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1. Integration of Remote Sensing & Environmental Science in Placed-Based Learning

   Ignatius, A.R.; Flood, M.G (January 2021, Proceedings of the ASPRS 2021 Annual Conference)

   null (Ed.)

   Integration of remote sensing techniques and Environmental Science methodologies in place-based curriculum design creates unique learning opportunities. To promote introductory-level student engagement with STEM, our team designed a set of multidisciplinary teaching materials to intensely examine a single location: the Lake Sidney Lanier watershed of North Georgia, USA. Using a combination of scientific approaches from a variety of disciplines, course exercises encourage students to holistically learn about environmental conditions within the watershed. In addition, the learning materials require students to contemplate the process of knowledge-formation by considering the limitations and potential applications of different scientific approaches. Remote sensing exercises are embedded throughout the course content and include analysis of historic aerial imagery, Landsat-derived dynamic surface water extent, google timelapse land cover change, Sentinel 2 spectral bands, and evaluation of lidar-derived topography. Learning resources were intentionally designed to seamlessly integrate remote sensing approaches and traditional environmental science methods. Fundamental spatial concepts of scale and connectivity are considered using interdisciplinary approaches and local data. The environmental science theory of landscape ecology is presented alongside remote sensing concepts of spatial and temporal resolution. This allows students to think about the diverse ways scientists understand scale, pattern, and the definition of “place”. Multiple data sources are also provided for each topic. For example, remote sensing imagery is used to investigate surface water conditions during drought and high-rainfall time periods. In addition, USGS streamgage river discharge data and rainfall estimates are provided for students to examine drought history using multiple parameters. Lastly, sensor deployment and limitations of each data source are described so that students understand both the history of place as well as the process and development of science. Through the use of a place-based curriculum design and interdisciplinary lab exercises, students gain a holistic understanding of a regional watershed. 

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2. Machine Learning in a Molecular Modeling Course for Chemistry, Biochemistry, and Biophysics Students

   https://doi.org/10.35459/tbp.2019.000140  

   Remington, Jacob M.; Ferrell, Jonathon B.; Zorman, Marlo; Petrucci, Adam; Schneebeli, Severin T.; Li, Jianing (June 2020, The Biophysicist)

   null (Ed.)

   ABSTRACT Recent advances in computer hardware and software, particularly the availability of machine learning (ML) libraries, allow the introduction of data-based topics such as ML into the biophysical curriculum for undergraduate and graduate levels. However, there are many practical challenges of teaching ML to advanced level students in biophysics majors, who often do not have a rich computational background. Aiming to overcome such challenges, we present an educational study, including the design of course topics, pedagogic tools, and assessments of student learning, to develop the new methodology to incorporate the basis of ML in an existing biophysical elective course and engage students in exercises to solve problems in an interdisciplinary field. In general, we observed that students had ample curiosity to learn and apply ML algorithms to predict molecular properties. Notably, feedback from the students suggests that care must be taken to ensure student preparations for understanding the data-driven concepts and fundamental coding aspects required for using ML algorithms. This work establishes a framework for future teaching approaches that unite ML and any existing course in the biophysical curriculum, while also pinpointing the critical challenges that educators and students will likely face. 

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3. An instructional lab apparatus for quantum experiments with single nitrogen-vacancy centers in diamond

   https://doi.org/10.1119/5.0216511  

   Yuan, Zhiyang; Mukherjee, Sounak; Thompson, Jeff D; de_Leon, Nathalie P; Gardill, Aedan; Kolkowitz, Shimon (November 2024, American Journal of Physics)

   Hands-on experimental experience with quantum systems in the undergraduate physics curriculum provides students with a deeper understanding of quantum physics and equips them for the fast-growing quantum science industry. Here, we present an experimental apparatus for performing quantum experiments with single nitrogen-vacancy (NV) centers in diamond. This apparatus is capable of basic experiments such as single-qubit initialization, rotation, and measurement, as well as more advanced experiments investigating electron–nuclear spin interactions. We describe the basic physics of the NV center and give examples of potential experiments that can be performed with this apparatus. We also discuss the options and inherent trade-offs associated with the choice of diamond samples and hardware. The apparatus described here enables students to write their own experimental control and data analysis software from scratch, all within a single semester of a typical lab course, as well as to inspect the optical components and inner workings of the apparatus. We hope that this work can serve as a standalone resource for any institution that would like to integrate a quantum instructional lab into its undergraduate physics and engineering curriculum. 

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4. Engaging Civil Engineering Students by Exposing them to a “Capstone-like” Experience in their Sophomore Year: A Case Study

   Sarasua, Wayne; Kaye, Nigel B.; Ogle, Jennifer H.; Benaissa, Mehdi N.; Benson, Lisa; Putman, Bradley J.; and Pfirman, Aubrie L. (June 2020, 2020 ASEE Annual Conference & Exposition)

   As part of a National Science Foundation-funded initiative to completely transform the civil engineering undergraduate program at Clemson University, a capstone-like course sequence is being incorporated into the curriculum during the sophomore year. Clemson’s NSF Revolutionizing Engineering Departments (RED) program is called the Arch Initiative. Just as springers serve as the foundation stones of an arch, the new courses are called “Springers” because they serve as the foundations of the transformed curriculum. Through a project-based learning approach, Springer courses mimic the senior capstone experience by immersing students in a semester-long practical application of civil engineering, exposing them to concepts and tools in a way that challenges students to develop new knowledge that they will build on and use during their junior and senior years. In the 2019 spring semester, a pilot of the first Springer course introduced students to three civil engineering sub-disciplines: construction management, water resources, and transportation. The remaining sub-disciplines are covered in a follow-on Springer 2 pilot. The purpose of this paper is to describe all aspects of the Springer 1 course, including course content, teaching methods, faculty resources, and the design and results of a Student Assessment of Learning Gains (SALG) survey to assess students’ learning outcomes. The feedback from the SALG indicated positive attitudes towards course activities and content. Challenges for full-scale implementation of the Springer course sequence as a requirement in the transformed curriculum are also discussed. 

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5. Exploring Student Understanding of Force and Motion Using a Simulation-Based Performance Assessment

   https://doi.org/10.51355/jstem.2016.21  

   Gale, Jessica; Koval, Jayma; Wind, Stefanie; Ryan, Mike; Usselman, Marion (July 2016, Journal of Research in STEM Education)

   Performance assessment (PA) has been increasingly advocated as a method for measuring students’ conceptual understanding of scientific phenomena. In this study, we describe preliminary findings of a simulation- based PA utilized to measure 8th grade students’ understanding of physical science concepts taught via an experimental problem-based curriculum, SLIDER (Science Learning Integrating Design Engineering and Robotics). In SLIDER, students use LEGO robotics to complete a series of investigations and engineering design challenges designed to deepen their understanding of key force and motion concepts (net force, acceleration, friction, balanced forces, and inertia). The simulation-based performance assessment consisted of 4 tasks in which students engaged with video simulations illustrating physical science concepts aligned to the SLIDER curriculum. The performance assessment was administered to a stratified sample of 8th grade students (N=24) in one school prior to and following implementation of the SLIDER curriculum. In addition to providing an illustration of the use of simulation- based performance assessment in the context of design-based implementation research (DBIR), the results of the study indicate preliminary evidence of student learning over the course of curriculum implementation. 

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