Describes a course (Introduction to Numerical Techniques of Physics) which can be adapted to such courses as applied mathematics, numerical analysis, mechanical or electrical engineering, chemistry, and biomathematics. Course goals (including emphasis on the distinction between computing, programming and coding) and instructional strategies are…

Twelve papers focusing on various aspects of teaching chemistry to the nonchemist are presented. Includes details of courses designed around specific topics and/or needs (such as art hazards), use of field trips, issues related to the problem of explaining technical ideas to lay persons, and other topic areas. (JN)

Suggests general chemistry, organic chemistry, and biochemistry content for a two-semester, health-related, chemistry course sequence. Indicates that basic principles should be emphasized and that (when appropriate) these principles should be discussed with applications to health care. Other issues related to chemistry for health-related programs…

Provides rationale and objectives for presenting chemical reactions in a unified, logical six-stage approach rather than a piecemeal approach. Stages discussed include: introduction, stable electronic configurations and stable oxidation states, reactions between two free elements, ion transfer/proton transfer reactions, double displacement…

Discusses an audio-tutorial anatomy and physiology course which was no more expensive to establish and operate than a traditional course. Topics include development of audio-tutorial materials, construction of facilities, space use, staffing, development of computer programs, and computer costs. (Author/JN)

Discusses who takes college-level courses on solar energy; what material should be covered; sources of texts, outlines, curricula, and teaching aids; kinds of equipment needed; and science-, business-, and vocationally-oriented programs to prepare for such solar energy careers as design, research, education, and construction. (Author/JN)

Describes a two-quarter hour college chemistry course focusing on laboratory safety. Includes lists of topics/assignments, problem sets (toxicology, storage, and energy) and videotapes, films, and slide sets used in the course. (JN)

Describes the use and analysis of pretests/posttests for assessing instructional consequences in introductory college chemistry. Results from two studies (N=58 and N=136) are discussed as well as the use of pretests/posttests in helping instructors to identify course topics which need attention and improvement. (Author/JN)

Describes the first course of a new physics curriculum developed at the Karlsruke Institute for the Didactics of Physics. The basic idea, energy flow, is introduced at the beginning of the course and illustrated by examples from everyday life. Highlights selected topics which introduce concepts unique to the approach. (Author/JN)

Descriptions of high school chemistry courses are provided, including organic chemistry, introductory chemistry for mathematics-shy students, and a course for eighth-graders taught by high school seniors. (SK)

Describes the physics program at Saudi Arabia's University of Petroleum and Minerals, including the physics curriculum, examinations, and future plans. Includes comments on the development and operation of the University as a whole. (SK)

Suggestions are given for dealing with "senioritis" in high school students. These include offering college-level courses at a reduced cost. A description of introducing the college freshman biology course at Syracuse University into a high school program is given, with guidelines to promote success. (Author/SA)

The approach described in this article represents a combination of teaching techniques that were successful for a high school biology teacher. The process is described as shared decision making and the student becomes an active partner in the learning process. (Author/SA)

A course is described that is designed to encourage exploration, conceptual invention, and expansion of an idea. Results are given that relate to curricular experimentation with chemistry. (SA)

Describes a course, Chemistry for Elementary Education Majors, collaboratively planned and taught by chemistry and teacher education faculty. Discusses the instructional bases of the course, the audience, themes and activities in the course, course expenses, student learning, and challenges for the future. Lists the course schedule with lab and…