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1. From Resistance to Readiness – Building Capacity to Pilot and Scale Co-requisite Calculus for First-Year Engineering Gateway Courses

   https://doi.org/10.18260/1-2--46866  

   Olsen, Darlene; Supan, Karen; Johnson, Liz (June 2024, Gardening outdoor living)

   Norwich University, the oldest Senior Military College in the nation and the first private U.S. institution to teach engineering, has a residential program for approximately 2,100 primarily undergraduate students in both the Corps of Cadets and civilian lifestyles. Norwich secured a National Science Foundation S-STEM award in the beginning of 2020 to develop a program to attract and retain highly talented, low-income students in STEM. One of the aims of the project was to support students who enter college with less experience in mathematics as these students were significantly less likely to graduate with a STEM degree. In the fall of 2020, as a result of the S-STEM award, the mathematics department offered a pilot corequisite calculus course to STEM majors requiring calculus their first semester but placed into precalculus by the mathematics departmental placement test. The corequisite calculus course includes content from precalculus into a one semester calculus course that meets daily for 6 contact hours rather than a standard 4 credit hour calculus course. The Norwich University Civil, Electrical and Computer, and Mechanical Engineering programs are accredited by the Engineering Accreditation Commission of ABET, placing restrictions on the 8-semester engineering degree pathway. The added credits to the first semester corequisite calculus course fit the constraints of the first semester engineering course load and this course has enabled engineering students that place into precalculus to complete an on-time degree plan without taking summer courses. The corequisite course has been approved by the university curriculum committee and is a regular offering at the institution. The initial offering of the corequisite course occurred during the COVID pandemic necessitating the use of additional instructional technology. There was also an increase in low stakes assessments to encourage students to engage in the material. The added credits also increased the regularity of student interacting with calculus. Since the implementation of this pilot course, there have been several similar changes in other courses required by engineering majors. The pilot corequisite course has become institutionalized and even is now scaling, with the engineering department requesting the course to be offered each semester to benefit students who are out of sync with the intended curriculum pathway. This project examines how the corequisite calculus course may have influenced changes in the general education courses and engineering first year sequence. Outcome harvesting as well as process tracing are used to determine the strength of evidence linking the corequisite course to institutional change. Qualitative and quantitative data will be examined as well to understand how the S-STEM award contributed to breakdown of the resistance to curriculum change and the readiness to implement and scale corequisite courses in other areas. It is important to understand the mechanisms used for building capacity at the institution to transform STEM education in higher education 

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2. Developing Resources to Support Comprehensive Transfer Engineering Curricula: Assessing the Effectiveness of a Hybrid Materials Science Course

   https://doi.org/10.18260/p.26769  

   Dunmire, Erik; Enriquez, Amelito; Langhoff, Nicholas; Rebold, Thomas; Schiorring, Eva (June 2016, 2016 ASEE Annual Conference & Exposition)

   A substantial percentage of engineering graduates, especially those from traditionally underrepresented groups, complete their lower-division education at a community college before transferring to a university to earn their degree. However, engineering programs at many community colleges, because of their relatively small scale with often only one permanent faculty member, struggle to offer lower-division engineering courses with the breadth and frequency needed by students for effective and efficient transfer preparation. As a result, engineering education becomes impractical and at times inaccessible for many community college students. Through a grant from the National Science Foundation Improving Undergraduate STEM Education program (NSF IUSE), three community colleges from Northern California collaborated to increase the availability and accessibility of the engineering curriculum by developing resources and teaching strategies to enable small-to-medium sized community college engineering programs to support a comprehensive set of lower-division engineering courses. These resources were developed for use in a variety of delivery formats (e.g., fully online, online/hybrid, flipped face-to-face, etc.), providing flexibility for local community colleges to leverage according to their individual needs. This paper focuses on the development and testing of the resources for an introductory Materials Science course with 3-unit lecture and 1-unit laboratory components. Although most of the course resources were developed to allow online delivery if desired, the laboratory curriculum was designed to require some limited face-to-face interaction with traditional materials testing equipment. In addition to the resources themselves, the paper presents the results of the pilot implementation of the course during the Spring 2015 semester, taught using a flipped delivery format consisting of asynchronous remote viewing of lecture videos and face-to-face student-centered problem-solving and lab exercises. These same resources were then implemented in a flipped format by an instructor who had never previously taught the course, at a community college that did not have its own materials laboratory facilities. Site visits were arranged with a nearby community college to afford students an opportunity to complete certain lab activities using traditional materials testing equipment. In both implementations of the course, student surveys and interviews were used to determine students’ perceptions of the effectiveness of the course resources, student use of these resources, and overall satisfaction with the course. Additionally, student performance on assessments was compared with that of traditional lecture delivery of the courses in prior years. 

