This Science Learning+ project will develop a Youth Access & Equity Research & Practice Agenda, focusing on addressing equity issues for youth, ages 11-14, primarily from non-dominant backgrounds. The project will involve researchers and practitioners from three ISL settings/contexts, (1) Designed spaces, e.g., museums; (2) Community-based, e.g., afterschool clubs; and (3) Everyday science, e.g., science media. The goal of the agenda will be to advance scholarly understanding of equity issues in relation to these three contexts. Taking an ecological view of STEM learning as a sociocultural process of participation and transformation, the project will employ a Complex Adaptive System lens to document multiple pathways youth take (or not) within/across ISL settings over time, the impact these pathways have on learning and development, and their influence on ISL organizations themselves. These lenses will help us identify aspects of learning environments which shape youth access and development, and the value and impact of the equity ideas, tools and practices.
The purposes of the STUDIO 3D evaluation were to collect information about the impact upon student learning as a result of participating in the STUDIO 3D Project, as well as to elicit information for program improvement. Areas of inquiry include recruiting and retention, impact on project participants, tracking student impacts, and the project as a whole.
The formative evaluation of Season 2 of Design Squad was performed in two parts. Part 1 included a field test conducted by American Institutes for Research in spring 2008. Part 2, conducted by Veridian inSight, included follow-up interviews with teachers whose classrooms participated in the field test. The teacher interviews were conducted in fall of 2008. This document is the Design Squad, Season 2 final evaluation report. It contains the following sections: Section 1: Highlights from the teacher interviews conducted in fall of 2008 by Veridian inSight. Section 2: Findings from the field test
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Veridian inSight, LLCAmerican Institutes for Research
This research follows on a previous study that investigated how digitally augmented devices and knowledge building could enhance learning in a science museum. In this study, we were interested in understanding which combination of scaffolds could be used in conjunction with the unique characteristics of informal participation to increase conceptual and cognitive outcomes. Three hundred seven students from nine middle schools participated in the study. Six scaffolds were used in various combinations. The first was the digital augmentation. The next five were adaptations of knowledge-building
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Susan YoonKaren ElinichJoyce WangJaqueline SchooneveldEmma Anderson
For the purpose of clarity and consistency, the term e-learning is used throughout the paper to refer to technology-enhanced learning and information technology (IT) in teaching and learning. IT depicts computing and other IT resources. Research into e-learning has changed in focus and breadth over the last four decades as a consequence of changing technologies, and changes in educational policies and practices. Although increasing numbers of young people have access to a wide range of IT technologies during their leisure activities, little is known about this impact on their learning. Much of
In this article, we discuss the importance of recognizing students' technology-enhanced informal learning experiences and develop pedagogies to connect students' formal and informal learning experiences, in order to meet the demands of the knowledge society. The Mobile- Blended Collaborative Learning model is proposed as a framework to bridge the gap between formal and informal learning and blend them together to form a portable, flexible, collaborative and creative learning environment. Using this model, three categories of mobile application tools, namely tools for collaboration, tools for
The Flathead Community of Resource Educators (CORE) is a consortium of educators in the Flathead Watershed. They produced the Flathead Watershed Sourcebook as a tool to increase understanding and appreciation of the region. The objective of this project is to produce a curriculum guide to accompany the Sourcebook. This curriculum project will be carried out by a team of experts in interdisciplinary teacher education from Montana State University. The project will be conducted in four phases and include the guidance and feedback of Scientists, Educators, and Resource Managers living and working within the Flathead watershed.
