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1. Building Ocean Science Capacity in Africa: Impacts and Challenges

   https://doi.org/10.5670/oceanog.2025.133  

   Saba, Abdulwakil; Elegbede, Isa; Ansong, Joseph; Eyo, Victor; Akpan, Precious; Sogbanmu, Temitope; Akinwunmi, Mosunmola; Merolyne, Natuhwera; Mohamed, Abdirahman; Nubi, Olubunmi; et al (January 2025, Oceanography)

   Capacity sharing in the ocean sciences is essential for addressing pressing environmental challenges and fostering sustainable stewardship of marine ecosystems. This article focuses on three important capacity-sharing programs operating in Africa: Early Career Ocean Professionals (ECOP) Africa, Citizen Observation of Local Litter in Coastal Ecosystems (COLLECT) (a project of the Partnership for Observation of the Global Ocean), and Mundus Maris Africa. ECOP Africa, a pioneering platform for early career ocean professionals, emphasizes mentorship, training, and knowledge exchange to empower young marine scientists across the continent. Through dynamic programs and events, ECOP Africa is catalyzing interdisciplinary collaboration and inspiring the next generation of ocean leaders. Similarly, COLLECT leverages citizen science to tackle plastic pollution in coastal environments. By training secondary school students as “citizen scientists,” COLLECT has not only generated critical data on the distribution and abundance of coastal debris but also fostered environmental awareness and local engagement. These initiatives demonstrate the power of inclusive, community-driven approaches to capacity sharing in the ocean sciences. They highlight the transformative potential of combining open science, education, and international collaboration to address global challenges such as plastic pollution and climate change while empowering local communities to take active roles in preserving their marine environments. 

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2. A Study on the Impact of a Sketch-based Tutoring System in Statics Instruction

   Viswanathan, V; Hurt, J; Hammond, T; Caldwell, B; Talley, K.; Linsey, J. (June 2020, ASEE annual conference)

   Large class sizes in engineering programs often prevent instructors from providing detailed and meaningful feedback to students on their homework problems. While the literature shows that frequent and immediate formative feedback has several benefits in terms of knowledge gain and academic motivation, several instructors struggle to provide any feedback. Motivated by this inability, a sketch-based virtual tutoring system, named Mechanix, has been developed and implemented. Mechanix lets the students to sketch their freebody diagram on a virtual interface and the process involved is very close to using a pencil and paper. The system provides real-time feedback on the accuracy of their Freebody diagrams and the solution to the problem. This paper reports the implementation of Mechanix at two large public universities in the United States – Georgia Institute of Technology and Texas State University. Mechanix is used to solve specific assignments from each school that involve the use of freebody diagrams. Pre- and post- concept inventories are used to measure the improvements in the conceptual understanding of the students. The results show that students who solve their homework using Mechanix outperform their peers who do not in one school, whereas the results are similar across the two groups in the second school. The evaluation of the concept inventories shows that the students who used Mechanix has the same level of improvement in their conceptual knowledge compared to the control group. 

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3. A Study on the Impact of a Sketch-based Tutoring System in Statics Instruction

   Viswanathan, V; Hurt, J; Hammond, T; Caldwell, B; Talley, K; Linsey, J (June 2020, Proceedings of the 2020 ASEE Annual Conference)

   Large class sizes in engineering programs often prevent instructors from providing detailed and meaningful feedback to students on their homework problems. While the literature shows that frequent and immediate formative feedback has several benefits in terms of knowledge gain and academic motivation, several instructors struggle to provide any feedback. Motivated by this inability, a sketch-based virtual tutoring system, named Mechanix, has been developed and implemented. Mechanix lets the students to sketch their freebody diagram on a virtual interface and the process involved is very close to using a pencil and paper. The system provides real-time feedback on the accuracy of their Freebody diagrams and the solution to the problem. This paper reports the implementation of Mechanix at two large public universities in the United States – Georgia Institute of Technology and Texas State University. Mechanix is used to solve specific assignments from each school that involve the use of freebody diagrams. Pre- and post- concept inventories are used to measure the improvements in the conceptual understanding of the students. The results show that students who solve their homework using Mechanix outperform their peers who do not in one school, whereas the results are similar across the two groups in the second school. The evaluation of the concept inventories shows that the students who used Mechanix has the same level of improvement in their conceptual knowledge compared to the control group. 

