Project-Based Learning in a Multidisciplinary Two-Semester First-Year Experience

Mohammad Heshmati; Bill B. Elmore

Download Paper | Permalink

Conference: 2024 ASEE Annual Conference & Exposition
Location: Portland, Oregon
Publication Date: June 23, 2024
Start Date: June 23, 2024
End Date: July 12, 2024
Conference Session: ELOS Technical Session 4 - Design, Participation, and Projects
Tagged Division: Experimentation and Laboratory-Oriented Studies Division (DELOS)
Page Count: 17
Permanent URL: https://strategy.asee.org/47885

Request a correction

Paper Authors

biography

Mohammad Heshmati Mississippi State University orcid.org/0000-0002-4004-4345

visit author page

Dr. Mohammad Heshmati is an assistant professor in Swalm School of Chemical Engineering at Mississippi State University (MSU). His background is in Petroleum Engineering academia and industry settings. He is currently teaching Petroleum and Chemical Engineering courses at MSU and performs research in the fields of energy and dynamics of fluid flow in porous structures

visit author page

biography

Bill B. Elmore Mississippi State University

visit author page

Bill B. Elmore, Ph.D., P.E., is an Associate Professor and Director of the Swalm School of Chemical Engineering, holding the Deavenport Chair in Chemical Engineering. Interests include biotechnology for renewable energy and innovation in engineering education

visit author page

Download Paper | Permalink

Abstract

Experiential immersive learning not only provides a platform for students to learn by performing hands-on projects, but also, with proper planning, it helps with development of their collaboration, communication, safety considerations, and critical thinking skills. On the contrary, project-based learning comes with its own set of drawbacks, including the considerable time, energy, and resources instructors must invest in developing and implementing the course. In this work, we argue that, with proper planning over the span of several semesters, instructors can successfully transform a lecture-based first year course sequence for Chemical and Petroleum engineers’ offering. This transformation aims to provide students with the active learning experience in a project-based team environment while significantly reducing the reliance on traditional lectures. At Mississippi State University, the Introduction to Chemical and Petroleum Engineering course (fall semester) and the Chemical Engineering Analysis course (spring semester) are examples of such an achievement. Beginning in 2005, transformation of the lecture-based Chemical Engineering Analysis course began with a modest transition to allow students learn STEM concepts through hands-on scientific team experimentation. Year-by-year advancements have transformed the course to a predominantly project-based learning approach with minimal traditional lectures. Through such transformations, this course meets all ABET student outcomes criteria 1 through 7. With the re-establishment of the Petroleum engineering bachelor’s degree program in 2015, Petroleum engineering freshmen joined the Chemical Engineering Analysis course. In fall 2023, Chemical and Petroleum engineering freshmen were combined for an Introduction to Chemical and Petroleum Engineering course. The aim was to offer a comprehensive first-year experience blending project-based learning with additional content delivered through lectures. Supplementing technical content, these courses focus on safety, sustainable engineering, environmental awareness, teamwork, and technical communications. Team Challenges addressing topics such as flow through porous media, fluid mechanics, and heat transfer provide textual and video guidance for teams to conduct projects making iterative improvements. Students create technical reports summarizing experimental results with team oral presentations. Microsoft Excel is used for data collection and analysis, aligning with industry data management practices. To assess students' engagement, perspective on engineering, understanding of specific subjects, and preference for this course over lecture-based courses, surveys and assessments are conducted at the semester's start, end, and after significant course milestones. These evaluations are aligned with ABET Student Outcomes 1-7 and Program Specific criteria. Assessment methods include direct observation of team interactions, grading of technical reports using rubrics, and data management using Microsoft Excel. The data collected in 2023-24 will be compared to previous assessments of Chemical engineering students to track improvements and gauge the course's effectiveness. In conclusion, this study highlights the successful transformation of a traditional engineering course into an experiential immersive learning experience. It demonstrates the positive impact on student engagement, skill development, and understanding of course materials. The study also emphasizes the importance of continuous assessment and improvement to ensure the effectiveness of project-based learning approaches.

Citation
Format

Heshmati, M., & Elmore, B. B. (2024, June), Project-Based Learning in a Multidisciplinary Two-Semester First-Year Experience Paper presented at 2024 ASEE Annual Conference & Exposition, Portland, Oregon. https://strategy.asee.org/47885

TY - CPAPER
AB - Experiential immersive learning not only provides a platform for students to learn by performing hands-on projects, but also, with proper planning, it helps with development of their collaboration, communication, safety considerations, and critical thinking skills. On the contrary, project-based learning comes with its own set of drawbacks, including the considerable time, energy, and resources instructors must invest in developing and implementing the course.
In this work, we argue that, with proper planning over the span of several semesters, instructors can successfully transform a lecture-based first year course sequence for Chemical and Petroleum engineers’ offering. This transformation aims to provide students with the active learning experience in a project-based team environment while significantly reducing the reliance on traditional lectures. At Mississippi State University, the Introduction to Chemical and Petroleum Engineering course (fall semester) and the Chemical Engineering Analysis course (spring semester) are examples of such an achievement. Beginning in 2005, transformation of the lecture-based Chemical Engineering Analysis course began with a modest transition to allow students learn STEM concepts through hands-on scientific team experimentation. Year-by-year advancements have transformed the course to a predominantly project-based learning approach with minimal traditional lectures. Through such transformations, this course meets all ABET student outcomes criteria 1 through 7. With the re-establishment of the Petroleum engineering bachelor’s degree program in 2015, Petroleum engineering freshmen joined the Chemical Engineering Analysis course. In fall 2023, Chemical and Petroleum engineering freshmen were combined for an Introduction to Chemical and Petroleum Engineering course. The aim was to offer a comprehensive first-year experience blending project-based learning with additional content delivered through lectures.
Supplementing technical content, these courses focus on safety, sustainable engineering, environmental awareness, teamwork, and technical communications. Team Challenges addressing topics such as flow through porous media, fluid mechanics, and heat transfer provide textual and video guidance for teams to conduct projects making iterative improvements. Students create technical reports summarizing experimental results with team oral presentations. Microsoft Excel is used for data collection and analysis, aligning with industry data management practices.
To assess students&#39; engagement, perspective on engineering, understanding of specific subjects, and preference for this course over lecture-based courses, surveys and assessments are conducted at the semester&#39;s start, end, and after significant course milestones. These evaluations are aligned with ABET Student Outcomes 1-7 and Program Specific criteria. Assessment methods include direct observation of team interactions, grading of technical reports using rubrics, and data management using Microsoft Excel. The data collected in 2023-24 will be compared to previous assessments of Chemical engineering students to track improvements and gauge the course&#39;s effectiveness.
In conclusion, this study highlights the successful transformation of a traditional engineering course into an experiential immersive learning experience. It demonstrates the positive impact on student engagement, skill development, and understanding of course materials. The study also emphasizes the importance of continuous assessment and improvement to ensure the effectiveness of project-based learning approaches.
AU - Mohammad Heshmati
AU - Bill B. Elmore
CY - Portland, Oregon
DA - 2024/06/23
PB - ASEE Conferences
TI - Project-Based Learning in a Multidisciplinary Two-Semester First-Year Experience
UR - https://strategy.asee.org/47885
ER -