Microwave shock motivating the Sr substitution of 2D porous GdFeO_(3) perovskite for highly active oxygen evolution

The incorporation of partial A-site substitution in perovskite oxides represents a promising strategy for precisely controlling the electronic configuration and enhancing its intrinsic catalytic activity.Conventional methods for A-site substitution typically involve prolonged high-temperature processes.While these processes promote the development of unique nanostructures with highly exposed active sites,they often result in the uncontrolled configuration of introduced elements.Herein,we present a novel approach for synthesizing two-dimensional(2D)porous GdFeO_(3) perovskite with A-site strontium(Sr)substitution utilizing microwave shock method.This technique enables precise control of the Sr content and simultaneous construction of 2D porous structures in one step,capitalizing on the advantages of rapid heating and cooling(temperature~1100 K,rate~70 K s^(-1)).The active sites of this oxygen-rich defect structure can be clearly revealed through the simulation of the electronic configuration and the comprehensive analysis of the crystal structure.For electrocatalytic oxygen evolution reaction application,the synthesized 2D porous Gd_(0.8)Sr_(0.2)FeO_(3) electrocatalyst exhibits an exceptional overpotential of 294 mV at a current density of 10 mA cm^(-2)and a small Tafel slope of 55.85 mV dec^(-1)in alkaline electrolytes.This study offers a fresh perspective on designing crystal configurations and the construction of nanostructures in perovskite.

Boosting Hydrogen Storage Performance of MgH_(2) by Oxygen Vacancy-Rich H-V_(2)O_(5) Nanosheet as an Excited H-Pump

MgH_(2) is a promising high-capacity solid-state hydrogen storage material,while its application is greatly hindered by the high desorption temperature and sluggish kinetics.Herein,intertwined 2D oxygen vacancy-rich V_(2)O_(5) nanosheets(H-V_(2)O_(5))are specifically designed and used as catalysts to improve the hydrogen storage properties of MgH_(2).The as-prepared MgH_(2)-H-V_(2)O_(5) composites exhibit low desorption temperatures(Tonset=185℃)with a hydrogen capacity of 6.54 wt%,fast kinetics(Ea=84.55±1.37 kJ mol^(-1) H_(2) for desorption),and long cycling stability.Impressively,hydrogen absorption can be achieved at a temperature as low as 30℃ with a capacity of 2.38 wt%within 60 min.Moreover,the composites maintain a capacity retention rate of~99%after 100 cycles at 275℃.Experimental studies and theoretical calculations demonstrate that the in-situ formed VH_(2)/V catalysts,unique 2D structure of H-V_(2)O_(5) nanosheets,and abundant oxygen vacancies positively contribute to the improved hydrogen sorption properties.Notably,the existence of oxygen vacancies plays a double role,which could not only directly accelerate the hydrogen ab/de-sorption rate of MgH_(2),but also indirectly affect the activity of the catalytic phase VH_(2)/V,thereby further boosting the hydrogen storage performance of MgH_(2).This work highlights an oxygen vacancy excited“hydrogen pump”effect of VH_(2)/V on the hydrogen sorption of Mg/MgH_(2).The strategy developed here may pave a new way toward the development of oxygen vacancy-rich transition metal oxides catalyzed hydride systems.

Physical mechanism of oxygen diffusion in the formation of Ga_(2)O_(3) Ohmic contacts

The formation of low-resistance Ohmic contacts in Ga_(2)O_(3) is crucial for high-performance electronic devices. Conventionally, a titanium/gold(Ti/Au) electrode is rapidly annealed to achieve Ohmic contacts, resulting in mutual diffusion of atoms at the interface. However, the specific role of diffusing elements in Ohmic contact formation remains unclear.In this work, we investigate the contribution of oxygen atom diffusion to the formation of Ohmic contacts in Ga_(2)O_(3). We prepare a Ti/Au electrode on a single crystal substrate and conduct a series of electrical and structural characterizations.Using density functional theory, we construct a model of the interface and calculate the charge density, partial density of states, planar electrostatic potential energy, and I–V characteristics. Our results demonstrate that the oxygen atom diffusion effectively reduces the interface barrier, leading to low-resistance Ohmic contacts in Ga_(2)O_(3). These findings provide valuable insights into the underlying mechanisms of Ohmic contact formation and highlight the importance of considering the oxygen atom diffusion in the design of Ga_(2)O_(3)-based electronic devices.