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4. Polar oceans and sea ice in a changing climate

   https://doi.org/10.1525/elementa.2023.00056  

   Willis, Megan D; Lannuzel, Delphine; Else, Brent; Angot, Hélène; Campbell, Karley; Crabeck, Odile; Delille, Bruno; Hayashida, Hakase; Lizotte, Martine; Loose, Brice; et al (January 2023, Elem Sci Anth)

   Polar oceans and sea ice cover 15% of the Earth’s ocean surface, and the environment is changing rapidly at both poles. Improving knowledge on the interactions between the atmospheric and oceanic realms in the polar regions, a Surface Ocean–Lower Atmosphere Study (SOLAS) project key focus, is essential to understanding the Earth system in the context of climate change. However, our ability to monitor the pace and magnitude of changes in the polar regions and evaluate their impacts for the rest of the globe is limited by both remoteness and sea-ice coverage. Sea ice not only supports biological activity and mediates gas and aerosol exchange but can also hinder some in-situ and remote sensing observations. While satellite remote sensing provides the baseline climate record for sea-ice properties and extent, these techniques cannot provide key variables within and below sea ice. Recent robotics, modeling, and in-situ measurement advances have opened new possibilities for understanding the ocean–sea ice–atmosphere system, but critical knowledge gaps remain. Seasonal and long-term observations are clearly lacking across all variables and phases. Observational and modeling efforts across the sea-ice, ocean, and atmospheric domains must be better linked to achieve a system-level understanding of polar ocean and sea-ice environments. As polar oceans are warming and sea ice is becoming thinner and more ephemeral than before, dramatic changes over a suite of physicochemical and biogeochemical processes are expected, if not already underway. These changes in sea-ice and ocean conditions will affect atmospheric processes by modifying the production of aerosols, aerosol precursors, reactive halogens and oxidants, and the exchange of greenhouse gases. Quantifying which processes will be enhanced or reduced by climate change calls for tailored monitoring programs for high-latitude ocean environments. Open questions in this coupled system will be best resolved by leveraging ongoing international and multidisciplinary programs, such as efforts led by SOLAS, to link research across the ocean–sea ice–atmosphere interface. 

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5. The Limits of Ocean Forcing on the Exchange Flow of the Salish Sea

   https://doi.org/10.1029/2025JC022384  

   Sanchez, R.; Giddings, S_N; Lemagie, E. (May 2025, Journal of Geophysical Research: Oceans)

   Abstract The dynamics of ocean‐estuary exchange depend on a variety of local and remote ocean forcing mechanisms where local mechanisms include those directly forcing the estuary such as tides, river discharge, and local wind stress; remote forcing includes forcing from the ocean such as coastal wind stress and coastal stratification variability. We use a numerical model to investigate the limits of oceanic influence, such as wind‐driven upwelling, on the Salish Sea exchange flow and salt transport. We find that along‐shelf winds substantially modulate flow throughout the Strait of Juan de Fuca until flow reaches sill‐influenced constrictions. At these constrictions the exchange flow variability becomes sensitive to local tidal and river forcing. The salt exchange variability is tidally dominated at Admiralty Inlet and upwelling has little impact on seasonal salt exchange variability. While within Haro Strait, the salt exchange variability is driven by a mix of coastal upwelling and local forcing including river discharge. There, the transition from oceanic to local control of salt exchange occurs over a longer distance and is primarily identifiable in the increasing variability of bulk outflowing salinity values. The differences between the two locations highlight how ocean variability interacts with both tidal pumping and gravitational circulation. We also distinguish between transient ocean forcing which can modify fjord properties near the mouth of the strait and seasonal ocean forcing which primarily affects along‐strait pressure gradients. The results have implications for understanding the transport variability of biogeochemical variables that are influenced by both along‐shelf winds and local sources. 

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