This article examines the tensions that arose as teachers, scientists, youth, and community organizers worked to develop a curriculum that was responsive to community concerns and the Next Generation Science Standards (NGSS). Within the context of urban heavy metal contamination and building on previous critiques of the standards, we identified…

The STEM (science, technology, engineering and mathematics) movement has developed from a non-educational rationale. Although some think it may enliven the delivery of maths and science in classrooms, the social and economic rationales are those that have initiated this movement. Spurred on by the global financial crisis, it is hoped that…

Cites the need for educational materials dealing with recent technological advancements. Discusses "an Alaskan Adventure," a multi-media resource packet on the discovery, extraction, and transportation of North Slope crude which was produced by the petroleum industry. (CP)

Outlines an industrial chemistry course aimed at bridging the academe-industry gap by identifying two major threads: the way industry functions and the way industrial chemists should act in order to be most effective. Contains 39 references. (DDR)

Describes aspects of the Understanding British Industry Project which was designed to provide information to teachers regarding the role which industry and commerce play in British society. (CS)

Discusses two main problem areas for school/industry cooperation: (1) the need to define the purpose of such cooperation; and (2) the logistical restraints of mass visits to local industries. Also discusses the development of attitudes, and the construction of interactive teaching packages. (CS)

The widespread deployment and use of Information Technologies (IT) has paved the way for change in many fields of our societies. The Internet, mobile computing, social networks and many other advances in human communications have become essential to promote and boost education, technology and industry. On the education side, the new challenges…

The defining task for undergraduate departments is the design of a major, including the number and content of courses as well as other requirements. Department members must weigh the desire to produce graduates superbly prepared for further study against the charge that the major requires too large a share of an undergraduate's course options.…

Surveyed 170 English schools (for 13- to 16-year-olds) to determine the extent to which industrially relevent materials were adopted in science classes and attitudes of science teachers toward these materials in science syllabi. Indicates that although teachers believe the industrial materials should be emphasized, traditional science courses…

The Chemical Education for Public Understanding Project is a three-year pilot project designed to provide the public with accurate information on uses and hazards of chemicals, ranging from control of garden pests to types of toxic wastes generated by industry. Discusses project aims and educational materials to be developed. (JN)

Presents general directions on how the Swedish university physics curricula should be designed to meet future needs. How to improve the cooperation between industry and university is also discussed. (HM)

Presents an alternative syllabus in A-level chemistry based on the place of chemistry in industry and its effect upon society. (Author/GS)

Describes efforts by one university to meet its responsibility of service to the industrial and business community in its local atea. Presents a discussion of the objectives of graduate level chemistry study and predicts areas of job availability for the foreseeable future. (GS)

The curriculum model described here has been designed by incorporating the socio-scientific reasoning model with a simulation design in an attempt to have students investigate the onshore impacts of Outer Continental Shelf (OCS) gas and oil development. The socio-scientific reasoning model incorporates a logical/physical reasoning component as…

Summarizes curriculum guidelines for the following engineering technologies: chemical, industrial, mining, petroleum, nuclear, civil, mechanical, electrical, automotive, and manufacturing. In a few years, these Engineering Council for Professional Development committee guidelines are intended to become the criteria by which programs will be judged…