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1. One Step at a Time: Deepening Socio-technical Learning in Undergraduate ICT Externships to Bridge the Digital Divide

   Pickering, Cynthia ; Fisher, Erik ; Ross, Paul ( January 2021 , International Conference on Internet Technologies & Society)

   This paper describes the temporal progression of human and social dimensions that undergraduate information and communications technology (ICT) students realized during an experiential learning externship where they explored digital divide technology solutions for low-income neighborhoods in the surrounding urban community. The described research represents significant adaptation and use of socio-technical integration research (STIR) with undergraduate ICT students engaged in work based experiential learning to promote equity in STEM education, instill a sense of civic responsibility, and practice approaches to tackling complex societal problems. Methods used for the research study included: STIR, semi-structured interviews, and on-site group observations. Using STIR, an embedded social scientist conducted regular one-on-one dialogs with three of four student externs, to collaboratively describe each student’s consideration of human and social dimensions as part of their technical work, explore alternative choices and their potential outcomes, and engage in reflexive learning that in some cases, influenced deliberate changes to material and behavioral practices. The on-site observation of group activities within the ICT innovation center situated in the local urban community provided additional ecosystem context during technical solution design and development of the digital divide solution for local high schools and feeder schools. Outcomes for participating undergraduate ICT students showed: 1) Technology learning improvements for all students; 2) Capacity building to reflect, anticipate and respond to socio-technical interactions for some students; and 3) Each student was able to progress to a new level of socio-technical learning and decision making. Reflexive discourse with participants surfaced cultural assets and consideration of alternative knowledges in collaborative technology design, development, and implementation that can potentially lead to solutions that are more community centered now and in the future as the ICT students transition to the workforce. 

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2. Frameworks for Student Research Engagement on Interdisciplinary Civic-Engaged Projects

   Kweon, Byoung-Suk ; Belle, Lauren ; Fisher, Kim ; Burke, Tara ; Haghtalab, Joy ; Roy, Nirupam ; Bonsignore, Elizabeth ; Sachs, Naomi ; Roberts, Jennifer. ( January 2023 , The International Network for the Science of Team Science (INSciTS))

   Broadband infrastructure in urban parks may serve crucial functions including an amenity to boost overall park use and a bridge to propagate WiFi access into contiguous neighborhoods. This project: SCC:PG Park WiFi as a BRIDGE to Community Resilience has developed a new model —Build Resilience through the Internet and Digital Greenspace Exposure, leveraging off-the-shelf WiFi technology, novel algorithms, community assets, and local partnerships to lower greenspace WiFi costs. This interdisciplinary work leverages: computer science, information studies, landscape architecture, and public health. Collaboration methodologies and relational definitions across disciplines are still nascent —especially when paired with civic-engaged, applied research. Student researchers (UG/Grad) are excellent partners in bridging disciplinary barriers and constraints. Their capacity to assimilate multiple frameworks has produced refinements to the project’s theoretical lenses and suggested novel socio-technical methodology improvements. Further, they are excellent ambassadors to community partners and stakeholders. In BRIDGE, we tested two mechanisms to augment student research participation. In both, we leveraged a classic, curriculum-based model named the Partnership for Action Learning in Sustainability program (PALS). This campus-wide, community-engaged initiative pairs faculty and students with community partners. PALS curates economic, environmental, and social sustainability challenges and scopes projects to customize appropriate coursework that addresses identified challenges. Outcomes include: literature searches, wireframes, and design plans that target solutions to civic problems. Constraints include the short semester timeframe and curriculum-learning-outcome constraints. (1) On BRIDGE, Dr. Kweon executed a semester-based Landscape Architecture PALS 400-level-studio. 18 undergraduates conducted in-class and in-field work to assess community needs and proposed design solutions for future park-wide WiFi. Research topics included: community-park history, neighborhood demographics, case-study analysis, and land-cover characteristics. The students conducted an in-Park, community engagement session —via interactive posterboard surveys, to gain input on what park amenities might be redesigned or added to promote WiFi use. The students then produced seven re-design plans; one included a café/garden, with an eco-corridor that integrated technology with nature. (2) From the classic, curriculum-based PALS model we created a summer-intensive for our five research assistants, to stimulate interdisciplinary collaboration in their research tasks and co-analysis of project data products: experimental technical WiFi-setup, community survey results, and stakeholder needs-assessments. Students met weekly with each other and team leadership, exchanged journal articles, and attended joint research events. This model shows promise for integrating students more formally into an interdisciplinary research project. An end-of-intensive focus group highlighted, from the students’ perspective, the pro/cons of this model. Results: In contrasting the two mechanisms, our results include: Model 1 is tried-and-trued and produces standardized, reliable products. However, as work is group based, student independence is limited —to explore topics/themes of interest. Civic groups are typically thrilled with the diversity of action plans produced. Model 2 provides greater independence in student-learning outcomes, fosters interdisciplinary, “dictionary-building” that can be used by the full team, deepens methodological approaches, and allows for student stipend payments. Lessons learned: intensive time frame needed more research team support and ideally should be extended, when possible, over the full project-span. UMD-IRB#1785365-4; NSF-award: 2125526. 

