Exploring public attitudes towards science helps investigate the images of science and what the social representations of science are. In this regard, science communication plays a crucial role in its different ways of addressing different publics.
As recognized by United Nations Secretary General Kofi Annan, the human community has reached a point in which it is faced with an array of choices that will determine the quality of our lives and the state of the global environment for present and future generations. One possibility is that at long last we will pave a path toward environmental stewardship and sustainable development. But it is also quite possible that we will travel a less enlightened course, running down the earth's natural capital and severely limiting the choices our descendants will face.
In this paper I use the concepts “understanding of science” and “appreciation of science” to analyze selected case studies of current science communication in Denmark. The Danish science communication system has many similarities with science communication in other countries: the increasing political and scientific interest in science communication, the co-existence of many different kinds of science communication, and the multiple uses of the concepts of understanding vs. appreciation of science. I stress the international aspects of science communication, the national politico-scientific
From exhibitions to theatrical performances, from fireworks to video games, countless events and ventures have been held all over the world in 2005 to mark the occasion of the World Year of Physics (WYP2005). The year that is drawing to a close has brought physics out into the streets and University campuses, but in a few cases physics has even invaded theater stages and art museums, it has involved musicians and even architects. The worldwide objective was to highlight a science that has more and more need to communicate its close connections with society, its involvement in themes that are
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TEAM MEMBERS:
Marzia MazzonettoMaria Chiara Montani
Science and technology: these are the mainstays China wants to concentrate on in order to stabilise its future as an emerging world power. Beijing plans to have the whole, enormous Chinese population literate in the scientific field within a few years. Scientific popularization is the key to what now, due to political influences and deep social disparities, seems remote.
The Nanoscale Informal Science Education Network (NISE Network) is a national infrastructure that links science museums and other informal science education organizations with nanoscale science and engineering research organizations. The Network’s overall goal is to foster public awareness, engagement, and understanding of nanoscale science, engineering, and technology. As part of the front-end effort, this report, Part IIB, documents 19 nanoscale STEM programming, media, and school-based projects that have been completed or are in development as of 2005.
In October 2005, the National Science Foundation brought members of its nanoscale science and engineering education (NSEE) projects to Arlington, VA for a 2-day workshop to explore the status of on-going efforts and to forge collaborations at the national level that would facilitate future efforts. NSF currently funds NSEE projects through the Division of Elementary, Secondary, and Informal Education (ESIE), the Directorate for Engineering as part of the Nanoscale Science and Engineering Centers (NSEC), National Nanotechnology Infrastructure Network (NNIN), the Network for Computational
This monograph, the final report of the 21st Century Literacy Summit held in April 2005, presents an action plan for this emerging field applicable to higher education, K-12 education, policy makers, media & the arts, and research, and details the strategic priorities and specific recommendations for these sectors that were the summit's major outcomes.
This collaborative project aims to establish a national computational resource to move the research community much closer to the realization of the goal of the Tree of Life initiative, namely, to reconstruct the evolutionary history of all organisms. This goal is the computational Grand Challenge of evolutionary biology. Current methods are limited to problems several orders of magnitude smaller, and they fail to provide sufficient accuracy at the high end of their range. The planned resource will be designed as an incubator to promote the development of new ideas for this enormously challenging computational task; it will create a forum for experimentalists, computational biologists, and computer scientists to share data, compare methods, and analyze results, thereby speeding up tool development while also sustaining current biological research projects. The resource will be composed of a large computational platform, a collection of interoperable high-performance software for phylogenetic analysis, and a large database of datasets, both real and simulated, and their analyses; it will be accessible through any Web browser by developers, researchers, and educators. The software, freely available in source form, will be usable on scales varying from laptops to high-performance, Grid-enabled, compute engines such as this project's platform, and will be packaged to be compatible with current popular tools. In order to build this resource, this collaborative project will support research programs in phyloinformatics (databases to store multilevel data with detailed annotations and to support complex, tree-oriented queries), in optimization algorithms, Bayesian