Designing ultrastable P2/O3-type layered oxides for sodium ion batteries by regulating Na distribution and oxygen redox chemistry

P2/O3-type Ni/Mn-based layered oxides are promising cathode materials for sodium-ion batteries(SIBs)owing to their high energy density.However,exploring effective ways to enhance the synergy between the P2 and 03 phases remains a necessity.Herein,we design a P2/O3-type Na_(0.76)Ni_(0.31)Zn_(0.07)Mn_(0.50)Ti_(0.12)0_(2)(NNZMT)with high chemical/electrochemical stability by enhancing the coupling between the two phases.For the first time,a unique Na*extraction is observed from a Na-rich O3 phase by a Na-poor P2 phase and systematically investigated.This process is facilitated by Zn^(2+)/Ti^(4+)dual doping and calcination condition regulation,allowing a higher Na*content in the P2 phase with larger Na^(+)transport channels and enhancing Na transport kinetics.Because of reduced Na^(+)in the O3 phase,which increases the difficulty of H^(+)/Na^(+) exchange,the hydrostability of the O3 phase in NNZMT is considerably improved.Furthermore,Zn^(2+)/Ti^(4+)presence in NNZMT synergistically regulates oxygen redox chemistry,which effectively suppresses O_(2)/CO_(2) gas release and electrolyte decomposition,and completely inhibits phase transitions above 4.0 V.As a result,NNZMT achieves a high discharge capacity of 144.8 mA h g^(-1) with a median voltage of 3.42 V at 20 mA g^(-1) and exhibits excellent cycling performance with a capacity retention of 77.3% for 1000 cycles at 2000 mA g^(-1).This study provides an effective strategy and new insights into the design of high-performance layered-oxide cathode materials with enhanced structure/interface stability forSIBs.

CO_(2)capture costs of chemical looping combustion of biomass:A comparison of natural and synthetic oxygen carrier

Chemical looping combustion has the potential to be an efficient and low-cost technology capable of contributing to the reduction of the atmospheric concentration of CO_(2) in order to reach the 1.5/2°C goal and mitigate climate change.In this process,a metal oxide is used as oxygen carrier in a dual fluidized bed to generate clean CO_(2) via combustion of biomass.Most commonly,natural ores or synthetic materials are used as oxygen carrier whereas both must meet special requirements for the conversion of solid fuels.Synthetic oxygen carriers are characterized by higher reactivity at the expense of higher costs versus the lower-cost natural ores.To determine the viability of both possibilities,a techno-economic comparison of a synthetic material based on manganese,iron,and copper to the natural ore ilmenite was conducted.The synthetic oxygen carrier was characterized and tested in a pilot plant,where high combustion efficiencies up to 98.4%and carbon capture rates up to 98.5%were reached.The techno-economic assessment resulted in CO_(2) capture costs of 75 and 40€/tCO_(2) for the synthetic and natural ore route respectively,whereas a sensitivity analysis showed the high impact of production costs and attrition rates of the synthetic material.The synthetic oxygen carrier could break even with the natural ore in case of lower production costs and attrition rates,which could be reached by adapting the production process and recycling material.By comparison to state-of-the-art technologies,it is demonstrated that both routes are viable and the capture cost of CO_(2) could be reduced by implementing the chemical looping combustion technology.

