Tuning the crystalline and electronic structure of ZrO_(2)via oxygen vacancies and nano-structuring for polysulfides conversion in lithium-sulfur batteries

The recent emergence of tetragonal phases zirconium dioxide(ZrO_(2))with vacancies has generated significant interest as a highly efficient and stable electrocatalyst with potential applications in trapping polysulfides and facilitating rapid conversion in lithium-sulfur batteries(LSBs).However,the reduction of ZrO_(2)is challenging,even under strong reducing atmospheres at high temperatures and pressures.Consequently,the limited presence of oxygen vacancies results in insufficient active sites and reaction interfaces,thereby hindering practical implementation.Herein,we successfully introduced abundant oxygen vacancies into ZrO_(2)at the nanoscale with the help of carbon nanotubes(CNTs-OH)through hydrogen-etching at lower temperatures and pressures.The introduced oxygen vacancies on ZrO_(2-x)/CNTs-OH can effectively rearrange charge distribution,enhance sulfiphilicity and increase active sites,contributing to high ionic and electronic transfer kinetics,strong binding energy and low redox barriers between polysulfides and ZrO_(2-x).These findings have been experimentally validated and supported by theory calculations.As a result,LSBs assembled with the ZrO_(2-x)/CNTs-OH modified separators demonstrate excellent rate performance,superior cycling stability,and ultra-high sulfur utilization.Especially,at high sulfur loading of 6 mg cm^(-2),the area capacity is still up to 6.3 mA h cm^(-2).This work provides valuable insights into the structural and functional optimization of electrocatalysts for batteries.

Single-atom modified graphene cocatalyst for enhanced photocatalytic CO_(2) reduction on halide perovskite

Metal halide perovskite(MHP)has become one of the most promising materials for photocatalytic CO_(2) reduction owing to the wide light absorption range,negative conduction band position and high reduction ability.However,photoreduction of CO_(2) by MHP remains a challenge because of the slow charge separation and transfer.Herein,a cobalt single-atom modified nitrogen-doped graphene(Co-NG)cocatalyst is prepared for enhanced photocatalytic CO_(2) reduction of bismuth-based MHP Cs_(3)Bi_(2)Br_(9).The optimal Cs_(3)Bi_(2)Br_(9)/Co-NG composite exhibits the CO production rate of 123.16μmol g^(-1)h^(-1),which is 17.3 times higher than that of Cs_(3)Bi_(2)Br_(9).Moreover,the Cs_(3)Bi_(2)Br_(9)/Co-NG composite photocatalyst exhibits nearly 100% CO selectivity as well as impressive long-term stability.Charge carrier dynamic characterizations such as Kelvin probe force microscopy(KPFM),single-particle PL microscope and transient absorption(TA)spectroscopy demonstrate the vital role of Co-NG cocatalyst in accelerating the transfer and separation of photogenerated charges and improving photocatalytic performance.The reaction mechanism has been demonstrated by in situ diffuse reflectance infrared Fourier-transform spectroscopy measurement.In addition,in situ X-ray photoelectron spectroscopy test and theoretical calculation reveal the reaction reactive sites and reaction energy barriers,demonstrating that the introduction of Co-NG promotes the formation of ^(*)COOH intermediate,providing sufficient evidence for the highly selective generation of CO.This work provides an effective single-atom-based cocatalyst modification strategy for photocatalytic CO_(2) reduction and is expected to shed light on other photocatalytic applications.

Spheroid construction strategies and application in 3D bioprinting

Tissue engineering has been striving toward designing and producing natural and functional human tissues.Cells are the fundamental building blocks of tissues.Compared with traditional two-dimensional cultured cells,cell spheres are threedimensional(3D)structures that can naturally form complex cell–cell and cell–matrix interactions.This structure is close to the natural environment of cells in living organisms.In addition to being used in disease modeling and drug screening,spheroids have significant potential in tissue regeneration.The 3D bioprinting is an advanced biofabrication technique.It accurately deposits bioinks into predesigned 3D shapes to create complex tissue structures.Although 3D bioprinting is efficient,the time required for cells to develop into complex tissue structures can be lengthy.The 3D bioprinting of spheroids significantly reduces the time required for their development into large tissues/organs during later cultivation stages by printing them with high cell density.Combining spheroid fabrication and bioprinting technology should provide a new solution to many problems in regenerative medicine.This paper systematically elaborates and analyzes the spheroid fabrication methods and 3D bioprinting strategies by introducing spheroids as building blocks.Finally,we present the primary challenges faced by spheroid fabrication and 3D bioprinting with future requirements and some recommendations.

