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1. Detoxification of bisphenol A via sulfur-mediated carbon–carbon σ-bond scission

   https://doi.org/10.1039/D2SU00138A  

   Thiounn, Timmy; Karunarathna, Menisha S.; Lauer, Moira K.; Tennyson, Andrew G.; Smith, Rhett C. (May 2023, RSC Sustainability)

   Environmental contamination with bisphenol A (BPA), produced via degradation of plastic waste, constitutes a major hazard for human health due to the ability of BPA to bind to estrogen receptors and thereby induce hormonal imbalances. Unfortunately, BPA cannot be degraded to a “safe” material without breaking C–C σ-bonds, and existing methods required to break these bonds employ petroleum-derived chemicals and environmentally-harmful metal ions. Therefore, there is an urgent need to develop new “green” methods to break BPA into monoaryl compounds without the use of such reagents and, ideally, convert those monoaryls into valuable materials that can be productively utilized instead of being discarded as chemical waste. Herein we report a new mechanism by which O , O ′-dimethyl bisphenol A (DMBPA), obtained from BPA-containing plastic via low-temperature recycling, undergoes C–C σ-bond cleavage via thiocracking, a reaction with elemental sulfur at temperatures lower than those used in many thermal plastic recycling techniques ( e.g. , <325 °C). Mechanistic analyses and microstructural characterization of the DMBPA-derived materials produced by thiocracking elucidated multiple subunits comprising monoaryl species. Impressively, analyses of recoverable organics revealed that >95% of DMBPA had been broken down into monoaryl components. Furthermore, the DMBPA–sulfur composite produced by thiocracking (BC90) exhibited compressive strength (∼20 MPa) greater than those of typical Portland cements. Consequently, this new thiocracking method creates the ability to destroy the estrogen receptor-binding components of BPA wastes using greener techniques and, simultaneously, to produce a mechanically-robust composite material that represents a sustainable alternative to Portland cements. 

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2. Roles of Organohalide-Respiring Dehalococcoidia in Carbon Cycling

   https://doi.org/10.1128/mSystems.00757-19  

   Yang, Yi; Sanford, Robert; Yan, Jun; Chen, Gao; Cápiro, Natalie L.; Li, Xiuying; Löffler, Frank E. (June 2020, mSystems)

   Bouskill, Nick (Ed.)

   ABSTRACT The class Dehalococcoidia within the Chloroflexi phylum comprises the obligate organohalide-respiring genera Dehalococcoides , Dehalogenimonas , and “ Candidatus Dehalobium.” Knowledge of the unique ecophysiology and biochemistry of Dehalococcoidia has been largely derived from studies with enrichment cultures and isolates from sites impacted with chlorinated pollutants; however, culture-independent surveys found Dehalococcoidia sequences in marine, freshwater, and terrestrial biomes considered to be pristine (i.e., not impacted with organohalogens of anthropogenic origin). The broad environmental distribution of Dehalococcoidia , as well as other organohalide-respiring bacteria, supports the concept of active halogen cycling and the natural formation of organohalogens in various ecosystems. Dechlorination reduces recalcitrance and renders organics susceptible to metabolic oxidation by diverse microbial taxa. During reductive dechlorination, hydrogenotrophic organohalide-respiring bacteria, in particular Dehalococcoidia , can consume hydrogen to low consumption threshold concentrations (<0.3 nM) and enable syntrophic oxidation processes. These functional attributes and the broad distribution imply that Dehalococcoidia play relevant roles in carbon cycling in anoxic ecosystems. 

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3. Hygroscopicity of nitrogen-containing organic carbon compounds: o -aminophenol and p -aminophenol

   https://doi.org/10.1039/D2EM00163B  

   Malek, Kotiba A.; Rastogi, Dewansh; Al-Abadleh, Hind A.; Asa-Awuku, Akua A. (July 2022, Environmental Science: Processes & Impacts)

   Nitrogen-containing Organic Carbon (NOC) is a major constituent of atmospheric aerosols and they have received significant attention in the atmospheric science community. While extensive research and advancements have been made regarding their emission sources, concentrations, and their secondary formation in the atmosphere, little is known about their water uptake efficiencies and their subsequent role in climate, air quality, and visibility. In this study, we investigated the water uptake of two sparingly soluble aromatic NOCs: o -aminophenol (oAP) and p -aminophenol (pAP) under subsaturated and supersaturated conditions using a Hygroscopicity Tandem Differential Mobility Analyzer (H-TDMA) and a Cloud Condensation Nuclei Counter (CCNC), respectively. Our results show that oAP and pAP are slightly hygroscopic with comparable hygroscopicities to various studied organic aerosols. The supersaturated single hygroscopicity parameter ( κ CCN ) was measured and reported to be 0.18 ± 0.05 for oAP and 0.04 ± 0.02 for pAP, indicating that oAP is more hygroscopic than pAP despite them having the same molecular formulae. The observed disparity in hygroscopicity is attributed to the difference in functional group locations, interactions with gas phase water molecules, and the reported bulk water solubilities of the NOC. Under subsaturated conditions, both oAP and pAP aerosols showed size dependent water uptake. Both species demonstrated growth at smaller dry particle sizes, and shrinkage at larger dry particle sizes. The measured growth factor ( G f ) range, at RH = 85%, for oAP was 1.60–0.74 and for pAP was 1.53–0.74 with increasing particle size. The growth and shrinkage dichotomy is attributed to morphological particle differences verified by TEM images of small and large particles. Subsequently, aerosol physicochemical properties must be considered to properly predict the droplet growth of NOC aerosols in the atmosphere. 

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4. Incandescence-based single-particle method for black carbon quantification in lake sediment cores: Black carbon in lake sediments

   https://doi.org/10.1002/lom3.10276  

   Chellman, N. J.; McConnell, J. R.; Heyvaert, A.; Vannière, B.; Arienzo, M. M.; Wennrich, V. (November 2018, Limnology and Oceanography: Methods)
5. The fate of carbon utilized by the subterranean termite Reticulitermes flavipes

   https://doi.org/10.1002/ecs2.3872  

   Myer, Angela; Myer, Mark H.; Trettin, Carl C.; Forschler, Brian T. (December 2021, Ecosphere)