inference, and symbolic manipulation for phylogeny reconstruction, and in simulation of branching evolution at the genomic level, all within the context of a virtual collaborative center. Biology, and phylogeny in particular, have been almost completely redefined by modern information technology, both in terms of data acquisition and in terms of analysis. Phylogeneticists have formulated specific models and questions that can now be addressed using recent advances in database technology and optimization algorithms. The time is thus exactly right for a close collaboration of biologists and computer scientists to address the IT issues in phylogenetics, many of which call for novel approaches, due to a combination of combinatorial difficulty and overall scale. The project research team includes computer scientists working in databases, algorithm design, algorithm engineering, and high-performance computing, evolutionary biologists and systematists, bioinformaticians, and biostatisticians, with a history of successful collaboration and a record of fundamental contributions, to provide the required breadth and depth. This project will bring together researchers from many areas and foster new types of collaborations and new styles of research in computational biology; moreover, the interaction of algorithms, databases, modeling, and biology will give new impetus and new directions in each area. It will help create the computational infrastructure that the research community will use over the next decades, as more whole genomes are sequenced and enough data are collected to attempt the inference of the Tree of Life. The project will help evolutionary biologists understand the mechanisms of evolution, the relationships among evolution, structure, and function of biomolecules, and a host of other research problems in biology, eventually leading to major progress in ecology, pharmaceutics, forensics, and security. The project will publicize evolution, genomics, and bioinformatics through informal education programs at museum partners of the collaborating institutions. It also will motivate high-school students and college undergraduates to pursue careers in bioinformatics. The project provides an extraordinary opportunity to train students, both undergraduate and graduate, as well as postdoctoral researchers, in one of the most exciting interdisciplinary areas in science. The collaborating institutions serve a large number of underrepresented groups and are committed to increasing their participation in research.
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TEAM MEMBERS:
Tandy WarnowDavid HillisLauren MeyersDaniel MirankerWarren Hunt, Jr.
Education is a lifelong endeavor; the public learns in many places and contexts, for a diversity of reasons, throughout their lives. During the past couple of decades, there has been a growing awareness that free‐choice learning experiences – learning experiences where the learner exercises a large degree of choice and control over the what, when and why of learning – play a major role in lifelong learning. Worldwide, most environmental learning is not acquired in school, but outside of school through free‐choice learning experiences. Included in this article are brief overviews of
This external evaluation of the PEEP Explorer's Guide found the Guide effective in meeting its goals. Teachers who used the Guide were extremely satisfied with its content, materials, and usability. They reported the Guide was highly appealing to children, and they used materials from the Guide to forge home-school connections. Teachers found the Guide made useful links between science, literacy, and language. Pre-post comparisons demonstrated that, while teachers were engaged in similar instructional practices before and after using the Guide, the Guide alleviated the challenges of teaching
Maine is a rural state with unequal access to computers and information technology. To remedy this, the Maine laptop program supplies iBooks to every seventh and eighth grade student in the state. The goal of EcoScienceWorks is to build on this program and develop, test and disseminate a middle school curriculum featuring computer modeling, simple programming and analysis of GIS data coupled with hands-on field experiences in ecology. The project will develop software, EcoBeaker: Maine Explorer, to stimulate student exploration of information technology by introducing teachers and students to simple computer modeling, applications of simulations in teaching and in science, and GIS data manipulation. This is a three-year, comprehensive project for 25 seventh and eighth grade teachers and their students. Teachers will receive 120 contact hours per year through workshops, summer sessions and classroom visits from environmental scientists. The teachers' classes will field test the EcoScienceWorks curriculum each year. The field tested project will be distributed throughout the Maine laptop program impacting 150 science teachers and 17,000 middle school students. EcoScienceWorks will provide middle school students with an understanding of how IT skills and tools can be used to identify, investigate and model possible solutions to scientific problems. EcoScienceWorks aligns with state and national science learning standards and integrates into the existing middle school ecology curriculum. An outcome of this project will be the spread of a field tested IT curriculum and EcoBeaker: Maine Explorer throughout Maine, with adapted curriculum and software available nationally.
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TEAM MEMBERS:
Walter AllanEric KlopferEleanor Steinberg