Intracranial arterial stenosis in young adults:risk factors,diagnosis and treatment

Intracranial artery stenosis(ICAS)in youth is an under-explored condition.ICAS is one of the leading causes of stroke in young people worldwide and confers a higher risk of stroke recurrence,leading to a poor prognosis for individuals and a great burden to society.The etiology and risk factors of ICAS in youth differ from those of older patients,thus resulting in a difference in the progression and prognosis of the disease.Even though the diagnosis of ICAS is lumen-based,it is sometimes difficult to identify in young patients based on imaging alone.Notably,novel vessel wall imaging techniques play an important role in determining the cause of stenosis and screening patients at high risk of recurrence.Moreover,pharmacologic regimens and risk factor control goals for ICAS in young adults are largely consistent with those in older patients.Thus,considering the poor prognosis,there is an urgent need for high-quality studies in the young ICAS population to analyze the high-quality observational data collected.

The Impact of Patient Education on the Nursing Care of Perioperative Patients in the Interventional Catheterization Room

Objective:To explore and analyze the effect of implementing a precise education model on the nursing care of perioperative patients in the interventional catheterization room.Methods:We selected 70 patients who were going to undergo surgical intervention in our hospital from August 2020 to December 2022 as the subjects for this study through random sampling.The patients were divided into a control group and an observation group,with 35 cases in each group.The control group underwent basic nursing intervention,and the observation group was given precise patient education.The nursing effects of both groups were observed.Results:After the intervention,all compliance indicators of the observation group were better than those of the control group(P<0.05).Besides,the incidence of complications in the observation group(2.86%)was lower than that of the control group(17.14%)with P<0.05.Furthermore,the patient satisfaction of the observation group(97.14%)was higher than that of the control group(82.86%),with P<0.05.Conclusion:A precise propaganda and education model facilitates the nursing of perioperative patients in the interventional catheterization room.Therefore,this practice should be popularized.

基于数智化的人力资源决策优化路径探析

人力资源决策的效率和质量决定了人力资源管理各项工作能否顺利开展,并最终影响企业战略目标的达成。近些年得益于大数据、人工智能等数智化技术的发展和应用,企业人力资源管理理念和管理模式逐步发生改变。本文从分析传统人力资源决策面临的困境入手,结合数智化的发展阶段,探讨了数智化应用为人力资源决策带来的机会与挑战。进而分析了在人力资源管理实践中,如何抓住机会科学合理地利用数智化技术,提升人力资源决策的有效性,以期为企业人力资源决策的优化提供借鉴。

一种聚集诱导发光(AIE)铜碘簇合物的合成及其在构筑长余辉发光材料中的应用

设计了一个4学时的无机化学实验,通过学习一种具有聚集诱导发光(AIE)特性的铜碘簇合物的合成及其在构筑长余辉发光材料中的应用,使学生掌握无机簇合物合成、晶体生长等技能,加深其对教材中配位化合物、簇合物、旋光异构体、杂化轨道等概念的认识与理解。同时,将AIE和长余辉发光这些化学研究前沿热点引入本科实验教学,通过有趣直观的化学现象,激发学生的学习热情。结合课堂讲解、文献阅读,引导学生探索化学现象背后的机理。本实验学时紧凑,所需的试剂仪器简单、成本低廉,适合在化学或相关专业的本科实验教学中推广。本实验符合教育部高等学校化学类专业教学指导委员会《化学类专业化学实验教学建议内容》关于“物质的合成与制备”中对于“簇合物”知识点的相关内容要求,丰富了传统无机实验课程内容。

