Publications by authors named "Haoxuan Cai"

Biodegradable plastics (BPs) are known to decompose into micro-nano plastics (BMNPs) more readily than conventional plastics (CPs). Given the environmental risks posed by BMNPs in soil ecosystems, their impact has garnered increasing attention. However, research focusing on the toxic effects of BMNPs on soils remains relatively limited.

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A novel photocatalytic adsorbent, a cellulose nanofibrils based hydrogel incorporating carbon dots and BiO/BiOCOOH (designated as CCHBi), was developed to address lignin pollution. CCHBi exhibited an adsorption capacity of 435.0 mg/g, 8.

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Article Synopsis
  • The study focuses on how global warming-induced freezing and thawing cycles (FTCs) affect the biogeochemical cycling of carbon and nitrogen in soils, potentially increasing greenhouse gas (GHG) emissions.
  • It systematically evaluates the mechanisms behind these changes, looking at aspects like soil composition across different land types, soil structure, and microbial community responses to FTCs.
  • The research identifies challenges in translating lab results to real ecosystems and highlights the need for integrated methods to explore the complex interactions among carbon, nitrogen, and water in freeze-thaw processes.
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Hydrogel, a common carrier of photocatalyst that suffers from compromised catalytic efficiency, is still far from practical application. Herein, based on "computer chip-inspired design", a novel nanocellulose/carbon dots hydrogel (NCH) was fabricated as superior intensifier instead of common carrier of sodium titanate nanofibre (STN), where carbon dots (CDs) enhanced amino group-induced adsorption for Cr(VI), promoted photocatalytic properties of STN via transferring the photogenerated electron-hole pairs and improved amino group-induced desorption for reduced product (Cr(III)) via electrostatic repulsion, showing an efficiency of 1 + 1 > 2. Adsorption and photocatalysis experiments demonstrated superior removal performance of the NCH incorporating STN, as shown by theoretical maximum adsorption capacity of 425.

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