Denise W. Carlson

Beyond the pipeline: building a K-12 engineering outreach program

Outreach to the K-12 community by engineering faculty and students is not a novel idea. There have long been those individuals passionate about sharing the fun and excitement of solving problems, designing and building new devices, and creating what has never existed before. What is new is an increased national awareness of the importance of nurturing connections between the demands of the technological workplace, institutions of higher education, and the K-12 community of teachers and learners. This paper provides guidance on planning and implementing a K-12 engineering outreach program using the outreach component of the Integrated Teaching and Learning (ITL) Program at the College of Engineering and Applied Science, University of Colorado at Boulder (USA), as a case study.

Ascertaining the Impact of P–12 Engineering Education Initiatives: Student Impact through Teacher Impact

The widespread need to address both science, technology, engineering, and math (STEM) education and STEM workforce development is persistent. Underscored by the Next Generation Science Standards, demand is high for P–12 engineering-centered curricula. TeachEngineering is a free, standards-aligned NSF-funded digital library of more than 1,500 hands-on, design-rich K–12 engineering lessons and activities. Beyond anonymous site-user counts, the impact of the TeachEngineering collection and outreach initiatives on the education of children and their teachers was previously unknown. Thus, the project team wrestled with the question of how to meaningfully ascertain classroom impacts of the digital engineering education library and—more broadly—how to ascertain the impacts of teacher-focused P–12 engineering education initiatives. In this paper, the authors approach the classroom impact question through probing self-reported differentials in: (1) teachers’ confidence in teaching engineering concepts, and (2) changes in their teaching practices as a result of exposure to (and experiences with) K–12 engineering education resources and outreach opportunities. In 2016, four quantitative and qualitative surveys were implemented to probe the impact of the TeachEngineering digital library and outreach on four populations of K–12 teachers’ confidence and practices, including the frequency with which they integrate engineering into their precollege classrooms. Survey results document the teacher experience and perception of using hands-on K–12 engineering curricular materials in the classroom and help create a data-driven understanding of where to best invest future resources. The results suggest that the TeachEngineering curricular resources and outreach initiatives help teachers build confidence in their use of engineering curriculum and pedagogy in K–12 classrooms, impact their teaching practices, and increase their likelihood of teaching engineering in the classroom in the future.

Undergraduate Engineers and Teachers: Can Students Be Both?

Today’s college-aged students are graduating into a world that relies on multidisciplinary talents to succeed. Engineering college majors are more likely to find jobs after college that are outside of STEM (science, technology, engineering, and mathematics) fields, including jobs in healthcare, management, and social services. A survey of engineering undergraduate students at the University of Colorado Boulder in November 2012 indicated a desire by students to simultaneously pursue secondary teacher licensure alongside their engineering degrees: 25 percent ‘‘agreed’’ or ‘‘strongly agreed’’ that they ‘‘would be interested in earning grades 7–12 science or math teaching licenses while [they] earn [their] engineering degrees. As colleges of engineering education, how can we support the success of our students in these multidisciplinary fields post-graduation, including teaching? The University of Colorado Boulder’s College of Engineering and Applied Science in partnership with the School of Education, has developed an innovative program that results in graduates attaining a secondary school STEM teacher license concurrently with an engineering BS degree. This streamlined pathway through engineering educates and prepares a workforce of secondary teachers capable of high-level teaching in multiple STEM subjects—either engineering coupled with science (biology, chemistry, and physics), or engineering coupled with mathematics. These engineers are motivated and inspired to pursue two career routes because they find value and passion for both professions. One study showed that successful mathematics and science teachers ‘‘would have liked to be engineers’’. Teachers expressed that being comfortable and understanding engineering phenomena is a barrier to why they initially did not pursue an engineering career. We are fostering students that develop both an engineering mindset alongside a commitment to giving back through secondary teaching in this program. This research aims to discover if and how students in the engineering + teaching program identify themselves as both an engineering student and as a teaching student. We are exploring why students decided to pursue engineering and teaching and how they plan to use engineering, teaching, or both in their futures. It is important to also understand how we attract students to this program. Given the diverse student experience inherent in this degree program built around passion and desire to combine engineering and teaching, the paper addresses the questions, ‘‘How do engineering knowledge and teaching knowledge intersect for undergraduate engineering students?’’ and ‘‘What challenges exist to navigating an engineering major with a teaching license pathway?’’ Initial survey and focus group data collected this past academic year indicates that students in this degree program identify as both an engineer and a teacher. Using mixed-methods analysis informed by current education research—including quantitative and qualitative survey questions and small focus groups—we explore the ways in which students discovered this program and how they plan to incorporate the two disciplines in their future. We are interested in how engineering students will incorporate the knowledge that they learned in engineering classes into the lesson plans they design for secondary classroom students.