This poster was presented at the 2010 Association of Science-Technology Centers Annual Conference. The Saint Louis Science Center is a partner in Washington University's Cognitive, Computational, and Systems Neuroscience interdisciplinary graduate program funded by the NSF-IGERT (Integrative Graduate Education and Research Traineeship) flagship training program for PhD scientists and engineers.
This Integrative Graduate Education and Research Training (IGERT) award supports the establishment of an interdisciplinary graduate training program in Cognitive, Computational, and Systems Neuroscience at Washington University in Saint Louis. Understanding how the brain works under normal circumstances and how it fails are among the most important problems in science. The purpose of this program is to train a new generation of systems-level neuroscientists who will combine experimental and computational approaches from the fields of psychology, neurobiology, and engineering to study brain function in unique ways. Students will participate in a five-course core curriculum that provides a broad base of knowledge in each of the core disciplines, and culminates in a pair of highly integrative and interactive courses that emphasize critical thinking and analysis skills, as well as practical skills for developing interdisciplinary research projects. This program also includes workshops aimed at developing the personal and professional skills that students need to become successful independent investigators and educators, as well as outreach programs aimed at communicating the goals and promise of integrative neuroscience to the general public. This training program will be tightly coupled to a new research focus involving neuro-imaging in nonhuman primates. By building upon existing strengths at Washington University, this research and training initiative will provide critical new insights into how the non-invasive measurements of brain function that are available in humans (e.g. from functional MRI) are related to the underlying activity patterns in neuronal circuits of the brain. IGERT is an NSF-wide program intended to meet the challenges of educating U.S. Ph.D. scientists and engineers with the interdisciplinary background, deep knowledge in a chosen discipline, and the technical, professional, and personal skills needed for the career demands of the future. The program is intended to catalyze a cultural change in graduate education by establishing innovative new models for graduate education and training in a fertile environment for collaborative research that transcends traditional disciplinary boundaries.
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TEAM MEMBERS:
Kurt ThoroughmanGregory DeAngelisRandy BucknerSteven PetersenDora Angelaki
This is an efficacy study through which the Denver Museum of Nature and Science, the Denver Zoo, the Denver Botanic Gardens, and three of Denver's urban school districts join efforts to determine if partnerships among formal and informal organizations demonstrate an appropriate infrastructure for improving science literacy among urban middle school science students. The Metropolitan Denver Urban Advantage (UA Denver) program is used for this purpose. This program consists of three design elements: (a) student-driven investigations, (b) STEM-related content, and (c) alignment of schools and informal science education institutions; and six major components: (a) professional development for teachers, (b) classroom materials and resources, (c) access to science-rich organizations, (d) outreach to families, (e) capacity building and sustainability, and (e) program assessment and student learning. Three research questions guide the study: (1) How does the participation in the program affect students' science knowledge, skills, and attitudes toward science relative to comparison groups of students? (2) How does the participation in the program affect teachers' science knowledge, skills, and abilities relative to comparison groups of teachers? and (3) How do families' participation in the program affect their engagement in and support for their children's science learning and aspirations relative to comparison families?
The study's guiding hypothesis is that the UA Denver program should improve science literacy in urban middle school students measured by (a) students' increased understanding of science, as reflected in their science investigations or "exit projects"; (b) teachers' increased understanding of science and their ability to support students in their exit projects, as documented by classroom observations, observations of professional development activities, and surveys; and (c) school groups' and families' increased visits to participating science-based institutions, through surveys. The study employs an experimental research design. Schools are randomly assigned to either intervention or comparison groups and classrooms will be the units of analysis. Power analysis recommended a sample of 18 intervention and 18 comparison middle schools, with approximately 72 seventh grade science teachers, over 5,000 students, and 12,000 individual parents in order to detect differences among intervention and comparison groups. To answer the three research questions, data gathering strategies include: (a) students' standardized test scores from the Colorado Student Assessment Program, (b) students' pre-post science learning assessment using the Northwest Evaluation Association's Measures for Academic Progress (science), (c) students' pre-post science aspirations and goals using the Modified Attitude Toward Science Inventory, (d) teachers' fidelity of implementation using the Teaching Science as Inquiry instrument, and (e) classroom interactions using the Science Teacher Inquiry Rubric, and the Reformed Teaching Observation protocol. To interpret the main three levels of data (students, nested in teachers, nested within schools), hierarchical linear modeling (HLM), including HLM6 application, are utilized. An advisory board, including experts in research methodologies, science, informal science education, assessment, and measurement oversees the progress of the study and provides guidance to the research team. An external evaluator assesses both formative and summative aspects of the evaluation component of the scope of work.
