This paper contributes a theoretical framework informed by historical, philosophical and ethnographic studies of science practice to argue that data should be considered to be actively produced, rather than passively collected. We further argue that traditional school science laboratory investigations misconstrue the nature of data and overly constrain student agency in their production. We use our “Data Production” framework to analyze activity of and interviews with high school students who created data using sensors and software in a ninth-grade integrated science class. To understand the
Learn how to create opportunities for young people from low-income, ethnically diverse communities to learn about growing food, doing science, and how science can help them contribute to their community in positive ways. The authors developed a program that integrates hydroponics (a method of growing plants indoors without soil) into both in-school and out-of-school educational settings.
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.
The "Mentored Youth Building Employable Skills in Technology (MyBEST)" project, a collaboration of the Youth Science Center (YSC) and Learning Technology Center (LTC) at the Science Museum of Minnesota, is a three-year, youth-based proposal that seeks to engage 200 inner-city youngsters in learning experiences involving information and design technologies. The goal of the project is to develop participants' IT fluency coupled with work- and academic-related skills. The program will serve students in grades 7 through 12 with special emphasis on three underrepresented groups: girls, youngsters of color, and the economically disadvantaged. Project participants will receive 130 contact hours and 70% will receive at least 160 hours. Each project year, including summers, students participate in three seasons consisting of five two-week cycles. Project activities will center on an annual technology theme: design, engineering and invention; social and environmental systems; and networks and communication. The activities that constitute project seasons include guest presenter workshops; open labs facilitated by guest presenters, mentors and adult staff; presentations of student projects; career workshops and field trips. The project cycles feature programming (e.g., Logo computer language; Cricketalk), engineering and multi-media production (e.g., digital video; non-linear editing software). Each cycle will interface with an existing museum-related program (e.g., the NSF-funded traveling Cyborg exhibit). Mentors will work alongside participants in all technology-based activities. These mentors will be recruited from university, business, community partners and participant families. Leadership development is addressed through teamwork and in the form of internships and externships. Participants obtain work experience related to technology in the internship and externship component. The "MyBEST" project will serve as a prototype for the Museum to test the introduction of technology as central to the design and learning outcomes of its youth-based programs. An advisory board reflecting expertise in youth development, technology and informal science education will guide the program's development and plans for sustainability. Core elements of the "MyBEST" program will be integrated into the Museum's youth-based projects sponsored by the YSC and LTC departments. The Museum has a strong record of integrating prototype initiatives into long-standing programs.
Elementary school children are capable of reproducing sophisticated science process skills such as observing, designing experiments, collecting data, and evaluating evidence. An understanding of the nature of scientific knowledge requires more than teaching and learning the performance of these skills. It also requires an appreciation of how these actions lead to knowledge generation and shape its durable and tentative nature. Our understanding of activities that support the teaching and learning of the nature of scientific knowledge is still growing. This study compares how scientific
The Youth Astronomy Apprenticeship (YAA) is a yearlong, out-of-school time initiative that connects urban teenage youth with astronomy as an effective way to promote scientific literacy and overall positive youth development. The program employs the strategies of a traditional apprenticeship model, common in crafts and trades guilds as well as in higher education. During the apprenticeship, youth develop knowledge and skills to create informal science education projects: through these projects they demonstrate their understanding of astronomy and use their communication skills to connect to
This article describes the mission, approach and success of the New Jersey Academy of Aquatic Sciences' Community and Urban Science Enrichment Program (CAUSE). Through the CAUSE program, local high school students receive training in marine science and biology, and work as mentors for younger students and as educators. This article also points out that an enrichment program to increase visitorship from underrepresented youth is not enough; science centers must utilize Positive Youth Development (PYD) strategies to "lay the foundation" toward individual learning. Key findings from project
EdVenture Children's Museum, a hands-on, children's museum in Columbia, S.C., in close collaboration with NIH-funded researchers at the University of South Carolina, proposes a five-year, SEPA project titled "Unlocking the Mysteries of Chronic Diseases: BioInvestigations for Family, School and Youth Audiences." The program will develop teaching laboratories and experiments to educate youth ages 5-14, teens and adults about biomedical science topics in a fun, investigatory way. From these laboratory experiences, EdVenture will also develop educational programs designed to engage disadvantaged audiences in schools and communities to help expose them to the world of science and the benefits of community-based translational research. The laboratories and educational programs will utilize scientific content drawn from NIH-sponsored biomedical research, and will translate the research process and public impact into meaningful experiences for the public. These programs will reach a large population, both urban and rural, in socio-economically depressed areas of the state, promoting students' interest in topics that they may not otherwise be exposed to and encouraging a lifelong familiarity and facility with scientific thought and practice. Throughout the life expectancy of this project, a projected 2.5 million children and adults will experience the laboratories and related educational programs. Long-term goals are to encourage future biomedical science career choices, and most importantly, empower a child to take control over his/her own health decisions and to develop the necessary skills to navigate the flood of health information inherent in the quickly changing landscape that is health today.
