Infections caused by drug-resistant strains pose a serious threat to human health. Most bacterial infections are related to biofilms. The generation of bacterial biofilm greatly reduces the antibacterial efficiency of...
The morphologies of micromaterials play a key role in their functionality and efficiency across a broad range of applications, including catalysis, environmental remediation, and drug delivery. However, the relationships between the morphologies and performances of micromaterials still need to be further understood, to guide the rational design of effective morphologies for specific applications. A pollen‐derived microstructure library containing multivariate morphological characterization and functional performance data is proposed and constructed here. Systematic multivariate correlation analysis is conducted to extract the key morphological factors influencing the photocatalytic and adsorption efficiencies, to reveal the morpho–performance relationships of pollen‐derived microstructures. Subsequently, a chrysanthemum‐derived microstructure is selected as a typical candidate; it features a unique morphology suitable for advanced photocatalysis and dynamic environmental remediation. To summarize, the construction of a pollen‐derived microstructure library offers a powerful tool for studying the morpho–performance relationships of micromaterials; this can provide significant guidance and inspiration for the rational design of micro/nanomaterials for numerous applications.
Knowledge graph, originated from Semantic Web technology, is an emerging technology in the field of artificial intelligence (AI). As miscellaneous data and knowledge accumulate in power and energy system sections, an expert system with cognitive competence based on knowledge graph technologies can assist complex decision-making and quick response in relevant knowledge-intensive tasks. This study introduces the basic concept, key research progress and prospects of knowledge graphs, and their applications in low carbon power and energy systems.
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