沉积于含硼金属有机框架的Pt(Ⅱ)通过抑制分解来增强光催化H_(2)O_(2)的产生

H_(2)O_(2)作为一种重要的化工资源越来越受到关注,它不仅是环境友好的氧化剂,而且是很有应用前景的新型液体燃料.目前生产H_(2)O_(2)主要采用蒽醌法,该方法存在能耗高、副产物有毒等缺点.光催化合成H_(2)O_(2)因对环境友好而受到广泛关注,该合成反应中同时发生H_(2)O_(2)的生成和分解.目前光催化合成H_(2)O_(2)相关研究主要集中在H_(2)O_(2)的生成,而有关H_(2)O_(2)分解的研究较少.研究发现Pt作为助催化剂在提高光催化活性方面发挥着重要作用,但Pt价态对光催化活性的影响,特别是对H_(2)O_(2)的生成和分解的影响,尚未进行详细研究.本文将不同价态的Pt沉积在含硼金属有机骨架(UiO-67-B)上,详细研究了Pt(0),Pt(Ⅱ)和Pt(Ⅳ)在光催化产H_(2)O_(2)过程中的作用.粉末X射线衍射(XRD)、X射线光电子能谱(XPS)和傅里叶转换红外光谱(FT-IR)等表征结果证明了UiO-67-B/Pt(0),UiO-67-B/Pt(Ⅱ)和UiO-67-B/Pt(Ⅳ)样品的成功制备.此外,UiO-67-B/Pt(Ⅱ)的高分辨Cl 2p XPS光谱中出现了Cl-HO(Zr)峰,而且FT-IR谱中出现Cl-H键表明,[PtCl_(4)]^(2-)中的Cl与UiO-67-B中Zr-OH处的H进行了络合.密度泛函理论计算结果表明,UiO-67-B/Pt(Ⅱ)上Cl与H之间存在弱吸附,进一步证明了上述结论.光催化反应结果表明,样品中UiO-67-B/Pt(Ⅱ)催化生成H_(2)O_(2)产率最高,达到8275μmol L^(-1)h^(-1).H_(2)O_(2)生成和分解速率常数拟合结果表明,Pt(Ⅱ)的存在不仅促进H_(2)O_(2)的生成,而且抑制了光催化过程中H_(2)O_(2)的分解.光催化H_(2)O_(2)分解实验进一步证明了Pt(Ⅱ)对H_(2)O_(2)分解的抑制作用.O_(2)程序升温脱附和高角度环形暗场扫描透射电子显微镜结果表明,UiO-67-B/Pt(Ⅱ)具有最大的O_(2)吸附量,且Pt(Ⅱ)以单原子形式存在,这为O_(2)的吸附提供了更多的吸附位点.光致发光光谱、荧光寿命、光电流响应和阻抗图谱结果均表明,UiO-67-B/Pt(Ⅱ)拥有更高的载流子转移和分离能力,说明Pt(Ⅱ)与UiO-67-B的相互作用建立了一个电子传输通道,有效促进了UiO-67-B/Pt(Ⅱ)的电荷传输和分离.电子空间分布图也进一步证明了该结论.此外,进一步计算了反应过程中每一步所需的热力学自由能,包括O_(2)吸附、中间体质子化过程和H_(2)O_(2)解吸过程.结果表明,Pt(Ⅱ)的引入更有利于O_(2)的吸附和·O_(2)-质子化,且Pt(Ⅱ)的存在有利于H_(2)O_(2)的解吸.综上,本工作系统地研究了铂价态对H_(2)O_(2)生成的影响,为设计具有良好的H_(2)O_(2)产生效率的光催化剂提供了一种新策略.

GL9 from Oryza glumaepatula controls grain size and chalkiness in rice

Grain size is a key factor influencing grain yield and appearance quality in rice.We identified twelve quantitative trait loci(QTL)for grain length(GL),nine for grain width(GW),and nine for 1000-kernel weight(TKW)using GLU-SSSLs,which are single-segment substitution lines with Oryza glumaepatula as donor parent and Huajingxian 74(HJX74)as recipient parent.Among the QTL,qGL1-2,qGL1-4,qGL9-2,qGW2-2,qGW9-1 and qTKW9-2 contributed to high grain yield.GL9 was identified as a candidate gene for qGL9-2 by map-based cloning and sequencing,and is a novel allele of GS9.The kernel of NIL-gl9was slenderer and longer than that of HJX74,and the TKW and grain yield per plant of NIL-gl9 were higher than those of HJX74.The proportion of grain chalkiness of NIL-gl9 was much lower than that of HJX74.Thus,gl9 increased grain yield and appearance quality simultaneously.Three pyramid lines,NIL-gs3/gl9,NIL-GW7/gl9 and NIL-gw8/gl9,were developed and the kernel of each was longer than that of the corresponding recipient parent lines.The gl9 allele may be beneficial for breeding rice varieties with high grain yield and good appearance quality.

