student Engagement through Science) is a coordinated suite of resources including 42 interactive English and Spanish STEM videos produced by Children's Museum Houston in coordination with the science curriculum department at Houston ISD. The videos are aligned to the Texas Essential Knowledge and Skills standards, and each come with a bilingual Activity Guide and Parent Prompt sheet, which includes guiding questions and other extension activities.
This Innovations in Development project is funded by the Advancing Informal STEM Learning 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.
Quantum information science (QIS) is an emergent cross-disciplinary field at the interface of physics, computer science, materials science, and engineering. Yet, there are few educational programs that encourage young people to explore QIS and understand its applications and societal benefits. Such programs are critical for supporting the growth of a quantum-ready workforce. Building intuition is a foundational first step but this is challenging because quantum effects are neither visible to the naked eye, nor experienced in everyday life. This project will create a suite of accessible, engaging digital games for middle schoolers, and study their effectiveness in cultivating intuition around QIS. Relating QIS concepts to common game mechanics is designed to increase students’ confidence in their QIS knowledge, reduce their fear of tackling such a subject, and consider pursuing a career in this field or another STEM area. The game-driven design appeals to a broad population beyond the age groups studied. Moreover, the deliverables will be freely available online, which allows anyone with a phone or computer and internet access a way to learn about QIS in an engaging, play-based environment. The program will partner with teacher organizations and other community groups to share the games, maximizing the project’s impact.
The project is guided by the QIS Key Concepts developed in 2020, as well as research and best practices on gamification of learning. The games will be designed for 6th-8th grade students in an informal setting, focusing on the concepts of probability, superposition, and role of measurement. A game world titled "Quander" will include videos that explicitly tie game experiences to QIS concepts and applications. The project will evaluate students' understanding after playing the games and watching the videos, how they engage with aspects of the games, and how the game impacted their interest in QIS. The project data will advance understanding of how to facilitate QIS informal learning experiences in ways that engage young audiences in QIS and similar abstract emerging areas of technology where current research is scant. This project represents one of the first efforts to teach QIS concepts in ways that connect directly to young learners’ play-based experiences. Data gathered from the project will help future program designers understand the ability of young learners to reason about QIS concepts such as measurement, superposition and probabilities in game contexts, providing insights to the ages at which students are ready for more technical content.
This workshop is funded through the "Dear Colleague Letter: Principles for the Design of Digital Science, Technology, Engineering, and Mathematics (STEM) Learning Environments (NSF 18-017)." In today's educational climate, organizations are creating physical learning spaces for hands-on STEM activities, often called makerspaces, co-working spaces, innovation labs, or fablabs. These spaces have evolved to be interdisciplinary centers that personalize learning for individual, diverse learners in collaborative settings. When designed well, these physical spaces create communities that contextualize learning around participants' goals and thus address STEM learning in a dynamic and integrated way. Participation in these learning environments encourages the cultivation of STEM identities for young people and can positively direct their career trajectories into STEM fields. This workshop will bring together a community of collaborators from multiple stakeholder groups including academia, public libraries, museums, community based organizations, non-profits, media makers and distribution channels, and educators within and beyond K-12 schools. Led by the University of Arizona, and held at Biosphere 2, an international research facility, participants will engage in activities that invite experimentation with distributed learning technologies to examine ways to adapt learning to the changing technological landscape and create robust, dynamic online learning environments. The workshop will culminate in a synthesis of design principles, assessment approaches, and tools that will be shared widely. Partnerships arising from the workshop will pave the way for sustained efforts in this area that span research and practice communities. Outcomes will address research and development of the next generation of digitally distributed learning environments.
The three day workshop convening will provide a unique forum to (1) exchange innovative ideas and share challenges and opportunities, (2) connect practical and research-based expertise and (3) form cross-institutional and cross-community partnerships that envision, propose, and implement opportunities for collecting and analyzing data to systematically inform the collective understanding. Participation-based activities will include design-based experiences, participatory activities, demonstrations of works in progress, prototyping, creative pitching, practitioner lightning talks, small group breakouts, hands-on design activities, and an 'unconference' style synthesis of bold ideas. Participants will be invited to experiment with distributed learning technologies. Five focus areas for the workshop include (1) inclusivity of learning spaces that invite multiple perspectives and full participation, (2) documenting learning in ways that are linked to outcomes and impacts for all learners, (3) implementing the use of new technologies in diverse settings, such as the workforce, (4) interpersonal interactions and peer-to-peer learning that may encourage a STEM career-path, and, (5) methods for collecting and analyzing data at the intersection of people, the learning environment, and new technologies at multiple levels. Outcomes of the workshop will serve to advance knowledge regarding critical gaps and opportunities and identify and characterize models of collaboration, networking, and innovation that operate within and across studio-based STEM learning environments.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Described by Wohlwend, Peppler, Keune and Thompson (2017) as “a range of activities that blend design and technology, including textile crafts, robotics, electronics, digital fabrication, mechanical repair or creation, tinkering with everyday appliances, digital storytelling, arts and crafts—in short, fabricating with new technologies to create almost anything” (p. 445), making can open new possibilities for applied, interdisciplinary learning in science, technology, engineering and mathematics (Martin, 2015), in ways that decenter and democratize access to ideas, and promote the construction
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TEAM MEMBERS:
Jill CastekMichelle Schira HagermanRebecca Woodland
Meaningful Making 2 is a second volume of projects and strategies from the Columbia University FabLearn Fellows. This diverse group of leading K–12 educators teach in Fab Labs, makerspaces, classrooms, libraries, community centers, and museums—all with the goal of making learning more meaningful for every child.
