Oleic acid-mediated synthesis of small-sized and monodisperse NiSe2 nanowires as counter electrode catalysts for triiodide reduction

Morphological engineering of monodispersed Co2P nanocrystals for efficient alkaline water and seawater splitting

Developing feasible synthetic strategies for preparing advanced nanomaterials with narrow size distributions and well-defined structures represents a cutting-edge field in alkaline water and seawater electrolysis. Herein, the monodispersed Co2P nanocrystals with tunable morphologies, namely one-dimensional nanorods (Co2P-R), nanoparticles (Co2P-P), and nanospheres (Co2P-S), were controllably synthesized by using a Schlenk system through optimizing the reactivity of cobalt- and phosphorus-based sources. The resulting Co2P-R exhibited superior electrocatalytic activity for both hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) in 1.0 M KOH, simulated seawater, and natural seawater. Impressively, the reconstructed active species effectively avoid the chlorine evolution on Co2P-R surface and facilitate OER process. Density functional theory (DFT) calculations revealed that Co2P-R exhibited an optimal d-band center (εd) and a lower energy barrier for the rate-determining steps in both HER and OER processes in comparison with Co2P-P and Co2P-S. Additionally, the Co2P-R showed a more favorable water adsorption energy (EH2O) over Cl- adsorption energy (ECl-), which contributes to its enhanced seawater electrolysis performance. The Co2P-R||Co2P-R electrolyzer achieves a low voltage of 1.70, 1.76, and 1.76 V at 100 mA cm-2 in alkaline freshwater, simulated seawater, and natural seawater, respectively, and demonstrates stable operation for 200 h at 100 mA cm-2.

Morphology-Guided Phase-Controlled Synthesis of Nickel Selenide Nanocrystals through Cation Exchange Reactions

The precise control of the crystal phase during the synthesis of nickel selenide (NixSey) nanocrystals is crucial, as crystal structure and composition significantly influence their reactivity, growth kinetics, and properties. The cation exchange (CE) method provides a versatile and robust approach for synthesizing nanomaterials, enabling precise control over phase, composition, and morphology. However, the application of this method for phase-controlled synthesis of NixSey nanocrystals has received limited research attention. Here, we present a morphology-guided CE method for the synthesis of spinel Ni3Se4 nanoparticles (NPs) and rhombic Ni3Se2 nanorods (NRs), wherein berzelianite Cu2-xSe NPs and NRs are employed as sacrificial templates for CE with Ni2+. This phase-controlled behavior, which is guided by morphology and dependent on the stacking length of the close-packed facets, relies on the rearrangement of the Se2- sublattice accompanied by CE, providing a unique and precise approach to controlling phase during nanocrystal synthesis. Additionally, the obtained Ni3Se4 NPs and Ni3Se2 NRs exhibit structure-dependent catalytic activities in the oxygen evolution reaction.

NIR-II driven photocatalytic hydrogen peroxide-supply on metallic copper-nickel selenide (Cu-Ni0.85Se) nanoparticle for synergistic therapy

Currently, finite intratumoral H₂O₂ content has restricted the efficacy of chemodynamic therapy (CDT). Here, Cu-Ni_0.85Se@PEG nanoparticles are constructed to display intracellular NIR-II photocatalytic H₂O₂ supplement. The formation mechanism is explored to discover that H₂O₂ generation is dominated by photo-excited electrons and dissolved O₂ via a typical sequential single-electron transfer process. Both density functional theory calculation and experimental data confirm its metallic feature that endows the great NIR-II absorption and photothermal conversion efficiency (59.6 %, 1064 nm). Furthermore, the photothermal-assisting consecutive interband and intraband transition in metallic catalyst contributes to the high redox capacity and efficient separation/transfer ability of photo-generated charges, boosting H₂O₂ production under 1064 nm laser irradiation. In addition, Cu-Ni_0.85Se@PEG possess mimic peroxidase and catalase activity, leading to in-situ H₂O₂ activation to produce ∙OH and O₂ for the enhanced CDT and hypoxia relief. What's more, the nanomaterials reveal novel biodegradation that is derived from oxidation from insolvable selenide into soluble selenate, resulting in elimination via feces and urine within 2 weeks. Synergistic CDT and photothermal therapy (PTT) further lead to great tumor inhibition and immune response for anti-tumor. The antitumor mechanism and the potential biological process also are investigated by high-throughput sequencing of expressed transcripts (RNAseq). The great treatment performance is responsible for the regulation of related oxidative stress and stimulus genes to induce organelle (mitochondrial) and membrane dysfunction. Besides, the synergistic therapy also can efficiently evoke immune response to further fight against tumor.

Ce2(MoO4)3 synthesized with oleylamine and oleic acid as additives for photocatalysis: effect of preparation method

Ce₂(MoO₄)₃ was prepared using dielectric barrier discharge (DBD) plasma method, co-precipitation method and hydrothermal method, respectively, with water/ethanol (W/O) as solvent, oleylamine (OAm) and oleic acid (OAc) as additives. Preparation method showed significant influence on the morphological and structural properties, as well as photocatalytic performance. Ce₂(MoO₄)₃ synthesized with DBD plasma (MO-P) was mainly flowerlike nanosheets, which were beneficial to promoting electron transfer and providing more space for catalytic activity. Also, MO-P samples exhibited more oxygen vacancies, which were conducive to the photocatalytic performance. What's more, MO-P showed lower PL intensity and narrow energy gap, which implied a slow photoelectron-hole pair recombination rate and an increased electron transfer rate. The degradation rate of methyl orange (50 mg/L) could achieve 98% within 12 min with 0.5 g/L MO-P. Hydroxyl radicals (·OH) and superoxide radicals (·O₂^-) played a major effect. Plasma synthesis method exhibited potential application prospect in photocatalysts preparation.