Science and Mathematics Education Commons^™

Imsa© Fusion: Preparing Students For Future Scientific Expertise, Michelle Kolar, Dora Phillips, Elizabeth Martinez, Laurie S. Sutherland

Publications & Research

Illinois adopted the Next Generation Science Standards (NGSS) on February 19, 2014 with implementation scheduled to begin in the 2016-17 school year. This article explores (1) the national and statewide need for STEM college and career readiness based on current data; (2) the research on best practices in STEM teaching and learning; and (3) the work of the Illinois Mathematics and Science Academy (IMSA) to create IMSA Fusion, a science, technology, engineering and mathematics (STEM) educational program that is aligned with NGSS and utilizes research-based best practices to serve Illinois educators and students.

The introduction of the Next Generation Science …

Engineering Education For High-Ability Students, Branson Lawrence, Diane Hinterlong, Laurie S. Sutherland

Publications & Research

Over the course of their careers, engineers command a breadth and depth of knowledge from science, mathematics, society, politics, and economics that is needed for continuously updating their knowledge of the latest discoveries and advances. Driven by curiosity and enabled by rapid information technology, engineers are kept abreast of the latest advancements almost instantaneously. Today’s scientific knowledge is fluid and complex, yet these traits of engineering remain constant: the ability to define structure, plan, repeatedly evaluate, and align results to the initial objective. Engineering teachers need to facilitate their students’ ability to access information effectively and to apply it appropriately, …

Experiential Learning At The Illinois Mathematics And Science Academy, Michelle Kolar, Dora Phillips, Christopher G. Kolar

Publications & Research

“Am I ever going to use this in the real world?” is a common question in science and math middle school and high school classrooms. Students taught using experiential learning techniques, however, already know the answer. They learn content by solving real world problems through hands-on activities. In other words, they learn science, technology, engineering, and math (STEM) the same way professionals do every day—by doing, sharing, and improving. Experiential learning provides the promise that the U.S. can reverse the trend of students losing interest in STEM subjects during middle school and create life-long learners who apply the scientific thought …

Preparing Students For Careers That Do Not Yet Exist, Glenn W. "Max" Mcgee

Publications & Research

The Illinois Mathematics and Science Academy (IMSA), as a self-described "teaching and learning laboratory for imagination and inquiry," has a history of pursuing innovations closely aligned with the vision and framework of the National Science Education Standards. Innovations include both methods and materials for inquiry-based student instruction as well as for delivering professional development for pre-service and practicing teachers. Instructional innovations described include yearlong student inquiry and research projects (SIR), self-paced physics instruction, student-driven energy and engineering projects, instruction in innovation and entrepreneurialism, and a host of student-led outreach activities to "ignite and nurture creative, ethical, scientific minds of students …

Re-Imagining Specialized Stem Academies: Igniting And Nurturing ‘Decidedly Different Minds,’ By Design, Stephanie Pace Marshall

Publications & Research

This article offers a personal vision and conceptual design for reimagining specialized science, technology, engineering, and mathematics (STEM) academies designed to nurture decidedly different STEM minds and ignite a new generation of global STEM talent, innovation, and entrepreneurial leadership. This design enables students to engage actively in the authentic work, modes of inquiry, and practices that distinguish four STEM learning cultures, environments, and communities: (a) Inquiry and Research Laboratory and Interdisciplinary Learning Center—develops disciplinary, interdisciplinary, and inquiry-based thinking; (b) Innovation Incubator and Design Studio—ignites innovative and design-based thinking; (c) Global Leadership and Social Entrepreneurship Institute—nurtures change leadership and systems-based thinking; …

Stem Talent: Moving Beyond Traditional Boundaries, Stephanie Pace Marshall

Publications & Research

The future well-being, prosperity and sustainability of our nation, the global community and our planet resides in igniting and nurturing decidedly different STEM minds that can advance both the new STEM frontier and the human future.

Igniting And Nurturing The Next Generation Of Stem Talent, Innovation And Leadership, By Design, Stephanie Pace Marshall

Publications & Research

Regrettably, most American students experience STEM learning as an exclusive, individual, theoretical and “formulaic” enterprise. By decoupling STEM education from the human experience, we have distorted the essential nature of the scientific enterprise and advanced instrumentalist and utilitarian rationales for pursuing STEM careers—global economic superiority and technological competition.

Thailand Ties, Raymond J. Dagenais

Publications & Research

One of the resolutions I witnessed moving forward at the Summer 2006 National Congress on Science Education in Toronto, Canada involved expanding our learning through international collaborations. The Congress encouraged National Science Teacher Association affiliates to make an effort to connect with educators in other countries in order to both learn and share ideas and issues facing the science education community. With the already large numbers of students from other cultures in many school systems in the United States and the increasing quality of students coming out of science programs in other countries, it has become imperative that we better …