Engineering of oxygen vacancy and bismuth cluster assisted ultrathin Bi_(12)O_(17)Cl_(2)nanosheets with efficient and selective photoreduction of CO_(2)to CO

The photocatalytic conversion of CO_(2)into solar‐powered fuels is viewed as a forward‐looking strategy to address energy scarcity and global warming.This work demonstrated the selective photoreduction of CO_(2)to CO using ultrathin Bi_(12)O_(17)Cl_(2)nanosheets decorated with hydrothermally synthesized bismuth clusters and oxygen vacancies(OVs).The characterizations revealed that the coexistences of OVs and Bi clusters generated in situ contributed to the high efficiency of CO_(2)–CO conversion(64.3μmol g^(−1)h^(−1))and perfect selectivity.The OVs on the facet(001)of the ultrathin Bi_(12)O_(17)Cl_(2)nanosheets serve as sites for CO_(2)adsorption and activation sites,capturing photoexcited electrons and prolonging light absorption due to defect states.In addition,the Bi‐cluster generated in situ offers the ability to trap holes and the surface plasmonic resonance effect.This study offers great potential for the construction of semiconductor hybrids as multiphotocatalysts,capable of being used for the elimination and conversion of CO_(2)in terms of energy and environment.

Ultrafine ordered L1_(2)-Pt-Co-Mn ternary intermetallic nanoparticles as high-performance oxygen-reduction electrocatalysts for practical fuel cells

The long-range periodically ordered atomic structures in intermetallic nanoparticles(INPs)can significantly enhance both the electrocatalytic activity and electrochemical stability toward the oxygen reduction reaction(ORR)compared to the disordered atomic structures in ordinary solid-solution alloy NPs.Accordingly,through a facile and scalable synthetic method,a series of carbon-supported ultrafine Pt_3Co_(x)Mn_(1-x)ternary INPs are prepared in this work,which possess the"skin-like"ultrathin Pt shells,the ordered L1_(2) atomic structure,and the high-even dispersion on supports(L1_(2)-Pt_3Co_(x)Mn_(1-x)/~SPt INPs/C).Electrochemical results present that the composition-optimized L1_(2)-Pt_3Co_(0.7)Mn_(0.3)/~SPt INPs/C exhibits the highest electrocata lytic activity among the series,which are also much better than those of the pristine ultrafine Pt/C.Besides,it also has a greatly enhanced electrochemical stability.In addition,the effects of annealing temperature and time are further investigated.More importantly,such superior ORR electrocatalytic performance of L1_(2)-Pt_3Co_(0.7)Mn_(0.3)/~SPt INPs/C are also well demonstrated in practical fuel cells.Physicochemical characterization analyses further reveal the major origins of the greatly enhanced ORR electrocata lytic performance:the Pt-Co-Mn alloy-induced geometric and ligand effects as well as the extremely high L1_(2) atomic-ordering degree.This work not only successfully develops a highly active and stable ordered ternary intermetallic ORR electrocatalyst,but also elucidates the corresponding"structure-function"relationship,which can be further applied in designing other intermetallic(electro)catalysts.

Increased Oxygen Vacancies in CuO-ZnO Snowflake-like Composites Drive the Hydrogenation of CO_(2) to Methanol

Cu/ZnO is widely used in the hydrogenation of carbon dioxide (CO_(2)) to methanol (CH_(3)OH) to improve the lowconversion rate and selectivity generally observed. In this work, a series of In, Zr, Co, and Ni-doped CuO-ZnO catalysts wassynthesized via a hydrothermal method. By introducing a second metal element, the activity and dispersion of the activesites can be adjusted and the synergy between the metal and the carrier can be enhanced, forming an abundance of oxygenvacancies. Oxygen vacancies not only adsorb CO_(2) but also activate the intermediates in methanol synthesis, playing a keyrole in the entire reaction. Co3O4-CuO-ZnO had the best catalytic performance (a CO_(2) conversion rate of 9.17%;a CH_(3)OHselectivity of 92.77%). This study describes a typical strategy for multi-component doping to construct a catalyst with anabundance of oxygen vacancies, allowing more effective catalysis to synthesize CH_(3)OH from CO_(2).

