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1. Evolutionary Insights into Digital Ecologies of Fear: Survey

   https://doi.org/10.3886/e232763v1  

   Fails, Jerry Alan; Ziker, John P; House, Kendall; Abele, Hollie (June 2025, ICPSR - Interuniversity Consortium for Political and Social Research)

   The internet is a virtual social environment, where it can be difficult to discern genuine threats. The goal of this research is to develop new insights into parents' perceptions of online risks to their children. The project focuses on the parents of children in middle childhood, ages 6-12. The main goal is to gain insights that will inform the development of digital environments that more accurately align online dangers and parental fears. To address this alignment, this project brings together experts in evolutionary anthropology, computer science, and digital experience design in a novel interdisciplinary collaboration. The project will shed light on a theoretical framing, the digital ecology of fear. The project will advance a burgeoning new area of research and design that can impact cybersecurity for families. 

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2. Using Design-based Research Methods to Scale in an Expanding Intervention

   Boyer, D. M.; & Duncan, L. A. (July 2021, ASEE Annual Conference proceedings)

   In this work-in-progress paper, we present design-based methodological work intended to support implementation of a large-scale, ongoing NSF Scholarships in STEM (S-STEM) project. We have created pilot tools and procedures for data collection and analysis that will supply consistent research throughlines during the project lifespan while also providing iterations of formative feedback about participants’ needs and their experiences in the project. While these tools and procedures have allowed us to analyze pilot data, in each year of the project, participant numbers will continue to grow, placing additional demands on our research team and our chosen methods. Will the designs we have created help us to scale effectively while remaining fidelitous to our project goals? The purpose of the S-STEM project is to connect student pathways at state technical colleges to Engineering and Computer Sciences programs at a Research I university in the southeastern United States. Toward this goal, we are implementing communities of practice and cognitive apprenticeship strategies to support student cohorts and create programming aspects to enhance transfer students’ enculturation to the university, completion of STEM-related degrees, and placement in the industrial workforce. Cohorts begin at the technical colleges, guided by a doctoral student mentor who engages program participants in applied research and shepherds them throughout their transition to the university. Now in the second year of the project, the pilot cohort is studying at the university while new cohorts are engaged at the collaborating technical colleges. Each year, the number of students participating in the five-year implementation will accumulate to a proposed total of over 300 students. Our research team will need to scale our efforts toward project fidelity. Our intent with this work-in-progress paper is to share our current status and invite interested colleagues to provide feedback about our pilot analysis work and our plans for future data. We will introduce the design-based methods that inform both research and development in our project. In particular, we will focus on the applicability of these methods for implementation work and how they can be effectively scaled to large interventions. We will describe observation, interview and focus group, and survey methods, along with how these methods complement academic sources and other student-related data. 

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3. Billion Oyster Project: Linking Public School Teaching and Learning to Ecological Restoration of New York Harbor Using Innovative Applications of Environmental and Digital Technologies

   Janis, Samuel; Birney, Lauren; Newton, Robert (January 2016, International journal of digital content technology and its applications)

   
Research consistently shows that children who have opportunities to actively investigate natural settings and engage in problem-based learning greatly benefit from the experiences. They gain skills, interests, knowledge, aspirations, and motivation to learn more. But how can we provide these rich opportunities in densely populated urban areas where resources and access to natural areas are limited? This project will develop and test a model of curriculum and community enterprise to address that issue within the nation's largest urban school system. Middle school students will study New York harbor and the extensive watershed that empties into it, and they will conduct field research in support of restoring native oyster habitats. The project builds on the existing Billion Oyster Project, and will be implemented by a broad partnership of institutions and community resources, including Pace University, the New York City Department of Education, the Columbia University Lamont-Doherty Earth Observatory, the New York Academy of Sciences, the New York Harbor Foundation, the New York Aquarium, and others.
The project focuses on an important concept in the geological, environmental, and biological sciences that typically receives inadequate attention in schools: watersheds. This project builds on and extends the Billion Oyster Project of the New York Harbor School. The project model includes five interrelated components: A teacher education curriculum, a student learning curriculum, a digital platform for project resources, an aquarium exhibit, and an afterschool STEM mentoring program. It targets middle-school students in low-income neighborhoods with high populations of English language learners and students from groups underrepresented in STEM fields and education pathways. The project will directly involve over forty schools, eighty teachers, and 8,640 students over a period of three years. A quasi-experimental, mixed-methods research plan will be used to assess the individual and collective effectiveness of the five project components. Regression analyses will be used to identify effective program aspects and assess the individual effectiveness of participation in various combinations of the five program components. Social network mapping will be used to further asses the overall "curriculum plus community" model. 

