Examines various issues related to the establishment of a core of physics studies at 16+ and 18+. Indicates that a core physics syllabus should be concerned with phenomena, theory, models, and applications and not with such topics as the use of a U tube manometer. (JN)

If science can be taught in a way that makes it accessible to the nonmajor, student fear of science would decrease. The topic of memory allows for an interdisciplinary analysis because films can be selected to complement the science. A course at Brooklyn College is described. (MLW)

Papers presented include: (1) CORE science--an exploratory study of pupils' perceptions of their science course; (2) chemistry and science philosophy; (3) taxonomy of scientific words (focusing on language of science, science words, theories of meaning, uses/implications of the taxonomy); and (4) description of experimental studies, a 16+ work…

A teacher's viewpoints and comments on the core syllabus for A-level physics which appeared in the May 1980 issue of "Physics Education" are presented. (SK)

Summarizes a university professor's viewpoints and comments on the advantages and disadvantages of the core syllabus for A-level physics presented in the May 1980 issue of "Physics Education." (SK)

Summarizes the viewpoints and comments of a science educator on the core syllabus for A-level physics which appeared in the May 1980 issue of "Physics Education," including the nature of the syllabus, its lack of clarity or detail, and its lack of scope. (SK)

This guide, developed for the chemistry 200, 300 program in Manitoba, is designed to articulate with previous science courses, provide concepts, processes, and skills which will enable students to continue in chemistry-related areas, and relate chemistry to practical applications in everyday life. It includes a program overview (with program goals…

States the viewpoints of the Physics Interface Project (PIP) on the core syllabus for A-level physics presented in the May 1980 issue of "Physics Education," including potential problems with the syllabus and its content. Indicates that PIP materials will serve an important complementary function in physics instruction. (SK)

Presents a headmaster's viewpoints and comments on the core syllabus for A-level physics which appeared in the May 1980 issue of "Physics Education," including the necessity for instructional materials, in-service teacher learning, and feasibility studies. (SK)

A university lecturer comments on the importance of adequate detail and individual interpretations of items in the core syllabus for A-level physics presented in the May 1980 issue of "Physics Education." Suggests that the syllabus fails in containing all essential elementary ideas necessary to master advanced concepts. (SK)

This guide, developed for the physics 200, 300 program in Manitoba, is designed to articulate with previous science courses; provide concepts, processes, and skills which will enable students to continue in physics-related areas; and relate physics to practical applications in everyday life. It includes a program overview (with program goals and…

Lists polymer chemistry topics and depth of topics to be covered in general chemistry courses. Also lists topics using polymers as tools for delivering necessary concepts, discussing 11 topic areas. List of readings, information on textbook evaluation, and illustrative examination questions are included. (JN)

Supporting the concept of a core syllabus, the Council of Engineering Institutions (CEI) suggests that this syllabus for A-level physics, described in the May 1980 issue of "Physics Education," occupy 65 percent to 70 percent of instructional time and that an applied physics approach with relevance to everyday life be used. (SK)

This document consists of a workshop presentation on the development of a new engineering science core curriculum at Arizona State University (ASU). Part 1 presents an overview of the project, which was designed to return a true commonality to the engineering science core and increase understanding of fundamental concepts by reinserting design…

This syllabus is organized into 17 sections (or "maps") which focus on these topic areas: the earth in the universe; variety and adaptation; reproduction; growth; food and feeding; sensitivity; microscopic living things; movement, forces, and structures; heat; light and color; sound; magnets and magnetism; electricity; water and other…