Dual metal atom catalysts:Advantages in electrocatalytic reactions

The dual-metal-atom catalysts(DACs)have aroused much attention as they possess the advantages of single-atom and metal alloy catalysts.And the DACs have exhibited enhanced performance in various electrocatalytic reactions,such as hydrogen/oxygen evolution and oxygen/carbon dioxide/nitrogen reduction.In this review,we mainly overview the latest understanding of the advantages of DACs for these reactions.This review will start with the familiar characterization methods for DACs,then the primary synthesis strategies for DACs will be discussed.Emphasis is given to the advantages of DACs in catalytic reactions,including the adsorption and activation,electronic structure regulation,breaking scaling relations,reducing energy barriers,cascading and coupling,synergy effect,and providing mechanism research platforms.Finally,personal perspectives and challenges for the further development of DACs are briefly discussed.

应变不敏感型可拉伸导体及其智能电子纺织品应用现状

可拉伸导体作为应用于智能电子纺织品领域的重要材料,引起了人们的广泛关注。然而传统可拉伸导体的电阻存在应变敏感的特性,限制了其在可拉伸设备上的应用。应变不敏感型可拉伸导体由于其应变不敏感性、可拉伸性、高导电性成为可拉伸导体的首选。文中综述了几种应变不敏感型可拉伸导体的结构、材料及制备方法,应变不敏感性能的表征,其在智能电子纺织品的部分应用,并对应变不敏感型可拉伸导体的应用前景进行了展望。

Effects of constant light and dark conditions on the locomotor activity,body mass,and body temperature rhythms of Eurasian Tree Sparrows(Passer montanus)

Light is an essential environmental cue influencing the endogenous circadian clocks that regulate behavioral and physiological processes in animals.Despite extensive research on the circadian rhythms of avian behavior and physiology,the mechanisms by which they adapt and adjust to abnormal photoperiod conditions,such as artificial light,have yet to be fully elucidated.Here,the circadian rhythms of the body mass,activity,and core and peripheral body temperatures of the Eurasian Tree Sparrow(Passer montanus,ETS)-a diurnal passerine-were examined under three different lighting conditions:constant light(LL),constant darkness(DD),and normal light-dark cycles(LD).Our results showed that the activity,body mass,core,tarsometatarsus,and eye temperatures of the ETSs varied significantly with treatment,time,and the interaction between treatment and time;however,there was no significant change in body mass in response to the interaction between time and treatment.Under LD conditions,the ETSs exhibited significant circadian rhythms in activity and core,tarsometatarsus,and eye temperatures.Under LL conditions,only the core temperature exhibited significant rhythmicity.Under DD conditions,there were no significant circadian rhythms in activity,body mass,and eye temperature;however,the core and tarsometatarsus temperatures remained rhythmic.Our results indicate that the core body temperature rhythm of ETS is endogenous and can be maintained under abnormal photoperiods.In contrast,the activity and body surface temperature,uncoupled from the core body temperature under abnormal photoperiod conditions,strongly depend on light.These results differ from those of other diurnal avian species,suggesting a unique coping mechanism of ETS in response to an abnormal photoperiod.

基于正交质谱的N-糖组谱揭示哈夫病潜在病原学

食用煮熟的小龙虾可能导致哈夫病(HD),该病被认为是由不明毒素引起的,而病因尚不清楚。N-糖组的剖析将促进破译疾病的分子机制,而HD相关的糖基化从未被探索过。2019-2020年期间,本研究团队招募了来自武汉市疾病预防控制中心的90份HD患者和对照组血清样本。本文中,采用基于高通量的正交质谱对HD中血清和血清衍生的IgG的N-糖组谱进行了表征。数据显示,HD与总血清糖蛋白的核心岩藻糖基化和单半乳糖醇化升高有关。血清IgG水平是HD患者的良好指标。此外,IgG的差异半乳糖基化和唾液酸化与HD密切相关。值得注意的是,IgG1和IgG2的半乳糖基化和唾液酸化的变化具有亚类特异性。有意义的是,IgG2或IgG3/4的唾液酸化和半乳糖基化改变与HD的临床标志物密切相关。本研究表明差异化IgG N-糖基化与HD的关联,为这种罕见疾病的病因提供了新的见解。

High-pressure new phases of V–N compounds

The high-pressure diagram of V–N compounds is enriched by proposed seven new stable high-pressure phases.The P-1-VN_4with the armchair N-rich structure may be quenched to ambient conditions.The formed N–N covalent bond plays an important role for the structural stability of N-chain.The charge transfer results in a V–N ionic bond interaction,which further improves the stability of N-chain structure.The P-1-VN_4,P4mnc-VN_8,and Immm-VN_(10)with the outstanding detonation properties have potential application in explosive field.