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4. Coupon Material Testing:Subtitle

   https://doi.org/10.17603/ds2-k0db-er44  

   Duke, Jessica; Sause, Richard; Ricles, James; Cao, Liang; Marullo, Thomas (January 2022, Designsafe-CI)

   This project will develop a new structural system that will protect buildings, their contents, and occupants during large earthquakes and will enable immediate post-earthquake occupancy. This earthquake-resilient structural system will be particularly valuable for essential facilities, such as hospitals, where damage to buildings and contents and occupant injuries must be prevented and where continuous occupancy performance is imperative. The new system will use practical structural components to economically protect a building from damaging displacements and accelerations. The project team will collaborate with Japanese researchers to study the new system with full-scale earthquake simulations using the 3D Full-Scale Earthquake Testing Facility (E-Defense) located in Miki, Japan, and operated by the National Research Institute for Earth Science and Disaster Resilience. This project will advance national health, prosperity, and welfare by preventing injuries and loss of human life and minimizing social and economic disruption of buildings due to large earthquakes. An online course on resilient seismic design will be developed and offered through the American Institute of Steel Construction night school program, which will be of interest to practicing engineers, researchers, and students across the country. This project contributes to NSF's role in the National Earthquake Hazards Reduction Program. The novel steel frame-spine lateral force-resisting system with force-limiting connections (FLC) that will be developed in this project will control multi-modal seismic response to protect a building and provide resilient structural and non-structural building performance. This frame-spine-FLC system will rely on a conventional, economical base system that resists a significant proportion of the lateral load. The system judiciously employs floor-level force-limiting deformable connections and an elastic spine to protect the base system. Integrated experiments and numerical simulations will provide comprehensive understanding of the new frame-spine-FLC system, including rich full-scale experimental data on building seismic performance with combined in-plane, out-of-plane, and torsional response under 3D excitation. The FLCs will be tested using the NHERI facility at Lehigh University. This project will be conducted in collaboration with an ongoing synergistic research program in Japan. The extensive dataset from this integrated U.S.-Japan research program will enable unique comparisons of structural and non-structural performance, including critical acceleration-sensitive hospital contents that directly affect the health and safety of patients. In addition, the dataset will enable the advancement of computational modeling for the assessment of building performance and the development of practical, accurate models for use in design that capture the complex 3D structural response that occurs during an earthquake. 

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5. Spine Specimen 1:Subtitle

   https://doi.org/10.17603/ds2-ft21-gm10  

   Duke, Jessica; Sause, Richard; Ricles, James; Cao, Liang; Marullo, Thomas (January 2022, Designsafe-CI)

   This project will develop a new structural system that will protect buildings, their contents, and occupants during large earthquakes and will enable immediate post-earthquake occupancy. This earthquake-resilient structural system will be particularly valuable for essential facilities, such as hospitals, where damage to buildings and contents and occupant injuries must be prevented and where continuous occupancy performance is imperative. The new system will use practical structural components to economically protect a building from damaging displacements and accelerations. The project team will collaborate with Japanese researchers to study the new system with full-scale earthquake simulations using the 3D Full-Scale Earthquake Testing Facility (E-Defense) located in Miki, Japan, and operated by the National Research Institute for Earth Science and Disaster Resilience. This project will advance national health, prosperity, and welfare by preventing injuries and loss of human life and minimizing social and economic disruption of buildings due to large earthquakes. An online course on resilient seismic design will be developed and offered through the American Institute of Steel Construction night school program, which will be of interest to practicing engineers, researchers, and students across the country. This project contributes to NSF's role in the National Earthquake Hazards Reduction Program. The novel steel frame-spine lateral force-resisting system with force-limiting connections (FLC) that will be developed in this project will control multi-modal seismic response to protect a building and provide resilient structural and non-structural building performance. This frame-spine-FLC system will rely on a conventional, economical base system that resists a significant proportion of the lateral load. The system judiciously employs floor-level force-limiting deformable connections and an elastic spine to protect the base system. Integrated experiments and numerical simulations will provide comprehensive understanding of the new frame-spine-FLC system, including rich full-scale experimental data on building seismic performance with combined in-plane, out-of-plane, and torsional response under 3D excitation. The FLCs will be tested using the NHERI facility at Lehigh University. This project will be conducted in collaboration with an ongoing synergistic research program in Japan. The extensive dataset from this integrated U.S.-Japan research program will enable unique comparisons of structural and non-structural performance, including critical acceleration-sensitive hospital contents that directly affect the health and safety of patients. In addition, the dataset will enable the advancement of computational modeling for the assessment of building performance and the development of practical, accurate models for use in design that capture the complex 3D structural response that occurs during an earthquake. 

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