Tailoring Advanced CdS Anisotropy-Driven Charge Spatial Vectorial Separation and Migration via In Situ Dual Co-Catalyst Synergistic Layout.

Tailoring advanced anisotropy-driven efficient separation and migration of photogenerated carriers is a pivotal stride toward enhancing photocatalytic activity. Here, CdS-MoS2 binary photocatalysts are tailored into a dumbbell shape by leveraging the rod-shaped morphology of CdS and employing an in situ tip-induction strategy. To further enhance the photocatalytic activity, an in situ photo-deposition strategy is incorporated to cultivate MnOx particles on the dumbbell-shaped CdS-MoS2 . The in situ deposition of MnOx effectively isolated the oxidatively active sites on the CdS surface, emphasizing the reductively active crystalline face of CdS, specifically the (002) face. Benefiting from its robust activity as a reduction active site, MoS2 adeptly captures photogenerated electrons, facilitating the reduction of H+ to produce hydrogen. The anisotropically driven separation of CdS photogenerated carriers markedly mitigates the Coulomb force or binding force of the photogenerated electrons, thus promoting a smoother migration toward the active site for photocatalytic hydrogen evolution. The hydrogen evolution rate of 35MnOx -CdS-MoS2 -3 surpasses that of CdS by nearly an order of magnitude, achieving a quantum efficiency of 22.30% at 450 nm. Under simulated solar irradiation, it attains a rate of 42.86 mmol g-1 h-1 . This work imparts valuable insights for the design of dual co-catalysts, anisotropy-driven spatial vectorial charge separation and migration, and the analysis of migration pathways of photogenerated carriers.

Rational Design and Construction of Graphdiyne (CnH2n-2) Based NiMoO4/GDY/CuO in Situ XPS Proved Double S-Scheme Heterojunctions for Photocatalytic Hydrogen Production.

As a new two-dimensional (2D) carbon hybrid material, graphdiyne has attracted much attention due to its good conductivity, adjustable electronic structure, and special electron transfer enhancement properties. In this work, graphdiyne/CuO and NiMoO4/GDY/CuO composite catalysts were prepared by cross coupling method and high temperature annealing method. The CuI introduced by clever design not only acts as a catalytic coupling but also as a precursor of CuO. The CuO produced by the postprocessing improves the inefficient charge separation of graphdiyne and provides a good acceptor for the consumption of unwanted holes. The good conductivity and strong reduction ability of graphdiyne play key roles in the performance improvement of the composite catalyst. Under the dual evidence of XPS and in situ XPS, the charge transfer mode of double S-scheme heterojunction with graphdiyne as the active site of hydrogen evolution is constructed reasonably, which not only gives full play to the performance advantages of graphdiyne but also effectively improves the separation efficiency of photogenerated carriers. In this study, a clean and efficient multicomponent system was constructed by graphdiyne, which opened up a broad application prospect in the field of photocatalytic hydrogen production.

P-Induced In Situ Construction of ZnCoMOF@CoP-5 S-Scheme Heterojunctions for Enhanced Photocatalytic H2 Evolution.

In view of the fact that the exposed catalytic active sites of single-metal MOFs cannot satisfy the efficient progress of the catalytic reaction, here we constructed a star-shaped bimetallic ZnCoMOF by introducing a Zn source by the partial ion exchange method and coprecipitation method. By controlling the quality of sodium hypophosphite, ZnCoMOF was subjected to different degrees of phosphating to optimize the experimental conditions. The introduction of the more electronegative P can attract more H+ to participate in the reduction reaction. The ZnCoMOF@CoP-5 S-scheme heterojunction was constructed in situ by generating CoP on the surface of ZnCoMOF under a PH3 reducing atmosphere, which exhibited excellent H2 evolution performance. This unique heterojunction effectively promotes the separation and transfer of e--h+ pairs, ensuring a strong redox capability. The best hydrogen-evolution performance of ZnCoMOF@CoP-5 under the EY sensitization system reaches 16 958 µmol h-1 g-1, which has significant advantages over the same type of materials and similar photocatalytic hydrogen-evolution work. Finally, the photocatalytic mechanism was demonstrated by an in situ XPS technique. Our work provides important ideas for the research of bimetallic MOFs in the field of photocatalytic hydrogen evolution.

Synergistic effect of the MoO2/CeO2 S-scheme heterojunction on carbon rods for enhanced photocatalytic hydrogen evolution.

The separation efficiency of photogenerated carriers is a key factor affecting photocatalytic hydrogen evolution activity. However, loading precious metals is a cost problem, so in this work cheap carbon rods are introduced into the S-scheme heterojunction of CeO2/MoO2 as electron transfer channels. The construction of the S-scheme heterojunction greatly improves the reduction activity of a single catalyst and effectively inhibits the recombination of photogenerated electrons and holes. The carbon rods at the interface between CeO2 and MoO2 can ensure the rapid transfer of space charge, thus significantly improving the separation efficiency of photogenerated carriers. The synergistic effect of these two promotes the composite catalyst's photocatalytic hydrogen evolution activity. After optimization, the photocatalytic hydrogen evolution amount of 30% CeO2/MoO2-C (6725 µmol g-1) is 18.6 and 2.43 times those of CeO2 (373 µmol g-1) and MoO2-C (2771 µmol g-1), respectively. 30% CeO2/MoO2-C showed good stability in the photocatalytic cycle experiment. Simultaneously, steady-state fluorescence and electrochemical characterization showed that the introduction of carbon rods promoted the spatial transfer of electrons. This work provides a new design idea and method for applying and developing the S-scheme heterojunction.