A learning revolution is in the making around the world. Enthusiastic educators are using the new tools and technology of the maker movement to give children authentic learning experiences beyond textbooks and tests. The FabLearn Fellows work at the forefront of this movement in all
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TEAM MEMBERS:
Paulo BliksteinSylvia Libow MartinezHeather Allen PangKevin Jarrett
This book contains project ideas, articles, and best practices from educators at the forefront of making and hands-on education. The Stanford University FabLearn Fellows are a group of K-12 educators teaching in Fab Labs, makerspaces, classrooms, libraries, community centers, and museums—all with the goal of making learning more meaningful.
In this book, the FabLearn Fellows share inspirational ideas from their learning spaces, assessment strategies and recommended projects across a broad range of age levels. Illustrated with color photos of real student work, the Fellows take you on a
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TEAM MEMBERS:
Paulo BliksteinSylvia Libow MartinezHeather Allen Pang
This study researched whether and how affiliation with the Nanoscale Informal Science Education Network (NISE Net) led to change in informal science education organizations’ (ISEs) practices. The NISE Net provided an opportunity to look at how participation in a large but loosely-structured network of museums, science centers, educators, and scientists can influence museums to experience organizational change and adopt new practices.
By conducting qualitative case studies of a few selected partners, this research aimed to understand the conditions that facilitate or impede the influence of
As a part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds research and innovative resources for use in a variety of settings. This Broad Implementation project would scale up the CryptoClub Project, an afterschool and online program designed to engage middle school youth in mathematics and cryptography. The project builds on previous successful work and evaluation that is ready for scale up using a train-the-trainer model implemented through a partnership with the National Girls Collaborative. The project will train 160 new CryptoClub leaders who will then train 800 new leaders at 20 hub sites reaching 9600 students. In addition, professional development modules and webinars will continue to refresh leader skills. Other project components include an online multiplayer cryptography game, weekly challenges through social media, and digital cryptology badges for students.
The research uses a think-aloud method with students as they actually attempt to solve the cryptology problems using mathematical thinking. Three think-aloud studies will be performed during the Project. The research team will code transcripts of the interviews for evidence of the mathematical thinking intended to be addressed by each activity, as well as capturing unexpected kinds of thinking. Tasks will also be rated according to the type of knowledge elicited. A written report will include statistical analyses of the think-aloud and interview responses, interpreted in light of the overall CryptoClub goals. The findings will contribute to both future research efforts and practice. The evaluation by EDC uses a quasi-experimental design, which assesses project outcomes for trainers, leaders, students, and Internet users. EDC will also investigate the fidelity to the CryptoClub model as it is scaled up. These studies have strong potential for informing numerous other projects that are at a stage where scale up is under consideration.
Be a 4-H Scientist! Materials in a Green, Clean World is an inquiry-based science curriculum focusing on concepts of materials; plastics; reuse, recycle, and reduce; and the work of scientists and engineers. It is designed to build foundational skills of science and engineering: observation, asking questions, sorting and classifying, and communicating. The curriculum contains six learning modules intended for delivery in out-of-school time facilitated by an educator (trained volunteers or program staff). Most modules also include a “Science At Home” activity which parents/other adults and children can do at home.
As a part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program funds research and innovative resources for use in a variety of settings. This Broad Implementation project would scale up the CryptoClub Project, an afterschool and online program designed to engage middle school youth in mathematics and cryptography. The project builds on previous successful work and evaluation that is ready for scale up using a train-the-trainer model implemented through a partnership with the National Girls Collaborative. The project will train 160 new CryptoClub leaders who will then train 800 new leaders at 20 hub sites reaching 9600 students. In addition, professional development modules and webinars will continue to refresh leader skills. Other project components include an online multiplayer cryptography game, weekly challenges through social media, and digital cryptology badges for students.
The research uses a think-aloud method with students as they actually attempt to solve the cryptology problems using mathematical thinking. Three think-aloud studies will be performed during the Project. The research team will code transcripts of the interviews for evidence of the mathematical thinking intended to be addressed by each activity, as well as capturing unexpected kinds of thinking. Tasks will also be rated according to the type of knowledge elicited. A written report will include statistical analyses of the think-aloud and interview responses, interpreted in light of the overall CryptoClub goals. The findings will contribute to both future research efforts and practice. The evaluation by EDC uses a quasi-experimental design, which assesses project outcomes for trainers, leaders, students, and Internet users. EDC will also investigate the fidelity to the CryptoClub model as it is scaled up. These studies have strong potential for informing numerous other projects that are at a stage where scale up is under consideration.
This guide offers a comprehensive overview of NISE Network programming, including development by a multi-organization team, implementation by hundreds of partners nationwide, and impact on public audiences. It offers a practical introduction to the approaches, methods, and tools the Network uses to ensure our programs provide effective learning opportunities.
The Nanoscale Informal Science Education Network (NISE Network) is a national infrastructure that links science museums and other informal science education organizations with nanoscale science and engineering research organizations. The Network’s overall goal is to foster public awareness, engagement, and understanding of nanoscale science, engineering, and technology. As part of the front-end effort, this report, Part IIB, documents 19 nanoscale STEM programming, media, and school-based projects that have been completed or are in development as of 2005.