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1. Insights on Sustainability of Earth Science Data Infrastructure Projects

   https://doi.org/10.5334/dsj-2024-014  

   Virapongse, Arika; Gallagher, James; Tikoff, Basil (January 2024, Data Science Journal)

   We studied 11 long-term data infrastructure projects, most of which focused on the Earth Sciences, to understand characteristics that contributed to their project sustainability. Among our sample group, we noted the existence of three different types of project groupings: Database, Framework, and Middleware. Most efforts started as federally funded research projects, and our results show that nearly all became organizations in order to become sustainable. Projects were often funded for short time scales but had the long-term burden of sustaining and supporting open science, interoperability, and community building–activities that are difficult to fund directly. This transition from ‘project’ to ‘organization’ was challenging for most efforts, especially in regard to leadership change and funding issues.Some common approaches to sustainability were identified within each project grouping. Framework and Database projects both relied heavily on the commitment to, and contribution from, a disciplinary community. Framework projects often used bottom-up governance approaches to maintain the active participation and interest of their community. Database projects succeeded when they were able to position themselves as part of the core workflow for disciplinary-specific scientific research. Middleware projects borrowed heavily from sustainability models used by software companies, while maintaining strong scientific partnerships. Cyberinfrastructure for science requires considerable resources to develop and sustain itself, and much of these resources are provided through in-kind support from academics, researchers, and their institutes. It is imperative that more work is done to find appropriate models that help sustain key data infrastructure for Earth Science over the long-term. 

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2. My Trajectory in Molecular Reaction Dynamics and Spectroscopy

   https://doi.org/10.1146/annurev-physchem-090519-124238  

   Gerber, Robert Benny (April 2021, Annual Review of Physical Chemistry)

   null (Ed.)

   This is the story of a career in theoretical chemistry during a time of dramatic changes in the field due to phenomenal growth in the availability of computational power. It is likewise the story of the highly gifted graduate students and postdoctoral fellows that I was fortunate to mentor throughout my career. It includes reminiscences of the great mentors that I had and of the exciting collaborations with both experimentalists and theorists on which I built much of my research. This is an account of the developments of exciting scientific disciplines in which I was involved: vibrational spectroscopy, molecular reaction mechanisms and dynamics, e.g., in atmospheric chemistry, and the prediction of new, exotic molecules, in particular noble gas molecules. From my very first project to my current work, my career in science has brought me the excitement and fascination of research. What a wonderful pursuit! 

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3. Integrating authentic geoscience research into K–12 education via measurement of microbial extracellular enzymes in natural waters: A case report of two initiatives

   Steen, Andrew D; Biongiorno, J; Rearden, K; Coleman-King, Chonika; Drumheller, Stephanie K; Phillips, Elise K; Stokes, Murray; Lloyd, Karen G (June 2025, Special paper Geological Society of America)

   MacDonald, James H; Clary, Renee M; Archer, Reginald; Broadway, Ruby (Ed.)

   Participation in authentic scientific research has been shown to greatly benefit undergraduate students, both in terms of perception of science and knowledge of scientific concepts. We define authentic scientific research as projects in which results are unknown prior to performing experiments and are appropriate for presentation in peer-reviewed scientific journals and/or scientific conferences. Kindergarten through grade 12 (K–12) students have less frequent opportunities to participate in authentic research than university students, and the effects of research participation on such students are less well understood. From 2013 to the present, we organized two collaborations with different groups of K–12 students and teachers, each aimed at engaging K–12 students in authentic geoscience research, with a focus on K–12 students from excluded backgrounds who may have had restricted access to resources. First, the Malcolm X Shabazz Aquatic Geochemistry Team was an initiative to involve high school students at Malcolm X Shabazz High School in Newark, New Jersey, USA, in research focused on the activities of microbial communities inhabiting streams and rivers in New Jersey and eastern Pennsylvania. Second, the Integrating Continuous Experiential Activities for Geoscience Education (ICE-AGE) project is a Pathways into the Earth, Ocean, Polar and Atmospheric & Geospace Sciences (GEOPAths) project funded by the National Science Foundation that involves K–12 students in experiential learning through diverse means, including involving middle school students taking part in a summer program pseudonymously referred to as the Liberation Literacy Program (LLP) in geoscience research on a number of topics. Here, we report qualitative observations of the successes and challenges of these programs, as well as lessons learned, which may be useful for other researchers seeking to involve groups of K–12 students in authentic geoscience research education. 

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4. The air-sea interface in a changing climate: Research advances and future directions

   https://doi.org/10.1525/elementa.2025.00022  

   Law, Cliff S; Miller, Lisa A (January 2025, Elem Sci Anth)

   At the end of its second decade, the Surface Ocean-Lower Atmosphere Study (SOLAS) continues to expand critical collaborations in Earth system research, opening new gateways between the disciplines of oceanic and atmospheric science. The collection of papers in this Special Feature highlights important recent advances in air-sea interaction science, emphasizing emerging priorities and critical challenges. Since the last SOLAS synthesis in 2014, the community has gained a more nuanced understanding of the variety of marine sources of atmospheric aerosols; the influence of chemical speciation on atmospheric deposition and resulting biogeochemical impacts in the ocean; the mechanistic microscale controls of aerosol production and gas exchange at the sea surface; and also how air-sea exchange processes are influencing and responding to climate change, among numerous other advances. At the same time, SOLAS scientists have engaged more directly with socio-economic networks and in the development and evaluation of environmental and policy decisions. In addition to substantial contributions to improved understanding of the global cycling of greenhouse gases, SOLAS scientists are examining the impacts of new shipping regulations and contributing to development of frameworks for climate intervention research and governance. However, challenges remain, including characterizing the variability in air-sea gas exchange, particularly in coastal regions, and identifying mechanisms by which marine emissions influence cloud dynamics and thereby coupled marine and atmospheric feedbacks to climate change. Addressing these and other challenges requires development of innovative scientific tools (e.g., chemical sensors, expanded and integrated observational networks, machine learning algorithms), and also new inter- and trans-disciplinary collaborations, to ensure that air-sea exchange research continues to transcend boundaries in tackling current and emerging global challenges. 

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5. Nine Lessons about Aquatic Invasive Species from the North Temperate Lakes Long-Term Ecological Research (NTL-LTER) Program

   https://doi.org/10.1093/biosci/biae062  

   Vander_Zanden, M_Jake; Gorsky, Adrianna; Hansen, Gretchen_J_A; Johnson, Pieter_T_J; Latzka, Alexander_W; Mikulyuk, Alison; Rohwer, Robin_R; Spear, Michael_J; Walsh, Jake_R (August 2024, BioScience)

   Abstract Freshwater ecosystems can serve as model systems that reveal insights into biological invasions. In this article, we summarize nine lessons about aquatic invasive species from the North Temperate Lakes Long-Term Ecological Research program and affiliated projects. The lessons about aquatic invasive species are as follows: Invasive species are more widespread than has been documented; they are usually at low abundance; they can irrupt from low-density populations in response to environmental triggers; they can occasionally have enormous and far-reaching impacts; they can affect microbial communities; reservoirs act as invasive species hotspots; ecosystem vulnerability to invasion can be estimated; invasive species removal can produce long-term benefits; and the impacts of invasive species control may be greater than the impacts of the invasive species. This synthesis highlights how long-term research on a freshwater landscape can advance our understanding of invasions. 

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