Detection of Hepatitis E Virus in Raw Pork and Pig Viscera As Food in Hebei Province of China.

Hepatitis E virus (HEV) is an important human pathogen with pigs serving as the main natural animal reservoir. In China, pork is the most popular meat, while pig viscera are also widely consumed. The aim of this study was to evaluate the prevalence of HEV among pigs at slaughter, and assess the presence of HEV in raw pork and pig viscera as food. Samples of pig blood, raw pork, liver, kidney, and blood curd were collected from slaughterhouse or (and) retail market. Anti-HEV antibody in serum samples was detected using enzyme-linked immunosorbent assay based on an ORF2 antigen sandwich kit. HEV RNA was tested by reverse transcription nested polymerase chain reaction (RT-nested PCR) and the viral load was further assessed using quantitative real-time PCR. The final amplicons of RT-nested PCR were sequenced and undergone phylogenetic analysis. Prevalence of antibodies to HEV was 90.4% (104/115) in pigs at slaughtered level, and one serum sample was HEV RNA positive (0.9%, 1/115). HEV RNA was detected in liver, kidney, and blood samples with positivity of 6.1% (7/114), 3.1% (4/129), and 1.2% (2/170) respectively with viral loads ranged 102.4-104.4 (2.4Log-4.4Log) genome equivalents per gram, but not in pork. The HEV RNA prevalence in both liver and kidney were statistically higher than in pork. Phylogenetic analysis showed that all obtained sequences belonged to HEV genotype 4, which were divided into subtypes 4a, 4b, 4d, and 4i, highly identical to the known human and swine HEV sequences in China. The results indicate that raw pig viscera are more likely to harbor HEV than pork, suggesting a higher transmission risk related to consuming pig organs.

High seroprevalence of hepatitis E virus in rabbit slaughterhouse workers.

Hepatitis E virus (HEV) was first detected in rabbits in the year 2009. Rabbit HEV is now known to be widely prevalent in rabbits and tentatively assigned into genotype 3 (HEV-3) as subgenotype-3ra (HEV-3ra). However, its role in human infection remains undetermined. This study was conducted to investigate the prevalence of HEV infection among rabbit slaughterhouse workers and to identify whether the workers exposed to rabbits are at a higher risk of HEV infection. Seventy-five workers at rabbit slaughterhouses and a control group of 421 general adults in the same area in Hebei province, China, were serologically examined for anti-HEV antibodies. HEV seroprevalences between the slaughterhouse workers and the general adults were compared. Age-adjusted prevalence of anti-HEV immunoglobulin G (IgG) in the rabbit slaughterhouse workers and control group was 46.1% and 10.8% respectively. The slaughterhouse workers had significantly higher seroprevalence and an approximately 6.9-fold increased risk for being seropositive for anti-HEV IgG as compared to the general population (odds ratio, 6.9; 95% CI: 4.3, 10.9). In slaughterhouse workers, anti-HEV IgG positive rate was positively associated with working years; in general adults, this rate was positively associated with age. The prevalence of anti-HEV immunoglobulin M (IgM) among exposed workers (6.7%) was significantly higher than that of control groups (1.2%). In conclusion, the seroprevalence of HEV is significantly higher in slaughterhouse workers than in general adults indicating that occupational exposure to rabbits is a potential risk factor for HEV infection.

Hepatitis E virus was not detected in feces and milk of cows in Hebei province of China: No evidence for HEV prevalence in cows.

Hepatitis E virus (HEV) is an important human pathogen, with pigs and other species serving as natural animal reservoirs. Recently, the report of detection of genotype 4 HEV in dairy milk with high positive rate in Yunnan province of China has attracted extensive attention. To assess the zoonotic risk of cows as HEV reservoir and transmission of HEV through dairy milk, 467 fecal samples of cows, 276 fresh milk samples, and 140 retail milk samples were collected across Hebei Province, China, from March 2017 to May 2018, and detected for HEV RNA. Fecal samples of rabbit or pig were also collected for HEV detection from farms of mixed farming with cows or farms neighboring cow farms. HEV RNA was not detected in any cow feces or in any milk samples, but 9.3% feces of pigs and 18.9% feces of rabbits were positive for HEV RNA. In addition, all of the dairy milk samples undergone HEV antigen and anti-HEV antibody detections, but none was positive. Phylogenetic analysis showed that all of the HEV isolates from pigs belonged to genotype 4 and those from rabbits were genotype 3-rabbit HEV. The results indicate that, currently in Hebei province of China, HEV is not apparently prevalent in cows and hence there is no zoonotic transmission risk through dairy milk towards humans, albeit the genotype 4 and 3 (rabbit) HEV are prevalent in pigs and rabbits respectively.