The key outcome of the study is a research-informed and field-tested intervention implemented under specific conditions for enhancing middle school science learning and teaching, and supported by partnerships between formal and informal organizations.
This research oriented project integrates the informal and formal science education sectors, bringing their combined resources to bear on the critical need for well-prepared and diverse urban science teachers. It represents a partnership among The City College of New York (CCNY), the New York Hall of Science (NYHOS), and the City University of New York Center for Advanced Study in Education (CUNY-CASE). It integrates the Science Career Ladder, a sustained program of informal science teaching training and employment at the NYHOS, with the CCNY science teacher preparation program. The longitudinal and comparative research study being conducted is designed to examine and document the effect of this integrated program on the production of urban science teachers. Outcomes from this study include a new body of research related to the impact of internships in science centers on improving classroom science teaching in urban high schools. Results are being disseminated to both the informal science education community (through the Association for Science and Technology Centers and the Center for Informal Learning in Schools, an NSF supported Center for Learning and Teaching situated at the San Francisco Exploratorium) and the formal education community (through the National Science Teachers Association and the American Educational Research Association).
The Science Career Ladder program engages undergraduates as inquiry-based interpreters (Explainers) for visitors to the NY Hall of Science. Integrating this experience with a formal teacher certification program enables participants to coordinate experiences in the science center, college science and education classes, and K-12 classrooms. Participants receive a license to teach science upon graduating. The approach has its theoretical underpinnings in the concept of situated learning as noted by Kirshner and Whitson (1997, Situated Cognition: Social, Semiotic and Psychological Perspectives, Mahwah, NJ: Erlbaum). Through apprenticeship experiences, situated learning recreates the complexity and ambiguity of situations that learners will face in the real world. Science centers provide a potentially ideal setting for situational learning by future teachers, allowing them to develop, exercise and refine their science teaching and learning skills as noted by Gardner (1991, The Unschooled Mind, New York: Basic Books).
There is a well-documented shortage of science teachers in urban school districts. The causes of this shortage relate to all phases of the teacher professional continuum, from recruitment through training and retention. At the same time, the demographic composition of American teachers is increasingly out of synch with the demographics of the student population, raising concerns that a critical shortage of role models may be at hand, contributing to a worsening situation in urban schools. In the face of these challenges many innovative teacher recruitment and teacher preparation programs have been developed to augment traditional pathways to teaching. These programs range from high school academies for students expressing an interest in teaching to the recruitment and training of individuals making mid-life career changes. The CLUSTER program described above represents a new alternative. There are more than 250 science centers in the United States. Many of these have extensive youth internship programs and collaborative relationships with local colleges. Therefore, the proposed model is widely applicable.
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.
The school field trip constitutes an important demographic market for museums. Field trips enlist the energies of teachers and students, schools and museums, and ought to be used to the best of their potential. There is evidence from the literature and from practitioners that museums often struggle to understand the needs of teachers, who make the key decisions in field trip planning and implementation. Museum personnel ponder how to design their programs to serve educational and pedagogical needs most effectively, and how to market the value of their institutions to teachers. This paper
The Dynamic Earth: You Have To See it To Believe It is a public exhibition and suite of programming designed to educate and excite K-8 students, teachers, and families about weather and climate science, plate tectonics, erosion, and stream formation. The Dynamic Earth program draws attention to the importance of large-scale earth processes and the human impacts on these processes, utilizing real artifacts, hands-on models, and NASA earth imagery and data. The program includes the exhibition, student workshops, family workshops, annual professional development opportunities for classroom teachers, innovative theater shows, lectures for adults by visiting scientists, and interpretive activities. The Montshire Museum of Science has partnered with Chabot Space and Science Center (CA) and the US Army Corps of Engineers Cold Regions Research and Engineering Laboratory (NH) on various components. The project has broadened our internal capacity for providing quality earth science programming by greatly expanding our program titles and allowing us to create hands-on materials for use by our educators and to loan to schools in our Partnership Initiative. Programming developed during the grant period continues to reach thousands of students and teachers each year, both on-site and as part of our rural outreach efforts.
The primary purpose of the STARS: Strengthening Teaching, Awareness and Resources in Science project from the Challenger Learning Center of the San Joaquin Valley is to build upon the CLC's resources and partnership in order to maximize the impact of informal science education in creating a STEM pipeline for the San Joaquin Valley region. The goals are to promote lifelong learning among the general public regarding STEM fields and NASA's contribution to American society through a series of high-profile community events, strengthen K-12 partnerships to ensure the long-term utilization of the CLC as a STEM education resource, and further develop the CLC's partnership with the University of California Merced to ensure continuity of the STEM pipeline from K-12 to higher education, integrating informal science education to inspire students to pursue STEM learning throughout this progression.
