'Be a Scientist!' is a full-scale development project that examines the impact of a scalable, STEM afterschool program which trains engineers to develop and teach inquiry-based Family Science Workshops (FSWs) in underserved communities. This project builds on three years of FSWs which demonstrate improvements in participants' science interest, knowledge, and self-efficacy and tests the model for scale, breadth, and depth. The project partners include the Viterbi School of Engineering at the University of Southern California, the Albert Nerken Engineering Department at the Cooper Union, the Los Angeles Museum of Natural History, and the New York Hall of Science. The content emphasis is physics and engineering and includes topics such as aerodynamics, animal locomotion, automotive engineering, biomechanics, computer architecture, optics, sensors, and transformers. The project targets underserved youth in grades 1-5 in Los Angeles and New York, their parents, and engineering professionals. The design is grounded in motivation theory and is intended to foster participants' intrinsic motivation and self-direction while the comprehensive design takes into account the cultural, social, and intellectual needs of diverse families. The science activities are provided in a series of Family Science Workshops which take place in afterschool programs in eight partner schools in Los Angeles and at the New York Hall of Science in New York City. The FSWs are taught by undergraduate and graduate engineering students with support from practicing engineers who serve as mentors. The primary project deliverable is a five-year longitudinal evaluation designed to assess (1) the impact of intensive training for engineering professionals who deliver family science activities in community settings and (2) families' interest in and understanding of science. Additional project deliverables include a 16-week training program for engineering professionals, 20 physics-based workshops and lesson plans, Family Science Workshops (40 in LA and 5 in NY), a Parent Leadership Program and social networking site, and 5 science training videos. This project will reach nearly one thousand students, parents, and student engineers. The multi-method evaluation will be conducted by the Center for Children and Technology at the Education Development Center. The evaluation questions are as follows: Are activities such as recruitment, training, and FSWs aligned with the project's goals? What is the impact on families' interest in and understanding of science? What is the impact on engineers' communication skills and perspectives about their work? Is the project scalable and able to produce effective technology tools and develop long-term partnerships with schools? Stage 1 begins with the creation of a logic model by stakeholders and the collection of baseline data on families' STEM experiences and knowledge. Stage 2 includes the collection of formative evaluation data over four years on recruitment, training, co-teaching by informal educators, curriculum development, FSWs, and Parent Leadership Program implementation. Finally, a summative evaluation addresses how well the project met the goals associated with improving families' understanding of science, family involvement, social networking, longitudinal impact, and scalability. A comprehensive dissemination plan extends the project's broader impacts in the museum, engineering, evaluation, and education professional communities through publications, conference presentations, as well as web 2.0 tools such as blogs, YouTube, an online social networking forum for parents, and websites. 'Be a Scientist!' advances the field through the development and evaluation of a model for sustained STEM learning experiences that helps informal science education organizations broaden participation, foster collaborations between universities and informal science education organizations, increase STEM-based social capital in underserved communities, identify factors that develop sustained interest in STEM, and empower parents to co-invest and sustain a STEM program in their communities.
A Framework for K-12 Science Education and Next Generation Science Standards (NGSS) describe a new vision for science learning and teaching that is catalyzing improvements in science classrooms across the United States. Achieving this new vision will require time, resources, and ongoing commitment from state, district, and school leaders, as well as classroom teachers. Successful implementation of the NGSS will ensure that all K-12 students have high-quality opportunities to learn science. Guide to Implementing the Next Generation Science Standards provides guidance to district and school
Operation Magpie was a citizen science project that involved the community in collecting data about magpies. This article describes one aspect of the project from an education perspective. The study began with a collaboration of teacher educators, environmental scientists and a local radio station. After an initial workshop with 75 teachers, three teacher educators met regularly with 13 primary teachers who each volunteered to plan and teach a unit of work on birds. Meeting regularly in focus groups, the teachers shared their pedagogical strategies that supported students to connect with their
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Yvonne ZeegersKathryn PaigeDavid LloydPhilip Roetman
The article discusses citizen science projects focused on entomology, and examines their usefulness for engaging students in science education and providing meaningful hands-on educational experiences. Advice for incorporating citizen science into lessons and curricula are offered, and the applicability of entomology to science education standards is touched on.
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Renee ClarJames WandersheeJohn GuytonMichael Williams
Encouraging nonprofessionals to participate in ecological research through citizen science programs is a recent innovation and an effective strategy for gathering ecological information across broad geographical areas. In this paper, we demonstrate how reporting field-based observations through eBird, a citizen-based birding and data-recording program, can be used as a lab activity in an undergraduate ecology class. This exercise exposes students to worldwide data collecting networks in which non-scientific communities serve as major stakeholders. This lab activity also introduces basic field
The article presents advice by the authors for helping middle school science teachers in the U.S. to plan field trips related to science education. The authors say that the teachers should try to make the field trips a significant learning experience. They should communicate the goals of the trips to the students. According to them, many science museums offer pretrip planning meetings to allow teachers to know the resources available for students. They also offer excellent web sites for planning the trips.
The article discusses how a visit to a science museum illustrates the concept of informal learning in science education. The author describes a visit to a museum with science educator Jim Kisiel, who comments on how the behavior of museum guests is used to design exhibits. Kisiel discusses the importance of visually interesting displays and the role of signage in educating museum guests. The author suggests that similar concepts apply to science education in the classroom.
Collaboration efforts between educator preparation programs and children's science museums are important in assisting elementary pre-service teachers connect the theory they have learned in their classrooms with the actual practice of teaching. Elementary pre-service teachers must not only learn the science content, but how to effectively deliver that science content to a group of students. One university provided their elementary pre-service teachers with the opportunity to prepare and deliver science lessons to students in a children's science museum in south Texas.
It seems uncontroversial to claim that museums are unique places of interest with the potential to inspire learners, yet what this means and how it is managed are complex questions. Museum educators’ work is currently shaped by accountability requirements typically expressed as visitor targets. Centralised teaching and learning initiatives are presented as ‘good practice’. In opposition to these factors, the action research inquiry discussed here set out to enable the participants to research and reflect upon the challenges of their individual contexts, and to develop ideas for practice that
This study explored the nature of the relationship between a fifth-grade teacher and an informal science educator as they planned and implemented a life science unit in the classroom, and sought to define this relationship in order to gain insight into the roles of each educator. In addition, student learning as a result of instruction was assessed. Prior research has predominately examined relationships and roles of groups of teachers and informal educators in the museum setting (Tal et al. in Sci Educ 89:920–935, 2005 ; Tal and Steiner in Can J Sci Math Technol Educ 6:25–46, 2006 ; Tran 2007
This article describes a partnership between Seton Hall University and the Liberty Science Center to engage preservice teachers in teaching and learning science. The partnership program offered preservice teachers the opportunity to interact with displays and demonstrations, teach and interact with the public, participate in professional development activities, and communicate with diverse groups.
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Debra ZinicolaRoberta Devlin-Scherer
Many of the biggest problems facing the United States and the world require engineering expertise to solve: climate change, feeding a growing population, energy independence, access to clean water, crumbling infrastructure, and others. And with global economic competitiveness inextricably linked to innovation, employers across a wide range of engineering and non-engineering fields such as health care, management, and marketing are seeking employees with engineering knowledge and related skills. These skills include the ability to creatively and systematically solve ill-defined problems
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Community for Advancing Discovery Research in Education (CADRE)