As part of its overall strategy to enhance learning in informal environments, the Advancing Informal STEM Learning (AISL) program seeks to advance new approaches to, and evidence-based understanding of, the design and development of STEM learning in informal environments. This includes providing multiple pathways for broadening access to and engagement in STEM learning experiences, advancing innovative research on and assessment of STEM learning in informal environments, and developing understandings of deeper learning by participants. The Museum of Science, Boston (MOS) and Boston University (BU) will conduct a Pilot and Feasibility Study project that leverages the current Living Laboratory (LL) model and expand it to engage high school students (teens) in experimental psychology research, science communication and science education activities. In LL, which is now an extensive network of museums and university researchers across the country, scientists and museum staff collaborate to engage children in studies on the museum floor and educate caregivers about the research. Multi-site implementation and evaluation of LL has also documented positive impacts for undergraduate researchers. Many sites are eager to extend these benefits to high school students by engaging them as practitioners within the model and by providing them with opportunities to engage in current research, education and communication, thereby helping to foster stronger youth identities with science and its applications in society. This project expands a ten-year LL partnership between MOS and BU to: 1) pilot a program in which high school students both conduct scientific research and engage the public in learning about science; 2) explore strategies for museums and universities to collaboratively engage, support and mentor high school students in science research, communication and education activities; 3) document curricular, other programmatic, and evaluation materials; and 4) convene professional participants to provide feedback on pilot materials, and assess the viability of implementing similar programs at additional sites. Guided by developmental evaluation, these activities will generate knowledge for the field, and act to increase professional capacity to integrate experiences for teens at multiple LL sites in future projects. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
The article proposes a reflection on science communication and on the communicative processes characteristic to the production of new-found knowledge. It aims to outline the role that sociology can play within this frame for greater understanding. The article first defines the main evolutionary trends in scientific research in recent decades, with particular reference to the emergence of new social actors. Following on from this, it will look at some of the epistemological conditions that may strengthen the sociologist's role in the cognition of scientific production. Using this as a premise
At the beginning of the new millennium, science is not only a neutral system or an objective methodology of knowledge, but also the implicit basis of the totality of our culture. Though science and its derivates are omnipresent in daily life, its basic ideologies and functional mechanisms are in most cases not fully visible to the subject. In using the most evolved systematical-critical model of psychoanalysis provided by the French thinker Jacques Lacan (1901-1981), an enlightening analysis of western science can be made, which contributes not only to a better understanding of its own
Peer review is the evaluation method that has characterized the scientific growth of the last four centuries, the first four of what is called modern science, indeed. It is matter of scientific communication inside scientific community, a subject too poorly studied in comparison with its critical importance for a scientific study of science (science of science). Peer review has been used for scientific paper evaluation before publication (editorial peer review) and for research proposal evaluation before financial support (grants peer review). Both cases present similar pros and cons, so I
This poster was presented at the 2014 AISL PI Meeting in Washington, DC. This project seeks to improve public engagement in climate communication by broadcast meteorologists, using scientific methods to identify probable causes for their skepticism and/or reticence, and to test the efficacy of proposed solutions.
In order to broaden the conceptualizations of argument in science education, Bricker and Bell draw from diverse fields: the sociology of science, the learning sciences, and cognitive science to help practitioners think of new ways to bring argumentation into learning spaces while expanding what counts as scientific argument.
The notion that science is unified in one way or another dates back at least to Aristotle, though unity claims since then have been diverse and va riously motivated. By way of introduction to the modern discussion of unity, disunity, and integration, in this first section we examine five historical attempts to unify knowledge: Aristotle’s metaphysical and hierarchical unity; the Enlightenment project of the French Encyclopedists; the systematic unity of Naturphilosophen Lorenz Oken; the methodological unity of the Vienna School’s Encyclopedia of Unified Science; and finally, the organizational
Archaeology education activities in informal science learning settings are an underutilized, but effective strategy for teaching science inquiry skills in socially and culturally relevant contexts. This project investigated the potential for archaeological content and inquiry strategies to help informal science learning institutions increase learning with diverse ISE audiences. The project was based on foundational research for the development of a national research framework for archaeology education and a plan for developing high-quality science learning opportunities for under-represented
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TEAM MEMBERS:
Michael BrodyJohn FisherJeanne MoeHelen Keremedjiev
In the United States, African Americans are underrepresented in science careers and underserved in pre-collegiate science education. This project engaged African American elementary students in culturally relevant science education through archaeology and thereby increased positive dispositions toward science. While imagining what the lives of their ancestors were like, students practiced scientific inquiry and used natural sciences to analyze archaeological sites. The project helped to improve science literacy among African American elementary students through archaeological inquiry and
This paper lays out a theory of (re-)generative learning to explain how families and communities socialize young learners into thinking like scientists and mathematicians. Cultural communities and their families orient their young in varied ways toward the language, behaviors, and self-theories about the future presupposed in the learning of science and mathematics. Certain socialization processes and norms correspond closely with those that scientists and artists use in laboratories, studios, and rehearsals. Certain norms of politeness and patterns of language differ significantly from habits
Women have made tremendous progress in education and the workplace during the past 50 years. Even in historically male fields such as business, law, and medicine, women have made impressive gains. In scientific areas, however, women’s educational gains have been less dramatic, and their progress in the workplace still slower. In an era when women are increasingly prominent in medicine, law, and business, why are so few women becoming scientists and engineers? This study tackles this puzzling question and presents a picture of what we know—and what is still to be understood—about girls and
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TEAM MEMBERS:
Catherine HillChristianne CorbettAndresse St. Rose
This paper is birthed from my lifelong experiences as student, teacher, administrator, and researcher in urban science classrooms. This includes my years as a minority student in biology, chemistry, and physics classrooms, 10 years as science teacher and high school science department chair, 5-years conducting research on youth experiences in urban science classrooms, and current work in preparing science teachers for teaching in urban schools. These experiences afford me both emic and etic lenses through which to view urban science classrooms and urban youth communities. This paper, both