The NASA Science Research Mentoring Program (NASA SRMP) is an established mentoring program that presents the wonders of space exploration and planetary sciences to underserved high school students from New York City through cutting-edge, research-based courses and authentic research opportunities, using the rich resources of the American Museum of Natural History. NASA SRMP consists of a year of Earth and Planetary Science (EPS) and Astrophysics electives offered through the Museum’s After School Program, year-long mentorship placements with Museum research scientists, and summer programming through our education partners at City College of New York and the NASA Goddard Institute for Space Studies. The primary goals of the project are: 1) to motivate and prepare high school students, especially those underrepresented in science, technology, engineering and math (STEM) fields, to pursue STEM careers related to EPS and astrophysics; 2) to develop a model and strategies that can enrich the informal education field; and 3) to engage research scientists in education and outreach programs. The program features five in-depth elective courses, offered twice per year (for a total of 250 student slots per year). Students pursue these preparatory courses during the 10th or 11th grade, and a select number of those who successfully complete three of the courses are chosen the next year to conduct research with a Museum scientist. In addition to providing courses and mentoring placements, the program has produced curricula for the elective courses, an interactive student and instructor website for each course, and teacher and mentor training outlines.
Laurel Clark Earth Camp was a set of interconnected programs for Middle and High School students and their teachers that help them develop new perspectives on global change. The project was a partnership of the Arizona-Sonora Desert Museum, Arizona Project WET at the University of Arizona, and the Planetary Science Institute in Tucson, Arizona. Project goals were to: I. Engage students in lifelong learning in STEM disciplines to inform their Earth stewardship practices, career decisions and capacity for innovation; II. Provide teachers with tools and experiences to inspire students to discover the real-world relevancy of STEM disciplines and apply this learning to the pursuit of STEM careers and technological innovation; III. Enhance public awareness of environmental change in the southwestern US and the importance of NASA satellites for recording, understanding and predicting these changes. Over four years, Earth Camp served 132 students and 42 teachers. Program participants understand more about Earth System connectivity and are more aware of their impacts on the environment and how to quantify and reduce these impacts. A post-camp online survey of alumni from previous years indicated that 75% of participants were felt that the camp influenced them to be more interested in STEM careers and 80% were more motivated to do well in their science classes. Teachers in the program were able to implement many of the project activities in their classrooms and most of them were exposed to satellite data for the first time; The project also created a public exhibit “Earth Change from Space” at the Arizona-Sonora Desert Museum, and an online tool that allowed students to explore, research and report on global change issues using Google Earth historical imagery.
The Children’s Museum developed From the Blue Planet to the Red Planet: Exploring Planetary Science to provide opportunities for students in grades 4 through 8, teachers, and families to learn about Mars exploration. The Museum partnered with the Connecticut Center for Advanced Technology (CCAT) on four teacher professional development modules related to aspects of planetary science: soil and plant study, air pressure, robotic exploration, and the comparison of Mars and Earth. Teachers who attended free workshops could bring students to the Museum for classroom and planetarium experiences. The Museum received support from Central Connecticut State University and technical advice from Phoenix Project scientists at JPL. The Museum created a timeline of Mars exploration history with video clips of milestones and an accompanying quiz kiosk. CCAT created virtual Mars drive-through experiences with which visitors could explore the planet. The Travelers ScienceDome Planetarium staff wrote, directed, and animated a full-dome planetarium program about the future study of Mars that was finished in December 2012. For over two years the Museum has sponsored free, monthly Mars Madness programs during which the general public can visit the exhibit, see a Mars-related planetarium program, and test out some of the hands-on activities developed for the school groups. The Museum hoped to reach a diverse audience, especially, those people who might otherwise not afford admission. We have produced four teacher professional development guides with hands-on activities, an exhibit for our facility, a dedicated website, and a planetarium program.
Earth from Space highlights state-of-the-art NASA technology, in particular, the suite of Earth observing satellites orbiting our planet, the data they collect, and how people are using these data for research and applications. Participants learn how NASA EOS data is collected through remote sensing systems, recognize the connection between this data and the area in which they live, and recognize the relevance and value of NASA data for understanding changes in the Earth related to where they live. The project informs K–12 students and lifelong learners of our increasingly advanced technological society and prepare students to enter the STEM-related workforce with content in oceanography, geology, climatology, glaciology, geography, and meteorology. Content is presented through hands-on exhibits and dynamic demonstrations using spherical display systems at OMSI’s main museum location and through a travelling program at rural libraries, schools, and other outreach venues throughout Oregon.