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1. Dissolved inorganic carbon accumulating complexes from autotrophic bacteria from extreme environments

   https://doi.org/10.1128/JB.00377-21  

   Schmid, Sarah; Chaput, Dale; Breitbart, Mya; Hines, Rebecca; Williams, Samantha; Gossett, Hunter K.; Parsi, Sheila D.; Peterson, Rebecca; Whittaker, Robert A.; Tarver, Angela; et al (September 2021, Journal of Bacteriology)

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   In nature, concentrations of dissolved inorganic carbon (DIC; = CO 2 + HCO 3 - + CO 3 2- ) can be low, and autotrophic organisms adapt with a variety of mechanisms to elevate intracellular DIC concentrations to enhance CO 2 fixation. Such mechanisms have been well-studied in Cyanobacteria , but much remains to be learned about their activity in other phyla. Novel multi-subunit membrane-spanning complexes capable of elevating intracellular DIC were recently described in three species of bacteria. Homologs of these complexes are distributed among 17 phyla in Bacteria and Archaea, and are predicted to consist of one, two, or three subunits. To determine whether DIC accumulation is a shared feature of these diverse complexes, seven of them, representative of organisms from four phyla, from a variety of habitats, and with three different subunit configurations were chosen for study. A high-CO 2 requiring, carbonic anhydrase-deficient ( yadF - cynT - ) strain of E. coli Lemo21(DE3), which could be rescued via elevated intracellular DIC concentrations, was created for heterologous expression and characterization of the complexes. Expression of all seven complexes rescued the ability of E. coli Lemo21(DE3) yadF - cynT - to grow under low CO 2 conditions, and six of the seven generated measurably elevated intracellular DIC concentrations when their expression was induced. For complexes consisting of two or three subunits, all subunits were necessary for DIC accumulation. Isotopic disequilibrium experiments clarified that CO 2 was the substrate for these complexes. In addition, the presence of an ionophore prevented the accumulation of intracellular DIC, suggesting that these complexes may couple proton potential to DIC accumulation. IMPORTANCE To facilitate the synthesis of biomass from CO 2 , autotrophic organisms use a variety of mechanisms to increase intracellular DIC concentrations. A novel type of multi-subunit complex has recently been described, which has been shown to generate measurably elevated intracellular DIC concentrations in three species of bacteria, begging the question of whether these complexes share this capability across the 17 phyla of Bacteria and Archaea where they are found. This study shows that DIC accumulation is a trait shared by complexes with varied subunit structures, from organisms with diverse physiologies and taxonomies, suggesting that this trait is universal among them. Successful expression in E. coli suggests the possibility of their expression in engineered organisms synthesizing compounds of industrial importance from CO 2 . 

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2. Title Extreme Polarization Anisotropy in Resonant Third‐Harmonic Generation from Aligned Carbon Nanotube Films

   https://doi.org/10.1002/adma.202304082  

   Zhu, Song; Li, Wenkai; Yu, Shengjie; Komatsu, Natsumi; Baydin, Andrey; Wang, Fakun; Sun, Fangyuan; Wang, Chongwu; Chen, Wenduo; Tan, Chuan Seng; et al (June 2023, Advanced Materials)
3. Experimental evaluation on interlaminar shear strength of carbon nanomaterial z-threaded carbon fiber-reinforced polymer laminates after exposure to extreme elevated temperatures

   Warren, Ryan A; Hasan, Obaidul; Hsiao, Kuang-Ting (August 2025, International Conference on Composite Materials (ICCM))