The overall goal of the current proposal is to adapt the interdisciplinary research-based curriculum created at the School for Science and Math at Vanderbilt (SSMV) for implementation of a four-year program in three Metropolitan Nashville Public School (MNPS) high schools. The specific aims of the proposal are to adapt the on-campus (at Vanderbilt) model for implementation in three public high schools with different academic profiles (SSM Academies); to define the variables and features required to sustain the program and to replicate the model in any high school setting; and to define a strategy for disseminating the model to additional schools. Students entering 9th grade in a school in which an SSM Academy has been implemented will be encouraged to apply. Those who are accepted into the program will spend three hours every other day in two courses based on the adapted curriculum. As with the SSMV, rising seniors will have opportunities to enter Vanderbilt laboratories for summer research internships. Teachers from the high school will work with Center for Science Outreach scientists to adapt the SSMV curriculum for implementation. Ongoing, year-long teacher professional development will be conducted to ensure that the curriculum is dynamic and the teachers are well-prepared to engage and guide the students in the curriculum. The anticipated outcomes include enhanced student achievement as measured by GPA, and scores on ACT science reasoning and end of course tests; increased SSM student interest in careers in science; increased district-wide enrollment in SSM programs; increased graduation rates and postsecondary education enrollment by SSM students; development of unique curricular science units that can be adapted for a novel four-year interdisciplinary research- based curriculum; development of a sustainable model built on effective features of each SSM that can be exported to other high schools within and outside Nashville; enhanced community and family involvement in the SSM programs and school community in general; a strengthened partnership between Vanderbilt and MNPS that will serve as a national model of a successful university-K-12 collaboration to enhance science teaching and learning.
Having developed the concept of near-peer mentorship at the middle school/high school level and utilized it in a summer science education enhancement program now called Gains in the Education of Mathematics and Science or GEMS at the Walter Reed Army Institute of Research (WRAIR), it is now our goal to ultimately expand this program into an extensive, research institute-based source of young, specially selected, near-peer mentors armed with kits, tools, teacher-student developed curricula, enthusiasm, time and talent for science teaching in the urban District of Columbia Public Schools (specific schools) and several more rural disadvantaged schools (Frederick and Howard Counties) in science teaching. We describe this program as a new in-school component, involving science clubs and lunch programs, patterned after our valuable summer science training modules and mentorship program. Our in-house program is at its maximum capacity at the Institute. Near-peer mentors will work in WRAIR's individual laboratories while perfecting/adapting hands-on activities for the new GEMS-X program to be carried out at McKinley Technology HS, Marian Koshland Museum, Roots Charter School and Lincoln Junior HS in DC, West Frederick Middle School, Frederick, MD and Folly Quarter Middle School and Glenelg HS, in Howard County, MD. Based on local demographics in these urban/rural areas, minority and disadvantaged youth, men and women, may choose science, mathematics, engineering and technology (SMET) careers with increasing frequency after participating, at such an early age, in specific learning in the quantitative disciplines. Many of these students take challenging courses within their schools, vastly improve their standardized test scores, take on internship opportunities, are provided recommendations from scientists and medical staff and ultimately are able to enter health professions that were previously unattainable. Relevance to Public Health: The Gains in the Education of Mathematis and Science (GEMS) program educates a diverse student population to benefit their science education and ultimately may improve the likelihood of successfully entry into a health or health-related professions for participating individuals. Medical education has been show to improve public health.
The long-term goal is to broaden our model program that currently targets African-American populations in the national capital area. The aim of the program is to: a) educate junior and senior high students and elementary school teachers directly; and b) provide opportunities for exploration of health-related sciences for the public at large (via an interactive website) so that topics in the biomedical sciences become "friendly and familiar" rather than the existing stereotype that science is erudite, obtuse, and incomprehensible. Specific objectives: (A) Design hands-on experiences in science laboratories and opportunities to interact with scientists in the setting of a sophisticated research institute; especially target under-represented minorities, students from inner city schools and other local schools where science opportunities may be limited. This will include junior and high school students, elementary school teachers, as well as interactions with Children's Museum and other similar organizations. (B) Set up interactive web-based informatics to include: i) a system where high school students could refine the question they are posing for science projects by discussing it with a professional scientist; ii) a general "ask-the-expert" site for science and health issues; iii) a reference site containing the detailed experimental protocols for student experiments; and iv) an interactive resource to aid teachers throughout the U.S. to establish contacts with scientists. The goal of this project is to extend the reach of current health science programs that are targeted to females, African-American junior and senior high school students, and elementary school teachers, located in the Washington, D.C., metropolitan area. The project includes laboratory apprenticeships, student mentoring, and an interactive website to help students and teachers establish contact with scientists nationwide.
This dissertation examined changes in urban youth’s attitude towards science as well as their perception of the informal science education setting and third space opportunity provided by the BioBus, a mobile science lab. Findings from this study suggested that urban youth’s attitude towards science changed both positively and negatively in statistically significant ways after a BioBus visit and that the experience itself was highly enjoyable. Furthermore, implications for how to construct a third space within the urban science classroom and the merits of utilizing the theoretical framework