Ca and Sr co-doping induced oxygen vacancies in 3DOM La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)catalysts for boosting low-temperature oxidative coupling of methane

It is urgent to develop catalysts with application potential for oxidative coupling of methane(OCM)at relatively lower temperature.Herein,three-dimensional ordered macro porous(3 DOM)La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)(A_(2)B_(2)O_(7)-type)catalysts with disordered defective cubic fluorite phased structure were successfully prepared by a colloidal crystal template method.3DOM structure promotes the accessibility of the gaseous reactants(O2and CH4)to the active sites.The co-doping of Ca and Sr ions in La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)catalysts improved the formation of oxygen vacancies,thereby leading to increased density of surface-active oxygen species(O_(2)^(-))for the activation of CH4and the formation of C2products(C2H6and C2H4).3DOM La_(2-x)Sr_(x)Ce_(2-y)CayO_(7-δ)catalysts exhibit high catalytic activity for OCM at low temperature.3DOM La1.7Sr0.3Ce1.7Ca0.3O7-δcatalyst with the highest density of O_(2)^(-)species exhibited the highest catalytic activity for low-temperature OCM,i.e.,its CH4conversion,selectivity and yield of C2products at 650℃are 32.2%,66.1%and 21.3%,respectively.The mechanism was proposed that the increase in surface oxygen vacancies induced by the co-doping of Ca and Sr ions boosts the key step of C-H bond breaking and C-C bond coupling in catalyzing low-temperature OCM.It is meaningful for the development of the low-temperature and high-efficient catalysts for OCM reaction in practical application.

姜酮通过激活Nrf2/HO-1信号通路减轻OGD/R后氧化应激损伤对HT22细胞凋亡的抑制作用

目的:探讨姜酮对氧糖剥夺/复糖复氧(OGD/R)后小鼠海马神经元HT22细胞的保护作用,阐明其相关作用机制。方法:培养HT22细胞,设置不同OGD/R时间梯度,建立OGD/R细胞损伤模型。HT22细胞分为对照组、OGD/R组、OGD/R+1μmol·L^(-1)姜酮组、OGD/R+10μmol·L^(-1)姜酮、OGD/R+100μmol·L^(-1)姜酮组和OGD/R+0.2%二甲亚枫(DMSO)组,CCK-8法检测各组细胞活性并计算各组细胞存活率,确定姜酮最适药物浓度。细胞分为对照组、OGD/R组、OGD/R+姜酮组和OGD/R+姜酮+核因子E2相关因子2(Nrf2)抑制剂(ML385)组,OGD/R+姜酮组细胞经姜酮给药处理4 h后予以OGD 8 h和复糖复氧8 h处理,OGD/R+姜酮+ML385组细胞在姜酮给药前予以10μmol·L^(-1)ML385预处理6 h,CCK-8法检测各组细胞活性,Western blotting法检测各组细胞中Nrf2、血红素加氧酶1(HO-1)、B细胞淋巴瘤2(Bcl-2)和Bcl-2相关X蛋白(Bax)蛋白表达水平,酶联免疫吸附试验(ELISA)法检测各组细胞培养上清中超氧化物歧化酶(SOD)活性和丙二醛(MDA)水平。结果:与对照组比较,HT22细胞经OGD 8 h和复糖复糖8 h处理后细胞存活率低于50%,以OGD 8 h和复糖复糖8 h建立HT22细胞OGD/R模型。与OGD/R组比较,OGD/R+不同剂量姜酮组细胞存活率均不同程度升高,其中OGD/R+100μmol·L^(-1)姜酮组细胞存活率升高最明显(P<0.01),故选用100μmol·L^(-1)姜酮用于后续实验。与对照组比较,OGD/R组细胞活性明显降低(P<0.01),细胞中Nrf2、HO-1和Bax蛋白表达水平明显升高(P<0.01),Bcl-2蛋白表达水平明显降低(P<0.05),细胞培养上清中SOD活性明显降低(P<0.01),MDA水平明显升高(P<0.01);与OGD/R组比较,OGD/R+姜酮组细胞活性明显升高(P<0.01),细胞中Nrf2、HO-1和Bcl-2蛋白表达水平明显升高(P<0.05或P<0.01),Bax蛋白表达水平明显降低(P<0.05),细胞培养上清中SOD活性明显升高(P<0.01),MDA水平明显降低(P<0.01);与OGD/R+姜酮组比较,OGD/R+姜酮+ML385组细胞活性明显降低(P<0.01),细胞中Nrf2、HO-1和Bcl-2蛋白表达水平明显降低(P<0.01),Bax蛋白表达水平明显升高(P<0.01),细胞培养上清中SOD活性明显降低(P<0.01),MDA水平明显升高(P<0.05)。结论:姜酮可通过激活Nrf2/HO-1信号通路减轻OGD/R后氧化应激损伤对HT22细胞凋亡的抑制作用。