The Ross Sea Project was a Broader Impact projects for an NSF sponsored research mission to the Ross Sea in Antarctica. The project, which began in the summer of 2010 and ended in May 2011, consisted of several components: (1) A multidisciplinary teacher-education team that included educators, scientists, Web 2.0 technology experts and storytellers, and a photographer/writer blogging team; (2) Twenty-five middle-school and high-school earth science teachers, mostly from New Jersey but also New York and California; (3) Weeklong summer teacher institute at Liberty Science Center (LSC) where teachers and scientists met, and teachers learned about questions to be investigated and technologies to be used during the mission, and how to do the science to be conducted in Antarctica; (4) COSEE NOW interactive community website where teachers, LSC staff and other COSEE NOW members shared lesson plans or activities and discussed issues related to implementing the mission-based science in their classrooms; (5) Technological support and consultations for teachers, plus online practice sessions on the use of Web 2.0 technologies (webinars, blogs, digital storytelling, etc.); (6)Daily shipboard blog from the Ross Sea created by Chris Linder and Hugh Powell (a professional photographer/writer team) and posted on the COSEE NOW website to keep teachers and students up-to-date in real-time on science experiments, discoveries and frustrations, as well as shipboard life; (7) Live webinar calls from the Ross Sea, facilitated by Rutgers and LSC staff, where students posed questions and interacted directly with shipboard researchers and staff; and (8) A follow-up gathering of teachers and scientists near the end of the school year to debrief on the mission and preliminary findings. What resulted from this project was not only the professional development of teachers, which extended into the classroom and to students, but also the development of a relationship that teachers and students felt they had with the scientists and the science. Via personal and virtual interactions, teachers and students connected to scientists personally, while engaged in the science process in the classroom and in the field.
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. The project will further develop, roll out, and conduct research on a set of materials that will introduce middle school age youth to innovative and engaging engineering challenges in the Boys and Girls Club (B&GCs) context. Building on substantial prior work and evaluation-based learning, WISE Guys and Gals - Boys & Girls as WISEngineering STEM Learners (WGG) will: (1) combine engineering design activities with the (open source, online) WISEngineering infrastructure; (2) scale-up the infrastructure; (3) engage youth in informal afterschool experiences; and (4) collect a wealth of rich data to further our understanding of how youth learn through these experiences. This work will be conducted by Hofstra University's Center for STEM Research in conjunction with Brookhaven National Laboratory (BNL), The CUNY Graduate Center's Center for Advanced Study in Education (CASE), the Boys & Girls Club of America, and 25 B&GCs in New York and New Jersey. The underlying theoretical framework builds on proof-of-concept work supported by NSF and the Bill and Melinda Gates Foundation. An open source, on-line interface (WISEngineering) provides numerous virtual tools (e.g., social networking, Design Journal, embedded assessments) that promote learning and collaboration through challenging, thoughtful, and creative work. WGG will explore how to incorporate creativity, social networking, connections to real-world STEM needs/careers, and teamwork into challenges that can be completed in a one-hour period, an activity time constraint in many B&GC settings. Staff from the clubs will participate in face-to-face and virtual professional development in an effort to build their capacity as facilitators of STEM learning. Research will focus on: (1) how activities developed for 60-minute implementation and guided by informed engineering design and interconnected learning frameworks support youth learning and engagement; and (2) characteristics of the professional development approach that support B&GC facilitators' capacity development. By the end of the project, over 6,000 middle school aged youth, the majority from groups underrepresented in STEM areas, will gain experience with engineering design as they develop engineering thinking, new STEM competencies, STEM career awareness, and an appreciation for the civic value of STEM knowledge.
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David BurghardtXiang FuKenneth WhiteMelissa Rhodes
This project supports the development of technological fluency and understanding of STEM concepts through the implementation of design collaboratives that use eCrafting Collabs as the medium within which to work with middle and high school students, parents and the community. The researchers from the University of Pennsylvania and the Franklin Institute combine expertise in learning sciences, digital media design, computer science and informal science education to examine how youth at ages 10-16 and families in schools, clubs, museums and community groups learn together how to create e-textile artifacts that incorporate embedded computers, sensors and actuators. The project investigates the feasibility of implementing these collaboratives using eCrafting via three models of participation, individual, structured group and cross-generational community groups. They are designing a portal through which the collaborative can engage in critique and sharing of their designs as part of their efforts to build a model process by which scientific and engineered product design and analysis can be made available to multiple audiences. The project engages participants through middle and high school elective classes and through the workshops conducted by a number of different organizations including the Franklin Institute, Techgirlz, the Hacktory and schools in Philadelphia. Participants can engage in the eCrafting Collabs through individual, collective and community design challenges that are established by the project. Participants learn about e-textile design and about circuitry and programming using either ModKit or the text-based Arduino. The designs are shared through the eCrafting Collab portal and participants are required to provide feedback and critique. Researchers are collecting data on learner identity in relation to STEM and computing, individual and collective participation in design and student understanding of circuitry and programming. The project is an example of a scalable intervention to engage students, families and communities in developing technological flexibility. This research and development project provides a resource that engages students in middle and high schools in technology rich collaborative environments that are alternatives to other sorts of science fairs and robotic competitions. The resources developed during the project will inform how such an informal/formal blend of student engagement might be scaled to expand the experiences of populations of underserved groups, including girls. The study is conducting an examination of the new types of learning activities that are multiplying across the country with a special focus on cross-generational learning.
