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1. Physical Chemistry of Environmental Interfaces

   Grassian, Vicki H (October 2018, The Chemist)

   The 2018 Chemical Pioneer Award symposium provided an opportunity to give an overview of the physical chemistry of environmental interfaces. These interfaces include atmospheric aerosols, nanomaterials in the environment and indoor surfaces. As discussed below, detailed physical chemistry studies on these complex surfaces are challenging yet can provide important insights into processes occurring on interfaces in various indoor and outdoor environments. 

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2. Environmental performance of blue foods

   https://doi.org/10.1038/s41586-021-03889-2  

   Gephart, Jessica A.; Henriksson, Patrik J.; Parker, Robert W.; Shepon, Alon; Gorospe, Kelvin D.; Bergman, Kristina; Eshel, Gidon; Golden, Christopher D.; Halpern, Benjamin S.; Hornborg, Sara; et al (September 2021, Nature)

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3. The enigma of environmental organoarsenicals

   https://doi.org/10.1080/10643389.2021.1947678  

   Xue, Xi-Mei; Xiong, Chan; Yoshinaga, Masafumi; Rosen, Barry; Zhu, Yong-Guan (July 2021, Critical Reviews in Environmental Science and Technology)

   null (Ed.)

   Over 300 species of naturally occurring-organoarsenicals have been identified with the development of modern analytical techniques. Why there so many environmental organoarsenicals exist is a real enigma. Are they protective or harmful? Or are they simply by-products of existing pathways for non-arsenical compounds? Fundamental unanswered questions exist about their occurrence, prevalence and fate in the environment, metabolisms, toxicology and biological functions. This review focuses on possible answers. As a beginning, we classified them into two categories: water-soluble and lipid-soluble organoarsenicals (arsenolipids). Continual improvements in analytical techniques will lead to identification of additional organoarsenicals. In this review, we enumerate identified environmental organoarsenicals and speculate about their pathways of synthesis and degradation based on structural data and previous studies. Organoarsenicals are frequently considered to be nontoxic, yet trivalent methylarsenicals, synthetic aromatic arsenicals and some pentavalent arsenic-containing compounds have been shown to be highly toxic. The biological functions of some organoarsenicals have been defined. For example, arsenobetaine acts as an osmolyte, and membrane arsenolipids have a phosphate-sparing role under phosphate-limited conditions. However, the toxicological properties and biological functions of most organoarsenicals are largely unknown. The objective of this review is to summarize the toxicological and physiological properties and to provide novel insights into future studies. 

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4. Environmental impacts of biodegradable microplastics

   https://doi.org/10.1038/s44286-024-00127-0  

   Piao, Zhengyin; Agyei_Boakye, Amma_Asantewaa; Yao, Yuan (September 2024, Nature Chemical Engineering)

   Abstract Biodegradable plastics, perceived as ‘environmentally friendly’ materials, may end up in natural environments. This impact is often overlooked in the literature due to a lack of assessment methods. This study develops an integrated life cycle impact assessment methodology to assess the climate-change and aquatic-ecotoxicity impacts of biodegradable microplastics in freshwater ecosystems. Our results reveal that highly biodegradable microplastics have lower aquatic ecotoxicity but higher greenhouse gas (GHG) emissions. The extent of burden shifting depends on microplastic size and density. Plastic biodegradation in natural environments can result in higher GHG emissions than biodegradation in engineered end of life (for example, anaerobic digestion), contributing substantially to the life cycle GHG emissions of biodegradable plastics (excluding the use phase). A sensitivity analysis identified critical biodegradation rates for different plastic sizes that result in maximum GHG emissions. This work advances understanding of the environmental impacts of biodegradable plastics, providing an approach for the assessment and design of future plastics. 

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5. Environmental averaging

   https://doi.org/10.4171/EMSS/81  

   Shvydkoy, Roman (September 2024, EMS Surveys in Mathematical Sciences)

   Many classical examples of models of self-organized dynamics, including the Cucker–Smale, Motsch–Tadmor, multi-species, and several others, include an alignment force that is based upon density-weighted averaging protocol. Those protocols can be viewed as special cases of “environmental averaging”. In this paper we formalize this concept and introduce a unified framework for systematic analysis of alignment models.A series of studies are presented including the mean-field limit in deterministic and stochastic settings, hydrodynamic limits in the monokinetic and Maxwellian regimes, hypocoercivity and global relaxation for dissipative kinetic models, several general alignment results based on chain connectivity and spectral gap analysis. These studies cover many of the known results and reveal new ones, which include asymptotic alignment criteria based on connectivity conditions, new estimates on the spectral gap of the alignment force that do not rely on the upper bound of the macroscopic density, uniform gain of positivity for solutions of the Fokker–Planck-alignment model based on smooth environmental averaging. As a consequence, we establish unconditional relaxation result for global solutions to the Fokker–Planck-alignment model, which presents a substantial improvement over previously known perturbative results. 

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