   Previous studies have shown that carbon nanofiber (CNF) z-threaded carbon fiber-reinforced polymer (ZT-CFRP) laminates exhibit improved mechanical performance in comparison to traditional carbon fiber-reinforced polymer (CFRP) laminates when exposed to extreme elevated temperatures. Z-threaded reinforcement is a technique for strengthening the through-thickness of a laminate by introducing perpendicularly aligned carbon nanomaterial to be threading into the continuous fiber array. Improved performance has already been observed in properties such as interlaminar shear strength (ILSS) without extreme heat exposure, but there has also been evidence that z-thread inclusion may mitigate strength loss due to thermal degradation of the matrix. This study examined how ILSS was diminished in both CFRP and ZT-CFRP samples with matrix degradation caused by extreme temperature exposure. Test samples were heated to 350 ˚C for 10 minutes and then allowed to return to room temperature. SBS testing in accordance with ASTM D2344 was conducted on both untreated and heat-treated samples for comparison. All samples were at room temperature during testing. It was found that ZT-CFRP samples (with 0.5wt% CNF concentration the matrix) exhibited higher ILSS with and without heat treatment over the traditional CFRP samples with and without heat treatment by +33.96% and +25.12%, respectively. ZT-CFRP ILSS was found to decrease by 10.584 MPa (-14.56%) after the extreme heat treatment, while CFRP ILSS decreased by only 4.627 MPa (-8.53%). Microscopic image analysis was also performed to provide insight into how the CNF z-threads may have provided a mechanism for retaining ILSS performance even with matrix thermal degradation. 

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4. Extreme rainstorms drive exceptional organic carbon export from forested humid-tropical rivers in Puerto Rico

   https://doi.org/10.1038/s41467-022-29618-5  

   Clark, K. E.; Stallard, R. F.; Murphy, S. F.; Scholl, M. A.; González, G.; Plante, A. F.; McDowell, W. H. (December 2022, Nature Communications)

   Abstract Extreme rainfall events in the humid-tropical Luquillo Mountains, Puerto Rico export the bulk of suspended sediment and particulate organic carbon. Using 25 years of river carbon and suspended sediment data, which targeted hurricanes and other large rainstorms, we estimated biogenic particulate organic carbon yields of 65 ± 16 tC km −2 yr −1 for the Icacos and 17.7 ± 5.1 tC km −2 yr −1 for the Mameyes rivers. These granitic and volcaniclastic catchments function as substantial atmospheric carbon-dioxide sinks, largely through export of river biogenic particulate organic carbon during extreme rainstorms. Compared to other regions, these high biogenic particulate organic carbon yields are accompanied by lower suspended sediment yields. Accordingly, particulate organic carbon export from these catchments is underpredicted by previous yield relationships, which are derived mainly from catchments with easily erodible sedimentary rocks. Therefore, rivers that drain petrogenic-carbon-poor bedrock require separate accounting to estimate their contributions to the geological carbon cycle. 

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5. Wildfire and Extreme Rainfall Reduce Soil Carbon and Nitrogen Pools in a Semiarid Shrubland Ecosystem

   https://doi.org/10.1029/2025JG009183  

   Lipson, D A; Alvarez, A G; Brouwer, J N; Cleland, E E; Lively, J B; Parsons, D S; Rivas, Fortunato Vincente; Smith, K L; Varon, E L; Xu, X (February 2026, Journal of Geophysical Research: Biogeosciences)

   Abstract Due to a combination of anthropogenic causes, semi‐arid shrublands like those in California and other Mediterranean‐type ecosystems are increasingly subject to wildfires and variable rainfall, including drought and atmospheric rivers. Fire changes soil structure, leaving soils vulnerable to erosion and loss of organic matter (OM), especially when followed by intense rain events. However, interactions of fire and extreme rainfall are challenging to study due to their unpredictability and the complex interacting factors such as fire intensity, vegetation structure, topography, and soil type. This study took advantage of a wildfire, natural variation in rainfall, and a controlled rain‐shelter experiment to examine the interactions of fire and rain on soil structure and OM storage. Fire reduced organic carbon and nitrogen associated with particulate organic matter and water stable aggregates, and changed soil hydrology, slowing infiltration of water to deeper layers. The combination of rain shelters and the extreme rain fall year (2023) allowed us to evaluate threshold effects of rain in post‐fire soils: in 2023, there was a loss of total soil OM from burned relative to unburned plots; rain shelter effects on soil organic matter pools were only detectable in 2023; and the interactive effects of fire and rain shelters in this year reduced infiltration of rain into soil in burned areas exposed to full rain conditions. These results suggest a feedback mechanism in which fire causes loss of soil OM, damages soil structure, and decreases rainfall infiltration, increasing erosion through increased runoff and slowing recovery of soil structure. 

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