This publication presents examples of inquiry-based science teaching in which students develop an understanding of the natural world. Sections include: (1) "Connecting Students to Science and the World" (Jennifer Stepanek); (2) "Apple Orchard Lush with Life's Lessons" (Helen Silvis); (3) "Student Scientists Team Up with the Pros" (Amy Sutton); (4)…

Discusses the role of the laboratory in teaching chemistry, describing and differentiating between empirical laboratory investigations and discovery laboratory investigations. Also points out that if a laboratory is designed to illustrate something, it should be the scientific method. (JN)

Numerous examples of devices designed by primary school children are provided. The instructional methodology and classroom setting are also described. (CP)

Current scientific and technologiical issues should be incorporated into more active classroom, laboratory, and extracurricular learning so that students can perceive the future as personally relevant. (MJL)

An organic chemistry laboratory has been designed around independent laboratory projects that are done by groups, thus exposing students not only to a research experience but also to one that is more realistic and like the one they will be in as professional chemistry chemists. Instructional strategies used are described. (JN)

Determined student opinion of the investigative laboratory by surveying both students who had completed an introductory biology course using this format and another group of more advanced students who had taken other courses since this one. Results show that a majority of students feel the format improved their problem-solving skills. (JN)

Summarizes contents of a guide titled "Teaching Chemistry to Physically Handicapped Students," designed primarily for college-level teachers and intended to familiarize teachers with the practical aspects of teaching chemistry in the classroom and laboratory to students with physical handicaps. (CS)

Examines the psychology of learning and its application to work in the laboratory. States that the working memory capacity of students is limited; therefore the amount of information they can process needs to be controlled and "recipe following" in the laboratory is perfectly reasonable. (RT)

Presents instructional methods biology teachers can use to make their presentations more interesting. Author describes variety of methods for introducing lesson on the heart and discusses use of metaphors, form, models, and fractals in instruction pertaining to circulatory system. Presents idea of using Capon's "The Supper of the Lamb"…

Describes an innovative, but not revolutionary, secondary education science program that is modeled after American graduate education. Discussions include a comparison of pedagogical approaches, implementation, the teacher, facilities, and teaching strategies. (ZWH)

Reports the recommendations of the annual American Institute of Biological Sciences (AIBS) meeting at the University of Georgia. Suggests that biologists should become more involved in land use planning and resource allocation in the Southeast. Presents a seven-step process for land-use decision-making. (MA)

This article describes an introductory physics laboratory program which teaches three skills: (1) the ability to make estimates and order-of-magnitude calculations, and to use these to check experimental work, (2) the ability to use qualitative and quantitative statistics, and (3) the ability to describe an experiment in one's own words.…

Defines a few major reasons for the frequent failure of laboratory instructional methods and outlines some modes of thinking that seem to promise greater effectiveness and firmer justification for maintaining the laboratory as an essential component of physics teaching. (MVL)

Criticizes the way organic chemistry teaching laboratory experiments are approached from the viewpoint of physical chemistry. Compares these experiments to cooking. Stresses that what matters is not the practice of the finger skills of organic chemistry but practice in the style of thinking of organic chemists. (CW)