Argumentation in science involves the development, justification, and defence of evidence-based claims, together with the reasoned dispute of counterclaims. This process is the foundation for all scientific endeavours. Supporting the development of argumentation skills, therefore, is a key part of science education. Laboratory work is also as an essential part of science. Combining these two activities, therefore, would seem to be worthwhile. In this study, researchers explored the impact of three different lab-based tasks on the nature and quality of any subsequent argumentation.
When designing programs for science learning, it is important to consider that children's experiences with science begin years before they encounter science in the classroom. Children's developing understanding of science begins in their everyday activities and conversations about the natural and technical world. Children develop "scientific literacy" as they begin to learn the language of science (e.g., concepts such as "gravity" or "metamorphosis"), the kind of causal explanations that are used in scientific theories (e.g., the day-night cycle results from the rotation of the earth), and the
For children to achieve an understanding of science and of the ways of doing science, and for them to be motivated to use these ways in coping with, understanding, and enjoying the physical, biological, and social world around them, it is not enough that they believe that science is practically important. They must also be curious. Curiosity calls attention to interesting, odd, and sometimes important items in the drama that is revealed to us through our senses. Idle or purposeful, curiosity is the motor that interests children in science; it is also the principal motor that energizes and
Elementary school children are capable of reproducing sophisticated science process skills such as observing, designing experiments, collecting data, and evaluating evidence. An understanding of the nature of scientific knowledge requires more than teaching and learning the performance of these skills. It also requires an appreciation of how these actions lead to knowledge generation and shape its durable and tentative nature. Our understanding of activities that support the teaching and learning of the nature of scientific knowledge is still growing. This study compares how scientific
This study provides a historical overview of the development of the instructional television as a tool within the context of science education. The technology was traced from its beginning as experiments in public service broadcasting by universities and television networks, though closed circuit, cable, and commercially produced science-related programming. The use of the technology as a teaching tool is examined in terms of the concept of scientific literacy and the means by which instructional television helped to accomplish the goals of scientific literacy.
This poster from 2014 AISL PI Meeting describes a project that studies how 3-D visualizations can most effectively be used to improve public understanding of freshwater lake ecosystems and earth science processes.
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University of California, DavisGeoff Schladow
This poster was presented at the 2014 AISL PI Meeting in Washington, DC. It describes an EAGER project that conducts ongoing experiments on the chemical precursors to life as exhibit experiences in partner venues.
This project takes advantage of the charismatic nature of arachnids to engage the public in scientific inquiry, dialogue, and exploration. The project has two specific programs: (1) The development, implementation, and assessment of an informal museum event entitled 'Eight-Legged Encounters' which now has more than 25 associated activity stations. These activities encompass stations relating to (a) classification and systematics (e.g., 'What is an Arthropod', 'Create a Chelicerate', and 'Assemble an Arachnid'), (b) spider-specific stations focused on silk (e.g., 'Build a Burrow', 'Cribellate vs. Ecribellate Silk', 'Weave a Web', and 'Catch a Moth'), and (c) research related stations (e.g., 'Microscope Madness' and 'Community Experiment'). In addition, there is a stand-alone module entitled the 'Path of Predators' that includes an activity booklet and eleven stations that walk participants through the eleven living arachnid orders. Each stations has original artwork backdrops, clay sculptures, trading cards, and collectible stamps (participants place stamps on a phlylogenetic tree depicting the current hypothesis of evolutionary relationships among the eleven orders). Most stations have live animals and prizes are given to participants that complete their stamp booklet. 'Eight-Legged Encounters' has been hosted at the Nebraska State Museum (Morrill Hall) twice, with record-breaking attendance (>800 people in
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University of Nebraska-LincolnEileen Hebets
This guide provides techniques, tips, and best practices for citizen science practitioners who seek assistance in evaluating outcomes from their projects.
This poster was produced for the 2014 AISL PI Meeting held in Washington, DC. The Time Team America project's goal is to engage public audiences with the scientific process, STEM concepts, and STEM careers through the excitement of and active participation in archaeology.
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