Renewable biomass reinvigorates sustainable water-energy nexus.

The water-energy nexus has garnered worldwide interest. Current dual-functional research aimed at co-producing freshwater and electricity faces significant challenges, including sub-optimal capacities ("1 + 1 < 2"), poor inter-functional coordination, high carbon footprints, and large costs. Mainstream water-to-electricity conversions are often compromised owing to functionality separation and erratic gradients. Herein, we present a sustainable strategy based on renewable biomass that addresses these issues by jointly achieving competitive solar-evaporative desalination and robust clean electricity generation. Using hydrothermally activated basswood, our solar desalination exceeded the 100% efficiency bottleneck even under reduced solar illumination. Through simple size-tuning, we achieved a high evaporation rate of 3.56 kg h-1 m-2 and an efficiency of 149.1%, representing 128%-251% of recent values without sophisticated surface engineering. By incorporating an electron-ion nexus with interfacial Faradaic electron circulation and co-ion-predominated micro-tunnel hydrodynamic flow, we leveraged free energy from evaporation to generate long-term electricity (0.38 W m-3 for over 14d), approximately 322% of peer performance levels. This inter-functional nexus strengthened dual functionalities and validated general engineering practices. Our presented strategy holds significant promise for global human-society-environment sustainability.

Preparation and properties of phase-change materials with enhanced radial thermal conductivities based on anisotropic graphene aerogels.

In this study, anisotropic graphene aerogels are prepared using the heat-flow method. Then, graphene aerogels with nanosilver particles are prepared via a silver mirror reaction. The aerogels are soaked in paraffin wax and the effects on the properties of the wax are investigated. The thermal conductivity of pure paraffin wax is 0.2553 W m-1 K-1. For the prepared PCM, the aerogel content was 0.92 vol%; this increases to 1.2234 W m-1 K-1, which corresponds to a thermal conductivity enhancement efficiency of 582%. The axial thermal conductivity is 1.4953 W m-1 K-1, which corresponds to a thermal conductivity enhancement efficiency of 746%. The graphene aerogels with the nanosilver particles show high phase-change efficiency. Owing to the significant improvements in the axial and thermal conductivities, the radial and axial heat transfer properties show good consistency suitable for practical applications.

Arsenic removal via a novel hydrochar from livestock waste co-activated with thiourea and γ-Fe2O3 nanoparticles.

Arsenic (As) contaminants post tremendous threats to environment safety. Pristine hydrochar (PHC), thiourea-activated hydrochar (THC), and thiourea-Fe(NO3)3-activated hydrochar (Fe2O3@THC) were fabricated from dairy cattle manure via one-pot hydrothermal carbonization at 250 â„ƒ and applied for aqueous As(V) removal. Fourier transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS) were conducted to characterize hydrochars and As(V) adsorption. Thiourea increased N and S functional groups (-NH2, C-N, C=S and S=O). Fe(NO3)3 introduced γ-Fe2O3 nanoparticles and provided Fe2O3@THC with Fe-O. The combination of thiourea and Fe(NO3)3 granted Fe2O3@THC with the largest surface area (33.45 m2/g), and the highest total pore volume (0.095 cm3/g) among three hydrochars. As(V) adsorption was a physicochemical process involving electrostatic attraction, complexation, ion exchange and H-bond interaction. The maximum As(V) adsorption capacities and partition coefficients decreased as follows: Fe2O3@THC (44.80 mg/g; 38.44 L/g) > THC (38.77 mg/g; 5.94 L/g) > PHC (19.05 mg/g; 1.17 L/g). Three hydrochars exhibited preferable reusability in NaOH solution with only 24.2%, 11.8% and 14.1% decrease in adsorption rates after four cycles for PHC, THC and Fe2O3@THC, respectively. Fe2O3@THC is a promising adsorbent for efficient As(V) removal. This study explored the efficient As(V) removal by activated hydrochars with future research potential.

Acetylcholinesterase inhibition effects of marine fungi.

CONTEXT: To this day, there are no reports that marine compounds isolated from microorganisms of the Lianyungang area of China have been used for the treatment of Alzheimer's disease. OBJECTIVE: The present study was to isolate fungi from the sea sediment of the Lianyungang area and screen for acetylcholineseterase inhibition activities of ethyl acetate extracts. MATERIALS AND METHODS: Fungi were isolated from the sea sediment and fermented. After centrifugation, the supernate was extracted with ethyl acetate. The ethyl acetate extract was then fractionated into five fractions. Acetylcholinesterase inhibition activities of the ethyl acetate extracts and five sub-fractions were tested at a concentration of 500 µg/mL with the Ellman's method. RESULTS: Forty-three marine fungi were isolated; 15 extracts inhibited acetylcholinestrease >50% and 3 extracts inhibited the acetylcholinesterase >80% at the concentration of 500 µg/mL. The 3 extracts (L1705, S1101, SH0701) inhibited AChE dose-dependently with IC50 values of 11.3 ± 1.2, 72.1 ± 2.3, and 7.8 ± 2.8 µg/mL, respectively. After the extract of SH0701 was fractionated into five fractions, the ethyl acetate fraction possessed the highest acetylcholinesterase inhibitory activity with an inhibition rate of 71.55% at the concentration of 10 µg/mL. The fungus SH0701 was identified as Aspergillus ochraceus SH0701 according to morphology and molecular identification. DISCUSSION AND CONCLUSION: The present results indicates that some ethyl acetate extracts of marine fungi isolated from Lianyungang area of China could inhibit AChE potently. Therefore, some novel AChE inhibitors might exist in those extracts.