BMAL1减轻H_(2)O_(2)诱导的心肌细胞损伤机制研究

目的探讨脑和肌肉组织芳香烃受体核转运蛋白的类似蛋白1(BMAL1)通过核因子E2相关因子2(NRF2)调节活性氧(ROS)/NOD样受体热蛋白结构域相关蛋白3(NLRP3)炎症小体通路对过氧化氢(H_(2)O_(2))诱导的心肌细胞损伤的影响。方法体外培养H9c2细胞和BMAL1稳定过表达的H9c2细胞,建立H_(2)O_(2)诱导的H9c2细胞损伤模型,并将细胞分为对照(Control)组、H_(2)O_(2)组、BMAL1过表达(BMAL1-OE)组、BMAL1过表达+H_(2)O_(2)(BMAL1-OE+H_(2)O_(2))组、BMAL1过表达+NRF2抑制剂(BMAL1-OE+ML385)组、BMAL1过表达+NRF2抑制剂+H_(2)O_(2)(BMAL1-OE+ML385+H_(2)O_(2))组。采用CCK-8法检测细胞活力,荧光探针2’,7’-二氯荧光素二乙酸酯检测ROS生成,Western blot检测BMAL1、NRF2和NLRP3蛋白表达,酶联免疫吸附试验法检测白细胞介素(IL)-1β释放。结果与Control组相比,H_(2)O_(2)组H9c2心肌细胞活力减弱,ROS生成增多,BMAL1和NRF2蛋白表达水平降低,NLRP3蛋白表达水平升高,IL-1β释放增多(P<0.05);与H_(2)O_(2)组相比,BMAL1-OE+H_(2)O_(2)组H9c2心肌细胞活力升高,ROS生成减少,BMAL1和NRF2蛋白表达水平升高,NLRP3蛋白表达水平降低,IL-1β释放减少(P<0.05)。与BMAL1-OE+H_(2)O_(2)组相比,BMAL1-OE+ML385+H_(2)O_(2)组H9c2心肌细胞活力减弱,ROS生成增多,NLRP3蛋白表达水平升高,IL-1β释放增多(P<0.05)。结论BMAL1可减轻H_(2)O_(2)诱导的H9c2心肌细胞损伤,其机制可能与NRF2调节ROS/NLRP3炎症小体通路有关。

岩藻黄质活化核因子E2相关因子2改善糖皮质激素诱导的成骨细胞凋亡

背景:骨质疏松症发病率高,易导致骨折等并发症的发生,而现有药物干预不良反应大,难以满足临床需求。目的:探索岩藻黄质对糖皮质激素诱导成骨细胞骨质疏松症模型的作用与潜在机制。方法:将原代大鼠成骨细胞接种于6孔板内,待细胞融合度达到80%后分4组干预:对照组单纯培养24 h,糖皮质激素组使用地塞米松干预24 h,岩藻黄质组使用岩藻黄质干预24 h,糖皮质激素+岩藻黄质组使用地塞米松与岩藻黄质同时干预24 h。干预结束后,检测细胞增殖、凋亡、细胞内活性氧含量以及凋亡相关蛋白、骨形成相关蛋白、细胞核核因子E2相关因子2的蛋白表达。结果与结论:①CCK-8检测显示,与对照组比较,糖皮质激素组细胞活性降低(P<0.05);与糖皮质激素组比较,糖皮质激素+岩藻黄质组细胞活性升高(P<0.05);②JC-1线粒体膜电位染色与流式细胞学检测显示,与对照组比较,糖皮质激素组细胞凋亡比例增加(P<0.05);与糖皮质激素组比较,糖皮质激素+岩藻黄质组细胞凋亡比例减少(P<0.05);③Western Blot检测显示,与对照组比较,糖皮质激素组BAX、裂解聚ADP核糖聚合酶的蛋白表达升高(P<0.05),BCL2、Ⅰ型胶原蛋白α1肽链、碱性磷酸酶、骨钙蛋白、RUNX2的蛋白表达降低(P<0.05);与糖皮质激素组比较,糖皮质激素+岩藻黄质组BAX、裂解聚ADP核糖聚合酶的蛋白表达降低(P<0.05),BCL2、Ⅰ型胶原蛋白α1肽链、碱性磷酸酶、骨钙蛋白、RUNX2的蛋白表达升高(P<0.05);④荧光探针检测显示,与对照组比较,糖皮质激素组活性氧含量增加(P<0.05);与糖皮质激素组比较,糖皮质激素+岩藻黄质组活性氧含量减少(P<0.05);⑤免疫荧光染色与Western Blot检测显示,与对照组比较,糖皮质激素组细胞核核因子E2相关因子2的蛋白表达降低(P<0.05);与糖皮质激素组比较,糖皮质激素+岩藻黄质组细胞核核因子E2相关因子2的蛋白表达升高(P<0.05);⑥结果表明,岩藻黄质通过活化核因子E2相关因子2改善糖皮质激素诱导的成骨细胞凋亡与骨形成相关分子表达。

