Education research provides a range of curricular reform options that can lead to improved student course outcomes. These options can appear easy to implement with the hope of immediate increases in student learning. In 2006 the Ithaca College Physics Department went down this path by moving all of their 100-level courses out of lecture halls and…

This article describes the implementation of high-altitude balloon (HAB) research into a variety of undergraduate atmospheric science classes as a means of increasing active student engagement in real-world, problem-solving events. Because high-altitude balloons are capable of reaching heights of 80,000-100,000 ft (24-30 km), they provide a…

Dual-enrollment (DE) science courses offer a way to strengthen the science, technology, engineering, and mathematics pipeline between high school and college. These courses offer high school students the opportunity to experience college science in a more supported environment, allowing them to adjust to the different academic and social demands…

The ELMO (Embedded Learning Modules) curriculum reform project has designed science curricula for specific nonscience students that fulfill core requirements and demonstrate how science can be engaging and relevant. ELMO students experience science through active learning and group activities that encourage them to make connections between science…

We present an approach for integrating instruction of scientific writing and reading into undergraduate science courses, inspired by the pedagogical theory of cognitive apprenticeship. We demonstrate its implementation and describe a study of students' feedback that enabled us to elicit students' difficulties and fine-tune the next application…

The project described here involved the design, implementation, and evaluation of an upper level, undergraduate elective course for science majors. Specific course goals were to help students gain an appreciation of the interdisciplinary nature of astrobiology, understand key ideas in astrobiology, and develop the skills necessary to communicate…

Discusses need for and nature of science courses for the nonspecialist, outlining the content of an integrated four-year program devoted to sciences (first two years), technology (third year) and science/technology/human problems (fourth year). Includes recommendations for implementing such a program. (Author/JN)