The last three decades have seen extensive reflection concerning how science communication should be modelled and understood. In this essay we propose the value of a cultural approach to science communication — one that frames it primarily as a process of meaning-making. We outline the conceptual basis for this view of culture, drawing on cultural theory to suggest that it is valuable to see science communication as one aspect of (popular) culture, as storytelling or narrative, as ritual, and as collective meaning-making. We then explore four possible ways that a cultural approach might
DATE:
TEAM MEMBERS:
Sarah DaviesMegan HalpernMaja HorstDavid KirbyBruce Lewenstein
As part of its overall effort 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 science, technology, engineering, and mathematics (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. In alignment with these aims, the STEM + Digital Literacies (STEM+L) project will investigate science fiction as an effective mechanism to attract and immerse adolescents (ages 10-13) from diverse cultural backgrounds in environmental and human health content and socio-scientific issues. This work is particularly novel, as the current knowledge base is limited, and largely addresses the high school level. Therefore, the results of the proposed effort could yield important findings regarding the feasibility of this activity as an effective platform for science learning and engagement for younger students. As such, STEM+L would not only advance knowledge in the field but would also contribute to a growing AISL portfolio on digital literacy and learning.
STEM+L is an early stage Innovations in Development project that will engage thirty middle school students in out of school time experiences. Over a twenty-four-week period, students will work collaboratively in groups in-person and online with their peers and field experts to design, develop, and produce STEM content rich, multimedia science fictions. The in-person learning experiences will take place on the University of Miami campus during the summer and academic year. Culminating activities include student presentations online and at a local Science Fiction Festival. The research component will employ an iterative, design-based approach. Four research questions will be explored: (a) How do students learn science concepts and multimodal digital literacies through participating in the STEM+L Academy? (b) How do students change their views in STEM related subject matter and in pursuing STEM related careers? (c) How do students participate in the STEM+L Academy? (d) How do we best support students' participation and learning of STEM+L in face-to-face and online environments? Data collection methods include video records, student-generated artifacts, online surveys, embedded assessments, interviews, and multimodal reflections. Comparative case analysis and a mixed methods approach will be employed. A rigorous evaluation will be conducted by a critical external review board. Inclusive and innovative dissemination strategies will ensure that the results of the research and program reach a broad range of audiences including both informal and formal STEM and literacy educators and researchers, learning scientists, local communities, and policy makers through national and international conference presentations, journal publications, Web2.0 resources, and community outreach activities.
Nowadays, India is experiencing a widespread diffusion of science communication activities. Public institutions, non-governmental organisations and a number of associations are busy spreading scientific knowledge not only via traditional media but also through specific forms of interaction with a varied public. This report aims to provide a historical overview of the diffusion of science communication in India, illustrating its current development and its future prospects.
The use of photography in the field of psychiatry is an eloquent example of the complex evolution of the relationship between science, communication and society. The research that follows analyses the development of such a relationship in a crucial period of the history of psychiatry: the 1970s. That was the time that witnessed the revolution of a science which admitted the failure of its methods and "instruments", mental hospitals. That was also the time when a profound change took place in the communicative methods of photography related to this uncertain field of knowledge. A group of
This poster was presented at the 2014 AISL PI Meeting. It describes the radio and stage storytelling programs undertaken by the Center for Chemical Evolution, a CCI jointly funded by NSF and NASA.
The investigators address a major educational challenge by introducing a novel format and content for science education, (a) building on past successes; (b) combining development and dissemination at a new level; and (c) centered around an interactive planetarium show aimed to inform the public on an emerging scientific discipline and medical field: Tissue Engineering. For achieving a multitude of goals, the investigators propose the establishment of a unique partnership in scientific and medical education, bringing together university researchers, clinical leaders, science center experts, and students, educators and community representatives at all levels. The project is catalyzed by the Pittsburgh Tissue Engineering Initiative, a non-profit organization dedicated to the promotion of tissue engineering and its application to improving people's lives. The main goals fall in three categories, as follows: Education: - To communicate scientific information about the human body (principles of function will be emphasized over specific facts or terminology by focusing on a limited but fundamental set). -To convey the excitement and importance of tissue engineering research. The show will utilize engaging interactive demonstrations of tissue functions and illustrate the medical uses and potential of this field. Innovation: - To enhance the educational experience. The developers will use group-interactive technology as a tool for education by engaging participants as participants in the processing functions of the body. A special visualization/interactivity laboratory will be used where prototype interactive scenarios will be tested using focus groups, consultants and representatives of the target audiences. Dissemination: - To insure national distribution to other planetaria. The presentation system will utilize portable interactive technology (to be developed). It will be deployed to planetaria throughout the country, coordinated by the Association of Science and Techology Centers (ASTC). - To engage the target audience in the development process. Content development will be achieved by a consortium of leading research universities and medical centers, with input from a panel of worldclass experts. Visualization, interactivity and sound technologies will be developed in Pittsburgh, in a unique collaboration between the arts and sciences, based on past successes. Evaluation activities will be extensive, as will the range and targets of the spin-off educational materials. The Carnegie Science Center planetarium itself will serve in achieving group immersive visualization, akin to virtual reality, for improving target audience involvement. The expected outcome is a new way of delivering educational content, and a better understanding of the emerging field of tissue engineering by the general public.