典型低轨辐照环境对MoS_(2)-Ti薄膜真空摩擦学性能的影响

采用非平衡磁控溅射方法在9Cr18基底上制备了MoS_(2)-Ti薄膜,并对4组样品分别进行了电子辐照、电子/质子辐照、电子/质子/紫外辐照、电子/质子/紫外/原子氧辐照。采用SEM、XRD、XPS分析了辐照前后薄膜的结构和化学组成变化,通过摩擦试验考察了辐照前后薄膜的摩擦学性能,探讨了其损伤机制。研究结果表明,电子辐照、质子辐照、紫外辐照对MoS_(2)-Ti薄膜的显微组织结构、表面形貌及摩擦学性能没有明显影响。动能5 eV的原子氧对MoS_(2)-Ti薄膜表面有显著的损伤,主要表现在表面出现“绒毯”状形态,Mo、S和Ti元素被氧化成高价氧化物。原子氧辐照导致MoS_(2)-Ti薄膜摩擦起始和中段摩擦因数升高、中段摩擦因数不稳定,比磨损率增大。

A highly dispersed Pt/copper modified-MnO_(2)catalyst for the complete oxidation of volatile organic compounds:The effect of oxygen species on the catalytic mechanism

Manganese oxide(MnO_(2))exhibits excellent activity for volatile organic compound oxidation.However,it is currently unknown whether lattice oxygen or adsorbed oxygen is more conducive to the progress of the catalytic reaction.In this study,novel hollow highly dispersed Pt/Copper modified-MnO_(2)catalysts were fabricated.Cu^(2+)was stabilized into theδ-MnO_(2)cladding substituting original K+,which produced lattice defects and enhance the content of adsorbed oxygen.The 2.03 wt%Pt Cu_(0.050)-MnO_(2)catalyst exhibited the highest catalytic activity and excellent stability for toluene and benzene oxidation,with T_(100)=160℃under high space velocity(36,000 mL g^(-1)h^(-1)).The excellent performance of catalytic oxidation of VOCs is attributed to the abundant adsorbed oxygen content,excellent low-temperature reducibility and the synergistic catalytic effect between the Pt nanoparticles and Cu_(0.050)-MnO_(2).This study provides a comprehensive understanding of the Langmuir-Hinshelwood(L-H)mechanism occurring on the catalysts.

