Implementing Integrated Project-Based Learning Outcomes in a 21st-Century Environmental Engineering Curriculum

Susan Gallagher; Adrienne Phillips; Ellen Lauchnor; Amanda Hohner; Otto R. Stein; Craig R. Woolard; Catherine M. Kirkland; Kathryn Plymesser

Download Paper | Permalink

Conference: 2023 ASEE Annual Conference & Exposition
Location: Baltimore , Maryland
Publication Date: June 25, 2023
Start Date: June 25, 2023
End Date: June 28, 2023
Conference Session: Environmental Engineering Division (ENVIRON) Technical Session 3
Tagged Division: Environmental Engineering Division (ENVIRON)
Page Count: 13
DOI: 10.18260/1-2--43547
Permanent URL: https://peer.asee.org/43547
Download Count: 141

Request a correction

Paper Authors

biography

Susan Gallagher Montana State University - Bozeman

visit author page

Susan Gallagher is the Education and Workforce Program Manager at the Western Transportation Institute (WTI) at Montana State University.

visit author page

author page

Abstract

Engineering education research and accreditation criteria have for some time emphasized that to adequately prepare engineers to meet 21st century challenges, programs need to move toward an approach that integrates professional knowledge, skills, and real-world experiences throughout the curriculum [1], [2], [3]. An integrated approach allows students to draw connections between different disciplinary content, develop professional skills through practice, and relate their emerging engineering competencies to the problems and communities they care about [4], [5]. Despite the known benefits, the challenges to implementing such major programmatic changes are myriad, including faculty’s limited expertise outside their own disciplinary area of specialization and lack of perspective of professional learning outcomes across the curriculum.

In 2020, Montana State University initiated a five-year NSF-funded Revolutionizing Engineering Departments (RED) project to transform its environmental engineering program by replacing traditional topic-focused courses with a newly developed integrated and project-based curriculum (IPBC). The project engages all tenure-track faculty in the environmental engineering program as well as faculty from five external departments in a collaborative, iterative process to define what students should be expected to know and do at the completion of the undergraduate program. In the process, sustainability, professionalism, and systems thinking arose as foundational pillars of the successful environmental engineer and are proposed as three knowledge threads that can be woven throughout environmental engineering curricula.

The paper explores the two-year programmatic redesign process and examines how lessons learned through the process can be applied to course development as the team transitions into the implementation phase of the project. Two new integrated project-based learning courses targeting the 1st- and 2nd-year levels will be taught in academic year 2023-2024. The approach described in this work can be utilized by similar programs as a model for bottom-up curriculum development and integration of non-technical content, which will be necessary for educating engineers of the future.

References: [1] McGowan, JD, Knapper, CK, An Integrated and Comprehensive Approach to Engineering Curricula, Part One: Objectives and General Approach. Int. J. Engng Ed., 2002. 18(6): p. 633-637. [2] Shuman, L.J., M. Besterfield-Sacre, and J. McGourty, The ABET “Professional Skills” — Can They Be Taught? Can They Be Assessed? J. of Engng. Ed., 2005. 94(1): p. 41-55. [3] Froyd, JE, Ohland, MW, Integrated Engineering Curricula. J. of Engng. Ed., 2008. January: p. 147-164. [4] Villanueva, I and L Nadelson, Are We Preparing Our Students to Become Engineers of the Future or the Past? Int. J. Engng Ed., 2017. 33: p. 639-652. [5] Litzinger, T, et al., Engineering Education and the Development of Expertise. J. of Engng. Ed., 2011. 100(1): p. 123-150.

Citation
Format

Gallagher, S., & Phillips, A., & Lauchnor, E., & Hohner, A., & Stein, O. R., & Woolard, C. R., & Kirkland, C. M., & Plymesser, K. (2023, June), Implementing Integrated Project-Based Learning Outcomes in a 21st-Century Environmental Engineering Curriculum Paper presented at 2023 ASEE Annual Conference & Exposition, Baltimore , Maryland. 10.18260/1-2--43547

TY - CPAPER
AB - Engineering education research and accreditation criteria have for some time emphasized that to adequately prepare engineers to meet 21st century challenges, programs need to move toward an approach that integrates professional knowledge, skills, and real-world experiences throughout the curriculum [1], [2], [3]. An integrated approach allows students to draw connections between different disciplinary content, develop professional skills through practice, and relate their emerging engineering competencies to the problems and communities they care about [4], [5]. Despite the known benefits, the challenges to implementing such major programmatic changes are myriad, including faculty’s limited expertise outside their own disciplinary area of specialization and lack of perspective of professional learning outcomes across the curriculum.

In 2020, Montana State University initiated a five-year NSF-funded Revolutionizing Engineering Departments (RED) project to transform its environmental engineering program by replacing traditional topic-focused courses with a newly developed integrated and project-based curriculum (IPBC). The project engages all tenure-track faculty in the environmental engineering program as well as faculty from five external departments in a collaborative, iterative process to define what students should be expected to know and do at the completion of the undergraduate program. In the process, sustainability, professionalism, and systems thinking arose as foundational pillars of the successful environmental engineer and are proposed as three knowledge threads that can be woven throughout environmental engineering curricula.

The paper explores the two-year programmatic redesign process and examines how lessons learned through the process can be applied to course development as the team transitions into the implementation phase of the project. Two new integrated project-based learning courses targeting the 1st- and 2nd-year levels will be taught in academic year 2023-2024. The approach described in this work can be utilized by similar programs as a model for bottom-up curriculum development and integration of non-technical content, which will be necessary for educating engineers of the future.

References:
[1] McGowan, JD, Knapper, CK, An Integrated and Comprehensive Approach to Engineering Curricula, Part One: Objectives and General Approach. Int. J. Engng Ed., 2002. 18(6): p. 633-637.
[2] Shuman, L.J., M. Besterfield-Sacre, and J. McGourty, The ABET “Professional Skills” — Can They Be Taught? Can They Be Assessed? J. of Engng. Ed., 2005. 94(1): p. 41-55.
[3] Froyd, JE, Ohland, MW, Integrated Engineering Curricula. J. of Engng. Ed., 2008. January: p. 147-164.
[4] Villanueva, I and L Nadelson, Are We Preparing Our Students to Become Engineers of the Future or the Past? Int. J. Engng Ed., 2017. 33: p. 639-652.
[5] Litzinger, T, et al., Engineering Education and the Development of Expertise. J. of Engng. Ed., 2011. 100(1): p. 123-150.

AU - Susan Gallagher
AU - Adrienne Phillips
AU - Ellen Lauchnor
AU - Amanda Hohner
AU - Otto R. Stein
AU - Craig R. Woolard
AU - Catherine M. Kirkland
AU - Kathryn Plymesser P.E.
CY - Baltimore , Maryland
DA - 2023/06/25
PB - ASEE Conferences
TI - Implementing Integrated Project-Based Learning Outcomes in a 21st-Century Environmental Engineering Curriculum
UR - https://peer.asee.org/43547
DO - 10.18260/1-2--43547
ER -