This project examines the design principles by which computer-based science learning experiences for students designed for classroom use can be integrated into virtual worlds that leverage students' learning of science in an informal and collaborative online environment. GeniVille, developed and studied by the Concord Consortium, is the integration of Geniverse, a education based game that develops middle school students' understanding of genetics with Whyville, developed and studied by Numedeon, Inc., an educational virtual word in which students can engage in a wide variety of science activities and games. Genivers has been extensively researched in its implementation in the middle school science classroom. Research on Whyville has focused on how the learning environment supports the voluntary participation of students anywhere and anytime. This project seeks to develop an understanding of how these two interventions can be merged together and to explore mechanisms to create engagement and persistence through incentive structures that are interwoven with the game activities. The project examines the evidence that students in middle schools in Boston learn the genetics content that is the learning objective of GeniVille. The project uses an iterative approach to the modification of Geniverse activites and the Whyville context so that the structured learning environment is accessible to students working collaboratively within the less structured context. The modification and expansion of the genetics activities of the project by which various inheritance patterns of imaginary dragons are studied continues over the course of the first year with pilot data collected from students who voluntarily engage in the game. In the second year of the project, teachers from middle schools in Boston who volunteer to be part of the project will be introduced to the integrated learning environment and will either use the virtual learning environment to teach genetics or will agree to engage their students in their regular instruction. Student outcomes in terms of engagement, persistence and understanding of genetics are measured within the virtual learning environment. Interviews with students are built into the GeniVille environment to gauge student interest. Observations of teachers engaging in GeniVille with their students are conducted as well as interviews with participating teachers. This research and development project provides a resource that blends together students learning in a computer simulation with their working in a collaborative social networking virtual system. The integration of the software system is designed to engage students in learning about genetics in a simulation that has inherent interest to students with a learning environment that is also engaging to them. The project leverages the sorts of learning environments that make the best use of online opportunities for students, bringing rich disciplinary knowledge to educational games. Knowing more about how students collaboratively engage in learning about science in a social networking environment provides information about design principles that have a wide application in the development of new resources for the science classroom.
The Cyberlearning and Future Learning Technologies Program funds efforts that will help in envisioning the next generation of learning technologies and advancing what we know about how people learn in technology-rich environments. Development and Implementation (DIP) Projects build on proof-of-concept work that showed the possibilities of the proposed new type of learning technology, and project teams build and refine a minimally-viable example of their proposed innovation that allows them to understand how such technology should be designed and used in the future and answer questions about how people learn with technology. Although for years researchers have believed technology could afford anytime-anywhere learning, we still don't understand how learners behave differently across contexts, such as home, school, and in the community, and how to get youth to identify as learners across those contexts. This proposal aims to use mobile devices and strategically placed shared kiosks to 'scientize' youth in two low-income communities. Through strategic partnerships with community organizations, educators, and families, the innovation is to get primary and middle-school students engaging in scientific inquiry in the context of their neighborhoods. Research will help determine how the technology can best be deployed, but also answer important questions about how communities can provide support to help kids think like scientists and identify with science. This project will design and implement ubiquitous technology tools that include mobile social media and tangible, community displays (collectively called ScienceKit) that are deeply embedded into two urban neighborhoods, and demonstrate how such ubiquitous technologies and related cyberlearning strategies are vital to improve information flow and coordination across a neighborhood ecosystem, in order to create environments where children can connect their science learning across contexts and time (e.g. scientizing). A program called ScienceEverywhere comprised of partnerships between tightly connected neighborhood organizations with mentors, teachers, parents, and researchers will help learners develop scientifically literate practices both in and out of school, and will demonstrate students' learning to their communities. Research will consist of mixed methods studies of use of the tools, including iterative design-based research, ethnography, and the use of participant observers from the community; these will be triangulated with usage logs of the technologies and content analysis of microblogs by the learners on their identities and interests. Discourse analysis of interviews with focal learners will orient the qualitative work on identity development, and analysis using activity theory will inform the influences of the social practices and sociotechnical systems on learner trajectories. Formative evaluation will help shed light on if and how the sociotechnical system promotes STEM literacy and STEM identity development.