Effectively Modulating Oxygen Vacancies in Flower‑Likeδ‑MnO_(2)Nanostructures for Large Capacity and High‑Rate Zinc‑Ion Storage

In recent years,manganese-based oxides as an advanced class of cathode materials for zinc-ion batteries(ZIBs)have attracted a great deal of attentions from numerous researchers.However,their slow reaction kinetics,limited active sites and poor electrical conductivity inevitably give rise to the severe performance degradation.To solve these problems,herein,we introduce abundant oxygen vacancies into the flower-likeδ-MnO_(2)nanostructure and effectively modulate the vacancy defects to reach the optimal level(δ-MnO_(2)-x-2.0).The smart design intrinsically tunes the electronic structure,guarantees ion chemisorption-desorption equilibrium and increases the electroactive sites,which not only effectively accelerates charge transfer rate during reaction processes,but also endows more redox reactions,as verified by first-principle calculations.These merits can help the fabricatedδ-MnO_(2)-x-2.0 cathode to present a large specific capacity of 551.8 mAh g^(-1) at 0.5 A g^(-1),high-rate capability of 262.2 mAh g^(-1) at 10 A g^(-1) and an excellent cycle lifespan(83%of capacity retention after 1500 cycles),which is far superior to those of the other metal compound cathodes.In addition,the charge/discharge mechanism of theδ-MnO_(2)-x-2.0 cathode has also been elaborated through ex situ techniques.This work opens up a new pathway for constructing the next-generation high-performance ZIBs cathode materials.

Optimized CeO_(2) Nanowires with Rich Surface Oxygen Vacancies Enable Fast Li-Ion Conduction in Composite Polymer Electrolytes

Low-cost and flexible solid polymer electrolytes are promising in all-solid-state Li-metal batteries with high energy density and safety.However,both the low room-temperature ionic conductivities and the small Li^(+)transference number of these electrolytes significantly increase the internal resistance and overpotential of the battery.Here,we introduce Gd-doped CeO_(2) nanowires with large surface area and rich surface oxygen vacancies to the polymer electrolyte to increase the interaction between Gd-doped CeO_(2) nanowires and polymer electrolytes,which promotes the Li-salt dissociation and increases the concentration of mobile Li ions in the composite polymer electrolytes.The optimized composite polymer electrolyte has a high Li-ion conductivity of 5×10^(-4)4 S cm^(-1) at 30℃ and a large Li+transference number of 0.47.Moreover,the composite polymer electrolytes have excellent compatibility with the metallic lithium anode and high-voltage LiNi_(0.8)Mn _(0.1)Co_(0.1)O_(2)(NMC)cathode,providing the stable cycling of all-solid-state batteries at high current densities.

稀土金属Y掺杂锐钛矿TiO_(2)(101)表面的改性

为了掌握Y原子掺杂在锐钛矿TiO_(2)(101)表面的稳定吸附位置和电子结构变化,提高其表面光催化活性,本文利用基于密度泛函理论的第一性原理计算研究了Y原子掺杂在完美的、带有亚表层氧空位和带有表层氧空位的锐钛矿TiO_(2)(101)表面的结构稳定性和电子性能。结构优化和电荷密度结果表明,Y原子可以稳定吸附在三种不同的表面上。在完美表面吸附时,Y原子最稳定的吸附位置是两个三配位O原子之间的空位;与完美表面类似,在带有亚表层氧空位表面吸附时,Y原子最稳定吸附位置是与氧空位邻近的两个三配位O原子之间的空位;而在带有表层氧空位表面吸附时,Y原子则停留于氧空位邻近的四配位Ti原子位置上最稳定。电荷密度计算结果也表明Y原子与这三种表面结合非常稳固。电子态密度计算结果表明,在带有表层氧空位的锐钛矿TiO_(2)(101)表面引入Y原子会在费米面附近的带隙中引入缺陷态,带隙从1.67 eV降至1.44 eV,这有可能引起电子的分级跃迁,提高表面光催化能力。本文的研究为利用单原子Y掺杂提高TiO_(2)(101)表面光催化能力提供了理论支持。

