Regulating Oxygen Configuration in Hierarchically Porous Carbon Nanosheets for High-Rate and Durable Na+ Storage

Surface oxygen functionalities (particularly C−O configuration) in carbon materials have negative influence on their electrical conductivity and Na⁺ storage performance. Herein, we propose a concept from surface chemistry to regulate the oxygen configuration in hierarchically porous carbon nanosheets (HPCNS). It is demonstrated that the C−O/C=O ratio in HPCNS reduces from 1.49 to 0.43 and its graphitization degree increases by increasing the carbonization temperature under a reduction atmosphere. Remarkably, such high graphitization degree and low C−O content of the HPCNS-800 are favorable for promoting its electron/ion transfer kinetics, thus endowing it with high-rate (323.6 mAh g⁻¹ at 0.05 A g⁻¹ and 138.5 mAh g⁻¹ at 20.0 A g⁻¹) and durable (96 % capacity retention over 5700 cycles at 10.0 A g⁻¹) Na⁺ storage performance. This work permits the optimization of heteroatom configurations in carbon for superior Na⁺ storage.     

Biodegradable Black-Phosphorus-Nanosheet-Based Nanoagent for Enhanced Chemo-Photothermal Therapy

Black phosphorus nanosheet (BPNS) is a promising multifunctional material in the biomedical field with biodegradability and low side effects, however its features are always weakened severely owing to its poor stability. Here, a novel method is developed for improving the defect of BPNS based on the effective protection of poly(lactic-co-glycolic acid) (PLGA), which preserves the stable photothermal therapy (PTT) effect of BPNS and biodegradability of the material. Meanwhile, doxorubicin (DOX) is loaded on BPNS/PLGA to get BPNS/PLGA/DOX for further chemotherapy and preventing the recurrence of tumor after PTT. The presented combined therapeutic strategy exploits the strengths and improves the defects of BPNS, thus developing an efficient and safe nanoagent for cancer therapy, which affords and reveals the great potential of BPNS in nanomedicine.     

Fluorescence sensing of 2,4,6‐trinitrophenol based on hierarchical IRMOF‐3 nanosheets fabricated through a simple one‐pot reaction

Hierarchical IRMOF‐3 nanosheets were firstly fabricated by a simple reflux strategy and were then characterized through Fourier transform infrared spectroscopy, X‐ray diffraction, scanning electron microscopy, transmission electron microscopy and X‐ray photoelectron spectroscopy. They revealed a high fluorescence quantum yield (13.2%) and showed excellent selectivity and sensitivity for 2,4,6‐trinitrophenol (TNP) over a concentration range of 1–29 μM in aqueous solution. This work demonstrates that the facile fabrication method for hierarchical IRMOF‐3 nanosheets with favorable selectivity and sensitivity for TNP could produce a new point of view on novel metal–organic framework nanomaterials for on‐line detection of organic pollutants in water.     

Fabrication of an Electrochemical L‐Cysteine Sensor Based on Graphene Nanosheets Decorated Manganese Oxide Nanocomposite Modified Glassy Carbon Electrode

The graphene nanosheets/manganese oxide nanoparticles modified glassy carbon electrode (GC/GNSs/MnOx) was simply prepared by casting a thin film of GNSs on the GC electrode surface, followed by performing electrodeposition of MnOx at applied constant potential. The GC/GNSs/MnOx modified electrode shows high catalytic activity toward oxidation of L ‐cysteine. Hydrodynamic amperometry determination of L ‐cysteine gave linear responses over a concentration range up to 120 µM with a detection limit of 75 nM and sensitivity of 27 nA µM^?1. The GC/GNSs/MnOx electrode appears to be a highly efficient platform for the development of sensitive, stable and reproducible L ‐cysteine electrochemical sensors.     

Validity of Inorganic Nanosheets as an Efficient Planar Substituent To Enhance the Enantioselectivity of Transition‐Metal‐Catalyzed Asymmetric Synthesis

Effectively enhancing the enantioselectivity is a persistent challenge in heterogeneous asymmetric catalysis. Here, the validity of a layered double hydroxides (LDH) nanosheet as an efficient planar substituent to enhance the enantioselectivity has been investigated theoretically; first in vanadium‐catalyzed asymmetric epoxidation of allylic alcohols, and then in zinc‐catalyzed direct asymmetric aldol addition. The computational predication is further confirmed experimentally in zinc‐catalyzed direct asymmetric aldol addition by controlling the location of catalytic sites.     

Hydrothermal exfoliated molybdenum disulfide nanosheets as anode material for lithium ion batteries

Ultrathin MoS2nanosheets were prepared in high yield using a facile and effective hydrothermal intercalation and exfoliation route. The products were characterized in detail using X-ray diffraction, scanning electron microscopy, transmission electron microscopy and Raman spectroscopy. The results show that the high yield of MoS2nanosheets with good quality was successfully achieved and the dimensions of the immense nanosheets reached 1 μm–2 μm. As anode material for Li-ion batteries, the as-prepared MoS2nanosheets electrodes exhibited a good initial capacity of 1190 mAh g-1and excellent cyclic stability at constant current density of 50 mA g-1. After 50 cycles, it still delivered reversibly sustained high capacities of 750 mAh g-1.     

