A brightener-inspired polymer interphase enables highly reversible aqueous Zn anodes via suppressing side-reactions and manipulating the nucleation process.
The world's mounting demands for environmentally benign and efficient resource utilization have spurred investigations into intrinsically green and safe energy storage systems. As one of the most promising types of batteries, the Zn battery family, with a long research history in the human electrochemical power supply, has been revived and reevaluated in recent years. Although Zn anodes still lack mature and reliable solutions to support the satisfactory cyclability required for the current versatile applications, many new concepts with optimized Zn/Zn 2+ redox processes have inspired new hopes for rechargeable Zn batteries. In this review, we present a critical overview of the latest advances that could have a pivotal role in addressing the bottlenecks (e.g., nonuniform deposition, parasitic side reactions) encountered with Zn anodes, especially at the electrolyte-electrode interface. The focus is on research activities towards electrolyte modulation, artificial interphase engineering, and electrode structure design. Moreover, challenges and perspectives of rechargeable Zn batteries for further development in electrochemical energy storage applications are discussed. The reviewed surface/interface issues also provide lessons for the research of other multivalent battery chemistries with low-efficiency plating and stripping of the metal.
Tanhua et al. Ocean FAIR Data Services formats and made available through Web services is necessary. In particular, automation of data workflows will be critical to reduce friction throughout the data value chain. Adhering to the FAIR principles with free, timely, and unrestricted access to ocean observation data is beneficial for the originators, has obvious benefits for users, and is an essential foundation for the development of new services made possible with big data technologies.
Oxalate secretion by fungi is known to be associated with fungal pathogenesis. In addition, oxalate toxicity is a concern for the commercial application of fungi in the food and drug industries. Although oxalate is generated through several different biochemical pathways, oxaloacetate acetylhydrolase (OAH)-catalyzed hydrolytic cleavage of oxaloacetate appears to be an especially important route. Below, we report the cloning of the Botrytis cinerea oahA gene and the demonstration that the disruption of this gene results in the loss of oxalate formation. In addition, through complementation we have shown that the intact B. cinerea oahA gene restores oxalate production in an Aspergillus niger mutant strain, lacking a functional oahA gene. These observations clearly indicate that oxalate production in A. niger and B. cinerea is solely dependent on the hydrolytic cleavage of oxaloacetate catalyzed by OAH. In addition, the B. cinera oahA gene was overexpressed in Escherichia coli and the purified OAH was used to define catalytic efficiency, substrate specificity, and metal ion activation. These results are reported along with the discovery of the mechanism-based, tight binding OAH inhibitor 3,3-difluorooxaloacetate (K i ؍ 68 nM). Finally, we propose that cellular uptake of this inhibitor could reduce oxalate production.Numerous filamentous fungi, including the food biotechnology fungus Aspergillus niger, the opportunistic human pathogen Aspergillus fumigatus, the phytopathogenic fungi Botrytis cinerea and Sclerotinia sclerotiorum, as well as many brown-rot and white-rot basidiomycetes, are able to efficiently produce large quantities of oxalate (1, 2). It is known that oxalate secretion is associated with fungal pathogenesis (1, 3-6). In the wood-rotting fungus Fomitopsis palustris oxalate is formed as the product of glucose metabolism (7). We recently initiated investigations of the oxalate biosynthetic pathway to develop a genomic-based method for distinguishing between oxalate producing and non-producing fungi. An additional goal of this effort was to identify enzyme inhibitors that could be used to arrest oxalate formation in targeted fungi.To attenuate oxalate production in fungi, it is necessary to first identify the major pathway responsible for oxalate formation. There are three potential routes for production of oxalate in fungi: oxidation of glyoxylate (8, 9), oxidation of glycolaldehyde (10), and hydrolysis of oxaloacetate (11). The results of studies of [ 14 C]CO 2 incorporation into the metabolite pools of A. niger indicate that oxalate is derived from oxaloacetate (12). This finding parallels the results of earlier work on the purification of an enzyme "oxalacetalase" (now known as oxaloacetate acetylhydrolase or OAH) 4 that catalyzes the hydrolytic cleavage of oxaloacetate to form acetate and oxalate (11). In a subsequent study, a mutant A. niger strain, NW228 (13), was found to be deficient in both oxalate production and in the synthesis of active OAH (14). These observations suggest that oxalate is ...
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