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
Focusing on climate change and its impact on coastal zones and marine life, Visualizing Change will build educator capacity in the aquarium community and informal science education field. Building on NOAA datasets and visualizations, we will provide interpreters with strategic framing communication tools and training using the best available social and cognitive research so that they can become effective climate change educators. Objectives are to (1) Develop and test four exemplary interpretive "visual narratives" that integrate research-based strategic communication with NOAA data visualization resources; (2) Test the application of the visual narratives in a variety of geographic regions, institution types (aquarium, science center, etc.), and using multiple technology platforms (Science on a Sphere, Magic Planet portable globe display, iPad/tablets, and video walls); (3) Build a professional development program for climate change interpretation with data visualization; and (4) Leverage existing networks for dissemination and peer support.
On March 14-15, 2013, representatives of eight members of Coastal America’s Coastal Ecosystem Learning Center (CELC) network met at the Aquarium of the Pacific in Long Beach, California. The primary goal of the workshop was to explore ways of energizing all, or portions, of the network to engage, educate, and empower the public on major coastal, ocean and environmental issues. The particular issue that was used as the point of departure was “Increasing Community Resilience to Extreme Weather-Related Events.” Support for the workshop was provided by the NOAA Office of Education.
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TEAM MEMBERS:
Jerry SchubelJerry EnzlerAllen MunroeThomas Schmid
This project will convene a workshop to develop a framework to support Coastal Ecosystem Learning Centers in delivering coordinated educational programming focused on weather-related events. The workshop will be organized by a collaborative group of aquariums and involve institutions from multiple regions of the United States. It will be held at the Aquarium of the Pacific in the winter or early spring of 2013.
The most important consideration in evaluating chemistry outreach efforts is how to best use the evaluation to serve project needs. Evaluation should be about making programs more effective—at communicating ideas, changing attitudes, inspiring action, or reaching wider audiences, for example. A well-conducted evaluation typically contributes to the quality of a project by helping its leaders better define their goals, identify important milestones and indicators of success, and use evidence to support ongoing improvements. At its best, evaluation is an integral part of project design and
This evaluator reflection was provided to stimulate conversation at the June 20-21, 2013 CAISE Evaluation Convening. It reflects on the nature of learning and challenges assumptions of outcomes from engaging in informal learning experiences.
This funder reflection was provided to stimulate conversation at the June 20-21, 2013 CAISE Evaluation Convening. It describes the importance of evaluation to funders, and provides some prompts and questions for thinking about evaluation with relation to funding.
This leadership reflection was provided to stimulate conversation at the June 20-21, 2013 CAISE Evaluation Convening. It provides an organizational leadership perspective on evaluation.
This practitioner reflection was provided to stimulate conversation at the June 20-21, 2013 CAISE Evaluation Convening. It discusses improving practice through reflection.
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.
Currently, many museums present histories of science and technology, but very few are integrating scientific activity--observation, measurement, experimentation-with the time- and place-specific narratives that characterize history-learning experiences. For the Prairie Science project, Conner Prairie is combining proven science center-style activities, developed by the Science Museum of Minnesota, with family-engagement strategies developed through extensive research and testing with audiences in historical settings. The goal of this integration is to create guest experiences that are rich in both STEM and historical content and encourage family learning. One key deliverable of this project is the Create.Connect gallery, which is currently installed at Conner Prairie. Create.Connect allows the project team to evaluate and research hands-on activities, facilitation strategies and historic settings to understand how these elements combine to encourage family conversations and learning around historical narratives and STEM content. For example, in one exhibit area families can experiment with creating their own efficient wind turbine designs while learning about the innovations of the Flint & Walling windmill manufacturing company from Indiana. The activity is facilitated by a historic interpreter portraying a windmill salesman from 1900. The interpreter not only guides the family though the process of scientific inquiry, but shares his historic perspective on wind power as well. Two other exhibit areas invite hands-on exploration of electrical circuits and forces in motion as they connect to stories from Indiana history. Evaluation and research findings from the Create.Connect exhibit will be used to develop a model that can guide other history institutions that want to incorporate STEM content and thinking into their exhibits and interpretation. By partnering with the Science Museum of Minnesota, we will combine the experience of science center professionals and history museum professionals to find the best practices for incorporating science activities into historic settings. To ensure that this dissemination model is informed from many perspectives, Conner Prairie has invited the participation of four history museums: The Museum of America and the Sea, Mystic, Connecticut; the California State Railroad Museum, Sacramento, California; the Wabash County Historical Society, Wabash, Indiana; and the Oliver H. Kelley Farm, Elk River, Minnesota. Each of the four participants will install history-STEM exhibit components which will be connected to location-specific historic narratives. Drawing on the staff experience and talents of participant museums, this project will develop realistic solutions to an array of anticipated barriers. These issues and the resulting approaches will become part of a stronger, more adaptable dissemination model that will support history museums in creating STEM-based guest experiences.
The University of Chicago's Yerkes Observatory, the National Radio Astronomy Observatory, the University of North Carolina, the Astronomical Society of the Pacific, and 4-H are collaborating to provide professional development to 180 4-H leaders and other informal science educators, and engage 1,400 middle school youth in using research-grade robotic telescopes and data analysis tools to explore the Universe. Youth participating in 4H-based out-of-school programs in Wisconsin, West Virginia and North Carolina are learning about the universe and preparing for STEM careers by conducting authentic astronomy research, completing astronomy-related hands-on modeling activities, interacting with astronomers and other professionals who are part of the Skynet Robotic Telescope Network, and interacting with other youth who part of the Skynet Junior Scholars virtual community. The project is innovative because it is providing a diverse community of 4-H youth (including sight- and hearing-challenged youth and those from underrepresented groups) with opportunities to use high-quality, remotely located, Internet-controlled telescopes to explore the heavens by surveying galaxies, tracking asteroids, monitoring variable stars, and learn about the nature and methods of science. Deliverables include (1) online access to optical and radio telescopes, data analysis tools, and professional astronomers, (2) an age-appropriate web-based interface for controlling remote telescopes, (3) inquiry-based standards-aligned instructional modules, (4) face-to-face and online professional development for 4-H leaders and informal science educators, (5) programming for youth in out-of-school clubs and clubs, (6) evaluation findings on the impacts of program activities on participants, and (7) research findings on how web-based interactions between youth and scientists can promote student interest in and preparedness for STEM careers. The evaluation plan is measuring the effectiveness of program activities in (1) increasing youths' knowledge, skills, interest, self-efficacy, and identity in science, including youth who are sight- and hearing-impaired, (2) increasing educators' competency in implementing inquiry-based instruction and their ability to interact with scientists, and (3) increasing the number of Skynet scientists who are involved in education and public outreach.