Introduction of high valent Mo6+ in Prussian blue analog derived Co-layered double hydroxide nanosheets for improved water splitting

Herein, we report a facile method for synthesizing MoCo-layered double hydroxide (LDH) nanosheets employing Prussian blue analog (PBA) as the precursor. The introduction of Mo in Co-LDH modulates the electronic structure, increases the number of active sites and electrochemical surface area to improve the hydrogen evolution, oxygen evolution, and overall water splitting activity. As a result, PBA-derived Mo_0.25Co_0.75-LDH nanosheets demonstrated 10 mA cm^?2 current density at only 220 mV and 115 mV overpotentials for OER and HER, respectively. The overall water splitting was attained at 1.52 V cell voltage for 10 mA cm^?2 current density.     

A Novel Carbon Nitride Nanosheets-based Electrochemical Sensor for Determination of Hydroxychloroquine in Pharmaceutical Formulation and Synthetic Urine Samples

This study introduces modified carbon paste electrodes with carbon nitride nanosheets (CNNS) and outlines their application for the determination of hydroxychloroquine sulfate (HCQ) in tablets and synthetic urine samples. CNNS were synthesized by hydrothermal route (200 °C, 10 h) using melamine and citric acid as their precursors. The carbon nitride nanosheets-based electrode (CNNS/E) presented a linear dynamic range for HCQ (LDR), ranging from 10.0 nmol l⁻¹ to 6.92 μmol l⁻¹, and detection (LOD) and quantification limits (LOQ) of 0.16 nmol l⁻¹ and 0.52 nmol l⁻¹, respectively. LOD and LOQ were calculated by the equations: LOD=3(S_d/b), and LOQ=10(S_d/b). The modified sensor presented excellent relative standard deviations for parameters such as repeatability (2.39 % and 1.87 %) and reproducibility (3.22 % and 2.32 %) in HCQ oxidation peaks (1 and 2). The CNNS/E has not shown significant variations in its anodic signal intensity in the presence of some organic and inorganic substances. It is worth bearing in mind that CNNS/E can be easily manufactured and the sensor has the lowest HCQ detection limits reported so far. The proposed sensor was successfully applied for HCQ determination in tablets and synthetic urine, showing good recovery values and an error of 0.60 % about comparative method in tablet samples, assuring the quality of the method.     

具有光控氧空缺的钼掺杂Bi5O7Br纳米片用于光催化氮气合成氨

氨(NH3)作为合成燃料、化肥和潜在能源载体的重要前体,是现代化学工业中最重要的化学品之一.工业中主要通过高能耗的Haber-Bosch工艺在高温高压下将氮气和氢气转化为NH3,而原料氢气由天然气蒸汽获得,因而不仅消耗大量能源,而且导致温室气体二氧化碳的大量排放,对环境造成危害.光催化固氮以光能为驱动力,以水为质子源,为合成NH3提供了一种温和、绿色和可持续的方法.然而,传统固氮催化剂具有与N2结合弱、成键难以及电子转移效率低的缺点.为了克服上述问题,在催化剂中引入氧空缺和过渡金属作为给电子中心和活性位点的策略被广泛研究.本文以半导体Bi5O7Br纳米片作为研究对象,通过在水热合成过程中添加Na2MoO4前驱盐在Bi5O7Br中掺杂钼元素,合成了不同摩尔含量的钼掺杂Bi5O7Br(Mo-Bi5O7Br)纳米片,并将其应用于光催化N2还原反应,发现Mo-Bi5O7Br的光催化固氮性能显著优于空白Bi5O7Br的催化性能.扫描电镜、透射电镜、能量色散X射线元素映射以及X射线光电子能谱的结果表明,掺杂过程不会影响Bi5O7Br纳米片的晶相和形貌,掺杂后钼元素均匀地分布在Bi5O7Br纳米片晶格中.采用紫外可见漫反射光谱、电子自旋共振光谱、氮气程序升温脱附谱以及光电化学测试等方法研究了Mo-Bi5O7Br相较于空白Bi5O7Br纳米片在光催化N2还原反应中催化性能提升的原因.UV-vis DRS结果表明,钼掺杂对Bi5O7Br可见光吸收能力具有增强作用.以催化NH3产率最高的Mo-Bi5O7Br-1(Mo摩尔百分含量为1％)为研究样本,EPR结果表明,在黑暗条件下,只有Mo-Bi5O7Br-1样品可以检测到明显的表面氧空位(OVs)信号;在光照条件下,Bi5O7Br和Mo-Bi5O7Br-1两种样品都出现OVs的信号峰,但同等光照时间下的Mo-Bi5O7Br-1具有更高的信号强度.此外,OVs信号会随着光照时间的延长逐渐增强;当移除光源后,信号强度逐渐降低.这表明Mo-Bi5O7Br-1在光照下会产生更高浓度的表面光控OVs.N2-TPD结果表明,光控OVs作为活性位点促进催化剂对N2的吸附.关闭光源后,OVs被环境中的水或氧气中的氧原子重新填充,避免了OVs易被氧化而导致反应失活的缺点,有助于保持Mo-Bi5O7Br-1催化N2还原反应的活性和稳定性.光电化学表征结果表明,Mo-Bi5O7Br-1中的光生载流子的分离和迁移效率明显提高.以上结果表明,掺杂过渡金属钼有助于Bi5O7Br纳米片表面光控OVs的生成,光控OVs作为活性位点提升了Bi5O7Br吸附和活化N2的能力,钼掺杂和光控OVs协同提高Bi5O7Br内部光生载流子的分离迁移效率,增强Bi5O7Br光催化固氮合成氨的反应性能.