真空紫外协同Co^(2+)催化过硫酸氢钾降解罗丹明B

有机染料具有毒性强、色度高、不易降解等特性,为了高效去除有机染料,实验以真空紫外(VUV)为光源,研究了VUV协同Co^(2+)催化过硫酸氢钾(PMS)降解典型有机染料罗丹明B(RhB)的反应机制和转化途径.结果表明:①在RhB初始浓度为80 mg/L,Co^(2+)和PMS投加量分别为15μmol/L、0.5 mmol/L的条件下,VUV/Co^(2+)/PMS体系反应10 min,RhB去除率可达99.1%.VUV/Co^(2+)/PMS体系对RhB降解遵循一级动力学规律,反应速率常数(k)随初始质量浓度的增加而减小.②溶液初始pH对反应速率有较大的影响,随着pH减小,反应速率也同时减小.投加量为30 mmol/L的HCO_(3)^(−)、Cl^(−)均表现出显著的抑制作用,相较于对照组,RhB去除率由99.1%分别降至66.0%、84.2%,而NO_(3)^(−)和SO_(4)^(2−)抑制作用不显著;印染助剂柠檬酸钠也会显著抑制RhB降解.③自由基捕获实验和电子顺磁共振(EPR)测试结果表明,VUV/Co^(2+)/PMS体系中存在的氧化物种包括硫酸根自由基(SO_(4)^(−)·)、羟基自由基(·OH)、单线态氧(1O2).④根据紫外可见吸收光谱和质谱结果,初步推断RhB分子降解主要通过活性氧(ROS)攻击造成共轭结构破坏和N-位脱乙基等作用.另外,对总有机碳(TOC)进行测试,30 min时RhB矿化度可达到43.8%.研究显示,VUV/Co^(2+)/PMS体系能够有效去除RhB.

In situ confined vertical growth of Co_(2.5)Ni_(0.5)Si_(2)O_(5)(OH)_(4)nanoarrays on rGO for an efficient oxygen evolution reaction

Rational design of oxygen evolution reaction(OER)catalysts at low cost would greatly benefit the economy.Taking advantage of earth-abundant elements Si,Co and Ni,we produce a unique-structure where cobalt-nickel silicate hydroxide[Co_(2.5)Ni_(0.5)Si_(2)O_(5)(OH)_(4)]is vertically grown on a reduced graphene oxide(rGO)support(CNS@rGO).This is developed as a low-cost and prospective OER catalyst.Compared to cobalt or nickel silicate hydroxide@rGO(CS@rGO and NS@rGO,respectively)nanoarrays,the bimetal CNS@rGO nanoarray exhibits impressive OER performance with an overpotential of 307 mV@10 mA cm^(-2).This value is higher than that of CS@rGO and NS@rGO.The CNS@rGO nanoarray has an overpotential of 446 mV@100 mA cm^(-2),about 1.4 times that of the commercial RuO_(2)electrocatalyst.The achieved OER activity is superior to the state-of-the-art metal oxides/hydroxides and their derivatives.The vertically grown nanostructure and optimized metal-support electronic interactions play an indispensable role for OER performance improvement,including a fast electron transfer pathway,short proton/electron diffusion distance,more active metal centers,as well as optimized dualatomic electron density.Taking advantage of interlay chemical regulation and the in-situ growth method,the advanced-structural CNS@rGO nanoarrays provide a new horizon to the rational and flexible design of efficient and promising OER electrocatalysts.

Single-atom catalysts for the electrochemical reduction of carbon dioxide into hydrocarbons and oxygenates

The electrochemical reduction of carbon dioxide offers a sound and economically viable technology for the electrification and decarbonization of the chemical and fuel industries.In this technology,an electrocatalytic material and renewable energy-generated electricity drive the conversion of carbon dioxide into high-value chemicals and carbon-neutral fuels.Over the past few years,single-atom catalysts have been intensively studied as they could provide near-unity atom utilization and unique catalytic performance.Single-atom catalysts have become one of the state-of-the-art catalyst materials for the electrochemical reduction of carbon dioxide into carbon monoxide.However,it remains a challenge for single-atom catalysts to facilitate the efficient conversion of carbon dioxide into products beyond carbon monoxide.In this review,we summarize and present important findings and critical insights from studies on the electrochemical carbon dioxide reduction reaction into hydrocarbons and oxygenates using single-atom catalysts.It is hoped that this review gives a thorough recapitulation and analysis of the science behind the catalysis of carbon dioxide into more reduced products through singleatom catalysts so that it can be a guide for future research and development on catalysts with industry-ready performance for the electrochemical reduction of carbon dioxide into high-value chemicals and carbon-neutral fuels.