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3. Advancing undergraduate research through regional community college partnerships at Portland State University

   Rice, A. ; Loikith, P. ; Murry, A. ( December 2023 , Transactions American Geophysical Union)

   Opportunities for undergraduate research in STEM programs at community colleges can be few where lower-division science curriculum emphasizes classroom and laboratory-based learning and research laboratories are limited in number. This is particularly true in the geosciences where specialized programs are extremely rare. Urban serving academic research institutions have a unique role and opportunity to partner with regional community college programs for undergraduate research early-on in student post-secondary educational experiences. Programs built for community college transfer students to urban serving undergraduate programs can serve to integrate students into major programs and help reduce transfer shock. The benefits of exploring research as an undergraduate scholar are numerous and include: building towards mastery of technical skills; developing problem-solving in a real-world environment; reading and digesting scientific literature; analyzing experimental and simulation data; working independently and as part of a team; developing a mentoring relationship with a research advisor; and building a sense of belonging and confidence in a scientific field. However, many undergraduate research internships are targeted towards junior-level STEM majors already engaged in upper-division coursework and considering graduate school which effectively excludes community college students from participating. The Center for Climate and Aerosol Research (CCAR) Research Experience for Undergraduate program at Portland State University serves to help build the future diverse research community. 10-week intern research experiences are paired with an expert faculty mentor are designed for students majoring in the natural/physical sciences but not necessarily with a background in climate or atmospheric science. Additional programmatic activities include: 1-week orientation and training using short courses, faculty research seminars, and hands-on group workshops; academic professional and career development workshops throughout summer; journal club activities; final presentations at end of summer CCAR symposium; opportunities for travel for student presentations at scientific conferences; and social activities. Open to all qualifying undergraduates, since 2014 the program recruits primarily from regional (Northwest) community colleges, rural schools, and Native American serving institutions; recruiting students who would be unlikely to be otherwise exposed to such opportunities at their home institution. Over the past 9 cohorts of REU interns (2014-2019), approximately one third of CCAR REU scholars are community colleges students. Here we present criteria employed for selection of REU scholars and an analysis of selection biases in a comparison of students from community colleges, 4-year colleges, and PhD granting universities. We further investigate differential outcomes in efficacy of the REU program using evaluation data to assess changes over the program including: knowledge, intrinsic motivation, extrinsic motivation, science identity, program satisfaction, and career aspirations. In this presentation, we present these findings along with supportive qualitative analyses and discuss their implications for community college students in undergraduate research programs in geosciences. 

