The teaching of key scientific topics such as evolution are imperative for scientific literacy, but educators face pressure to eliminate or downplay these topics due to perceived controversy. Although teachers usually bear the burden of ensuring that these topics are taught appropriately, some of this responsibility must also fall upon…

Computational thinking is a contemporary science and engineering practice that has been introduced to the US science classrooms due to its emphasis in the "Next Generation Science Standards" (NGSS). However, including computational thinking into science instruction may be challenging. Therefore, for biological evolution (an essential…

Evolution offers an intellectually satisfying and extremely well-supported explanation for the diversity of life in the natural world, its similarities and differences, how changes occur and how new life forms have developed. There are plenty of reasons to anticipate the teaching of evolution with exhilaration. In recent years, the issue of…

Originally designed for K-12 teachers, the Understanding Evolution (UE) Web site ("www.understandingevolution.org") is a one-stop shop for all of a teacher's evolution education needs, with lesson plans, teaching tips, lists of common evolution misconceptions, and much more. However, during the past five years, the UE project team learned that…

Evolution curricula are replete with information about Darwin's theory of evolution as well as microevolutionary mechanisms underlying this process of change. However, other fundamental facets of evolutionary theory, particularly those related to macroevolution are often missing. One crucial idea typically overlooked is that of most recent common…

New science standards and reform recommendations spanning grades K--16 focus on a limited set of key scientific concepts from each discipline that all students should know. They also emphasize the integration of these concepts with science practices so that students learn not only the "what" of science but also the "how" and…

Cites five misconceptions related to the concept of belief which affect if and how evolution is taught. Suggests that the words 'believe' and 'accept' are used interchangeably by scientists. Discusses each of the misconceptions in detail. (Contains 33 references.) (DDR)

Suggests that misconceptions about natural selection arise from mistaken categorization. Proposes that students often fail to understand the ontological features of equilibrium processes. Contains 32 references. (DDR)

There are significant variances in both the religious and non-religious beliefs for rejecting evolution, and likewise diversity in the extent to which various creationists reject evolution. Describes the anti-evolution stances of literalists, progressives, and theists and addresses teaching concerns relative to anti-evolution positions. Contains…

Explains the misconceptions found in the traditional textbook presentation of the theory and the history of the theory of evolution. Outlines a more accurate and complete telling of the history of the discovery of evolution by natural selection. Contains 50 references. (DDR)

Uses interviews and a written questionnaire to probe students' ideas on the origin of earth and life on earth. A significant number of commonly held misconceptions were prevalent in the sample (N=493). Provides guidelines to assist learners in challenging existing views. Contains 64 references. (DDR)

Many science teachers recognize that teaching aspects of the history of science helps students learn science content and the nature of science (NOS). The use of history can potentially humanize science, help students refine their critical thinking skills, promote a deeper understanding of scientific concepts, and address common student…