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3. Creating Significant Learning Experiences in an Engineering Technology Bridge Course: a backward design approach

   Villalta-Cerdas, A.; Yildiz, F. (January 2022, 2022 ASEE Virtual Annual Conference Content Access)

   Academic bridge courses are implemented to impact students’ academic success by revising fundamental concepts and skills necessary to successfully complete discipline-specific courses. The bridge courses are often short (one to three weeks) and highly dense in content (commonly mathematics or math-related applications). With the support of the NSF-funded (DUE - Division of Undergraduate Education) STEM Center at Sam Houston State University (SHSU), we designed a course for upcoming engineering majors (i.e., first-year students and transfer students) that consists of a two-week-long pre-semester course organized into two main sessions. The first sessions (delivered in the mornings) were synchronous activities focused on strengthening student academic preparedness and socio-academic integration and fostering networking leading to a strong STEM learning community. The second sessions (delivered in the afternoons) were asynchronous activities focused on discipline-specific content knowledge in engineering. The engineering concepts were organized via eight learning modules covering basic math operations, applied trigonometry, functions in engineering, applied physics, introduction to statics and Microsoft Excel, and engineering economics and its applied decision. All materials in the course were designed by engineering faculty (from the chair of the department to assistant professors and lecturers in engineering) and one educational research faculty (from the department of chemistry). The course design process started with a literature review on engineering bridge courses to understand prior work, followed by surveying current engineering faculty to propose goals for the course. The designed team met weekly after setting the course goals over two semesters. The design process was initiated with backward design principles (i.e., start with the course goals, then the assessments, end with the learning activities) and continued with ongoing revision. The work herein presents this new engineering bridge course’s goals, strategy, and design process. Preliminary student outcomes will be discussed based on the course’s first implementation during summer 2021. 

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4. A Model for Materials Science in Physics and Chemistry Curricula and Research at a Primarily Undergraduate Institution

   https://doi.org/10.1557/adv.2017.96  

   Burnett, Brandon; Inglefield, Colin; Rabosky, Kristin (January 2017, MRS Advances)

   ABSTRACT Materials science skills and knowledge, as an addition to the traditional curricula for physics and chemistry students, can be highly valuable for transition to graduate study or other career paths in materials science. The chemistry and physics departments at Weber State University (WSU) are harnessing an interdisciplinary approach to materials science undergraduate research. These lecture and laboratory courses, and capstone experiences are, by design, complementary and can be taken independently of one another and avoid unnecessary overlap or repetition. Specifically, we have a senior level materials theory course and a separate materials characterization laboratory course in the physics department, and a new lecture/laboratory course in the chemistry department. The chemistry laboratory experience emphasizes synthesis, while the physics lab course is focused on characterization techniques. Interdisciplinary research projects are available for students in both departments at the introductory or senior level. Using perovskite materials for solar cells, WSU is providing a framework of different perspectives in materials: making materials, the micro- and macrostructure of materials, and the interplay between materials to create working electronic devices. Metal-halide perovskites, a cutting-edge technology in the solar industry, allow WSU to showcase that undergraduate research can be relevant and important. The perovskite materials are made in the chemistry department and characterized in the physics department. The students involved directly organize the collaborative exchange of samples and data, working together to design experiments building ownership over the project and its outcomes. We will discuss the suite of options available to WSU students, how we have designed these curricula and research, as well as some results from students who have gone through the programs. 

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5. Work In Progress: Assisting Academically Underprepared Engineering Students in Mathematics

   Shekhar, Prateek; Otondi, Stephen; Sodhi, Jaskirat (January 2020, Zone 1 Conference of the American Society for Engineering Education)

   null (Ed.)

   Foundational understanding of mathematics topics is a common prerequisite for several engineering courses. However, engineering students are often underprepared in several pre-calculus topics. This study identifies common areas of error for students enrolled in a remedial mathematics course. The emerging error categories pertinent to the topic of linear equations unpacks areas of conceptual difficulty that underprepared students may encounter. Instruction and curriculum that targets these topics will better assist students in developing the required mathematics proficiency. In our ongoing and future work, we intend to examine other topics of the course to develop a holistic understanding of student learning needs in pre-calculus remedial courses. These findings will inform future revisions of the offered course and subsequent assessment of the revised instruction. 

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