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4. GIFTS: Making Research Experiences Meaningful through Critical Self-Reflection

   DeCrescenzo, Peter ; Jangha, S. ( June 2023 , American Society of Engineering Education)

   In this Great Ideas for Teaching Students (GIFTS) paper, we offer learning outcomes that we are beginning to recognize from our eight-week research experience for undergraduates (REU). There are four characteristics that have been found to be essential to success in Science, Technology, Engineering, and Mathematics (STEM) fields: a strong sense of STEM identity, scientific self-efficacy, a sense of belonging, and a psychological sense of community. This is especially true for first-year and transfer students pursuing STEM undergraduate degrees. A variety of studies have been published that go into detail about why these characteristics in particular have such a significant effect on student performance and retention. This paper will present Critical Self-Reflection as a practical way to integrate development of these characteristics into student research experiences to foster experiential learning that goes beyond increasing technical skills. STEM students are not often trained to critically self-reflect on their experiences in classroom and research settings. An inability for undergraduates to reflect intentionally on their experiences creates greater risk for attrition from STEM disciplines. Curated reflective experiences in collaborative learning settings can offer professional development opportunities to enhance students’ social and technical communication skills. There are four phases within the scaffolded Critical Self-Reflection framework: Learning to Reflect, Reflection for Action, Reflection in Action, and Reflection on Action. When applying the evidence-based practice, STEM undergraduate researchers describe their perceptions via three activities: creating a legacy statement, participating in facilitated dialogue sessions, and writing curated reflection journal entries within an REU. Through critical self-reflection exercises, we are beginning to find growth of first-year and transfer STEM undergraduates in the following areas: understanding of their role in the lab; confidence in their researcher identity; expression of agency; observation and communication skills; and intentionality for action. Participating in this self-reflection allows students to make meaning of their experience enabling them to hone the aforementioned characteristics that creates a pathway from their undergraduate experience to undergraduate degree completion, graduate degree attainment, and to the STEM workforce. 

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5. Shaping the macro-ethical reasoning of engineers through deliberate cultural practices

   Radoff, J. ; Turpen, C. A. ; Tomblin, D. ; Mogul, N. F. ; Agrawal, A. ; Elby, A. ( June 2023 , Paper presented at 2023 ASEE Annual Conference & Exposition, Baltimore , Maryland)

   Most engineering ethics education is segregated into particular courses that, from a student’s perspective, can feel disconnected from the technical education at the center of their programs. In part because of this disconnect, several immersive programs designed to train engineering students in socio-technical systems thinking have emerged in the U.S. in the past two decades. One pedagogical goal of these programs is to provide alternative ideologies and practices that counter dominant cultural paradigms that marginalize macroethical thinking and social justice perspectives in engineering schools. In theory, longer-term immersion in such programs can help students overcome these harmful ideologies. However, because of the difficult nature of studying cultural change, very few studies have attempted to provide a thick description of how these alternative cultural practices are influencing student perspectives on engineering practices. Our study offers a rare glimpse at student uptake of these practices in a multi-year Science, Technology, and Society (STS) living-learning program. Our study explores whether and how cultural practices within an STS program help students develop and sustain the resources for using a socio-technical systems thinking approach to engineering practice. We grounded our work in a cultural practices framework from Nasir and Kirshner [1] which roughly understands practice to be “a patterned set of actions performed by members of a group based on common purposes and expectations, with shared cultural values, tools, and meanings” ([2, p. 99] as cited in [3]). Our descriptions of collective enactments of cultural practices are grounded in accounts of classroom events from researcher fieldnotes and reflections in student interviews. Looking across the enactment of practices in classrooms and students’ interpretations of these events in interviews allows us to describe the multiplicity of meanings that students distill from these activities. This paper will present on multiple cultural practices salient to students we have identified in this STS community, for example: cultivating an ethics of care, making the invisible visible, understanding systems from multiple perspectives, and empowering students to develop moral stances as citizens and scientists/engineers in society. Because of the complexity of the interplay between the scaffolding of the STS program’s pedagogy and the emergence of these four themes, we chose to center “cultivating an ethics of care” in this analysis and relationally explore the other three themes through it. Ethics of care manifests in two basic ways in the data. Students talk about how an ethics of care is part of the STS program community and how the STS program fosters the need for an ethics of care toward communities outside the classroom through human-centered engineering design. 

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