The push for STEM has raised the visibility of engineering as a discipline that all students should learn. With the release of the "Framework for K-12 Science Education" and the Next Generation Science Standards (NGSS), engineering now has an official place in the science curriculum. In both the "Framework" and the NGSS,…

The author notes that the sciences are now something one must latch onto early and successfully as a teenager, and endure against all odds. This pivotal point requires maturity and even myopia--delayed gratification and voluntary dorkiness--traits not common in the young. As a nation, Americans are losing their hegemony in the sciences. In just…

The author of this article argues that, just as Americans were shocked into action, when the Soviet Union launched Sputnik in 1957, by strengthening STEM (science, technology, engineering, and mathematics) in the educational curriculum, Americans must be shocked again. The nation must address the failure of its leaders to provide adequate funding…

Discusses how engineers will be educated in the twenty-first century, including workstation, teaching methods, teaching materials, and the college system. Describes some of the obstacles, such as small numbers of applicants, aging professors, poor preparation at high school level, and costs. (YP)

Compares graduate chemical engineering education practices of the U.S. and Japan. States that Japanese universities have set time limits on degrees due to industrial hiring practices. Concludes that Japanese graduates are highly trained and uniform. They tend to stay in the same job throughout their career. (MVL)

Are textbooks useful, or are they an unnecessary expense or even an obstacle to robust conceptual understanding? Clearly, the answer depends upon course context--what are the goals of the course, how could the textbook be used to achieve these goals, does this use justify the cost of the textbook, and are there more educationally effective or…

Proposes that there is a universal method for all realms of knowledge. Reviews Descartes's definition of the universal method, the engineering definition, and the philosophical basis for the universal method. Contends that the engineering method best represents the universal method. (ML)

Considered is the importance of teaching creativity in the field of chemical engineering. Lists major concepts in teaching creativity. Suggests ways of bringing creativity into chemistry instruction. (MVL)

Differentiates among science, engineering, design, and technology. Examines recent recommendations that accreditation criteria for engineering science and engineering design be changed. Provides five guidelines for the development of design experiences which would permeate the entire chemical engineering curriculum. (TW)

Expresses the opinion that education has overemphasized the written word and needs to move back to the oral tradition. Warns that Americans are trained to use the left brain whereas much of engineering needs right brain processing. Gives perspectives to improve engineering education. (MVL)

Argues that the field of chemical engineering is going through a major transition. Discusses trends in microchemical and biochemical engineering and warns that the overall field of chemical engineering is departing from the fundamentals of science. Urges chemical engineering educators to restructure their programs to again emphasize basic science.…

Reports on a survey of the undergraduate programs of 50 engineering schools which was designed to investigate the engineering curriculum with regard to core courses in statics and dynamics. Indicates that only about one-third of the schools require these courses. Argues for their return to the programs. (TW)

Describes four principles to help engineering faculty facilitate high rates of learning: (1) Objective Based Instruction; (2) Absolute Criterion-Referenced Grading Standard; (3) Varied Learning Strategies; and (4) Flexible Time Frames. Illustrates several teaching/learning systems that facilitate the effective applications of these principles. (SK)

Contains ten basic teaching principles formulated from the author's past experiences. Each of the principles is illustrated by relevant observations in order to increase understanding and aid application. The author states that use of these principles will increase teaching success. (SMB)

Investigates whether replacing a single traditional laboratory activity with a widely-used, non-microcomputer-based laboratory, research-based activity could produce improved conceptual understanding of a topic in electricity. Shows that a single instructional experience utilizing the research-based tutorial materials is superior to a traditional…