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1. “Whose story is being told?”: Local history, cultural heritage, and digital maps.

   Alexander, C; Brown, K; Weinburgh, M; Valverde, E (April 2023, Society for Information Technology and Teacher Education Conference Proceedings)

   Langran, E (Ed.)

   A critical outcome in social studies education is identity development, and an important component of this process is students establishing a sense of place in their communities, nation, and world. Using data from a southwestern city in the United States, researchers investigated the intersection of local history, identity development, and cultural heritage resources using GIS technology. The instructional unit in which students participated utilized a variety of geospatial technologies which facilitated the visualization of geographic concepts, field-based data collection of geocoded places, and creation of a digitally-mediated cultural heritage map, which allowed students to create a narrative around their cultural identity. The study followed an interpretive case study design. Based on the findings from this study, important implications emerged, which are valuable for both future research in this area, as well as for teachers who wish to replicate this pedagogical approach in their own teaching practice. The implications include the flexibility of geospatial technologies for addressing content-area concepts at all levels of the instructional unit, the potential of geospatial technologies for supporting student cultural identity development, and the value of school-university partnerships in promoting innovative teaching strategies in a high school classroom. 

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2. DEVELOPING GEOSPATIAL SCIENTISTS – USING STUDENTS AS PARTNERS IN DRONE RESEARCH

   https://doi.org/10.5194/isprs-archives-XLIV-M-2-2020-69-2020  

   McKee, T.; Hashemi-Beni, L. (January 2020, ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences)

   null (Ed.)

   Abstract. The U.S. Department of Labor Occupational Outlook Handbook predicts geospatial careers to increase much faster than average (15%) from 2018 to 2028 with no additional on-the-job training expected. Geospatial professionals can assist in promoting these career opportunities by mentoring high school students through real-world and transferable-skill building activities. The aim is to enhance students’ awareness and stimulate their interest towards STEM education and careers, especially in geospatial data analytics. This area of study incorporates a variety of modern-day tools for analyzing and mapping the Earth. The technology used offers a radically different way in which geospatial scientist produce and use the geospatial information required to manage a large variety of communities and industries. 

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3. Teacher Preparation and Student Participation in a GIS-Focused Computer Science Unit Impact Students’ Geospatial Thinking

   Pagano, Lauren C; Sotelo, Jose; McGee-Tekula, Randi; McGee, Steven; Kolvoord, Robert A; Uttal, David H (April 2024, American Educational Research Association)

   Experience with geographic information systems (GIS) can improve students’ spatial skills and provide a foundation for success in STEM (Jant et al., 2019). Researchers and educators co-designed a GIS unit in which high school students learned to use ArcGIS software by exploring geospatial patterns in their local communities. Across three teachers, 134 students participated in the unit and completed a geospatial problem-solving assessment. Students’ performance on the assessment significantly increased from pre- to post-test. Students whose teachers had more GIS experience and completed graded GIS assessments scored higher on geospatial assessments and used more spatial language than students whose teachers had less GIS experience and graded on participation. Students’ expectancy, value, and cost of computer science varied across teachers, and may be linked to students’ ability to devote time to mapbuilding and their engagement with a GIS careers guide. We discuss the impacts of teacher training and lesson implementation on students’ geospatial thinking. 

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4. Google Earth as a Tool for Supporting Geospatial Thinking

   https://doi.org/10.3390/land13122218  

   Jaeger, Allison J (December 2024, Land)

   In landscape planning and design, geospatial technologies (GSTs) are used to aid in visualizing and interpreting geographic environments, identifying geospatial patterns, and making decisions around information based on maps and geospatial information. GSTs are related to the different tools and technologies used to represent the earth’s surface and have transformed the practice of landscape design and geospatial education. These technologies play an important role in promoting the development and application of STEM-relevant geospatial thinking. Curricula that incorporate GSTs have been used across educational levels, from elementary school through college, and have been shown to support the development of geospatial learning and understanding. The present work discusses the use of one type of GST, virtual globes, as a tool for developing geospatial thinking, with a specific focus on Google Earth. This review highlights outcomes of several studies using Google Earth in the context of disciplines related to landscape design, such as geography and earth science. Furthermore, the potential mechanisms underlying the effectiveness of this technology for supporting the development of geospatial knowledge, such as its role in facilitating data visualization and supporting student’s ability to think flexibly about spatial patterns and relations, are discussed. Finally, the limitations of the current research on Google Earth as a tool for supporting geospatial learning are discussed, and suggestions for future research are provided. 

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5. Water in Geospatial Higher Education: A Discussion of Lessons Learned

   Ignatius, A.R.; Coleman, L.; Kurimo-Beechuk, E.; McDonald, J.; Milligan, R.; Mishra, D.R.; Page, M. (January 2021, Georgia Water Resources Conference)

   null (Ed.)

   Geospatial technologies and geographic methods are foundational skills in modern water resources monitoring, research, management, and policy-making. Understanding and sustaining healthy water resources depends on spatial awareness of watersheds, land use, hydrologic networks, and the communities that depend on these resources. Water professionals across disciplines are expected to have familiarity with hydrologic geospatial data. Proficiency in spatial thinking and competency reading hydrologic maps are essential skills. In addition, climate change and non-stationary ecological conditions require water specialists to utilize dynamic, time-enabled spatiotemporal datasets to examine shifting patterns and changing environments. Future water specialists will likely require even more advanced geospatial knowledge with the implementation of distributed internet-of-things sensor networks and the collection of mobility data. To support the success of future water professionals and increase hydrologic awareness in our broader communities, teachers in higher education must consider how their curriculum provides students with these vital geospatial skills. This paper considers pedagogical perspectives from educators with expertise in remote sensing, geomorphology, human geography, environmental science, ecology, and private industry. These individuals share a wealth of experience teaching geographic techniques such as GIS, remote sensing, and field methods to explore water resources. The reflections of these educators provide a snapshot of current approaches to teaching water and geospatial techniques. This commentary captures faculty experiences, ambitions, and suggestions for teaching at this moment in time. 

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