Control of epileptic activities in a cortex network of multiple coupled neural populations under electromagnetic induction

Epilepsy is believed to be associated with the abnormal synchronous neuronal activity in the brain,which results from large groups or circuits of neurons.In this paper,we choose to focus on the temporal lobe epilepsy,and establish a cortex network of multiple coupled neural populations to explore the epileptic activities under electromagnetic induction.We demonstrate that the epileptic activities can be controlled and modulated by electromagnetic induction and coupling among regions.In certain regions,these two types of control are observed to show exactly reverse effects.The results show that the strong electromagnetic induction is conducive to eliminating the epileptic seizures.The coupling among regions has a conduction effect that the previous normal background activity of the region gives way to the epileptic discharge,owing to coupling with spike wave discharge regions.Overall,these results highlight the role of electromagnetic induction and coupling among the regions in controlling and modulating epileptic activities,and might provide novel insights into the treatments of epilepsy.

Tuning Li nucleation and growth via oxygen vacancy-enriched 3D flexible self-supporting protection layer of P-Mn_(3)O_(4-x)for advanced lithium-sulfur batteries

Lithium sulfur batteries have attracted much attention due to their high theoretical specific energy and environmental friendliness.However,the practical application is severely plagued by the cycling life issues resulting from the uncontrollable generation and growth of Li dendrites.Herein,an innovative 3D flexible self-supporting Li anode protection layer of P-Mn_(3)O_(4-x)is constructed via a facile solvothermal method followed by an annealing process.Benefiting from the rich oxygen vacancies coupled with the 3D flexible self-supporting skeleton,abundant lithiophilic sites and high ionic conductivity are obtained,which succeed in guiding Li+homogeneous adsorption and redistribution,accelerating Li+diffusion rate,inducing Li+uniform deposition and nucleation.DFT calculations and experimental results conclusively demonstrate such a protection mechanism.Meanwhile,the effective anchoring and catalytic nature of polar P-Mn_(3)O_(4-x)can also be applied as an immobilization-diffusion-conversion host to improve polysulfides redox.Taking advantage of these merits,super-stable functions for Li symmetric cell matched with P-Mn_(3)O_(4-x)layer are achieved,which exhibits an ultralong lifespan of>5000 h with an ultralow overpotential of 20 m V,far lower than that of bare Li symmetric cell(overpotential of 800 m V only after 250 h)at high current densities of 5 m A cm^(-2)and high plating/stripping capacity of 10 m A h cm^(-2).Even in Li|P-Mn_(3)O_(4-x)||S full cell at 1 C,a high initial discharge specific capacity of 843.1 m A h g^(-1)is still delivered with ultralow capacity fading rate of 0.07%per cycle after 250 cycles,further confirming the synergistic regulation of P-Mn_(3)O_(4-x)for Li nucleation behavior.This work illustrates a sufficient guarantee of 3D protection layer coupled with oxygen vacancies in guiding Li diffusion and nucleation behavior and provides new guidance for promoting the development of advanced Li-S batteries.

Perspectives on potential neuroprotective role of albumin in acute ischemic stroke

Albumin is the most abundant protein in plasma and is synthesized primarily in the liver.It has a variety of biological roles,such as increasing colloid osmotic pressure, and performing antioxidant, anti-inflam-matory,and substance transportation functions.Several studies have confirmed that albumin has neuroprotective effects and it has been used in the treatment of cerebral edema and increased intracranial pressure.In this review we focus on the neuroprotective effects of albumin in ischemic stroke,such as the reduction of cerebral edema, antioxidant effects, protection of neuronal cell membranes, and increased cerebral blood flow. In addition, we summarize preclinical and clinical studies of albumin in ischemic stroke. We believe that the neuroprotective role of albumin should be re-investigated in the era of reperfusion therapy.

植入式光电极器件发展

光遗传技术为神经科学研究提供了一种可精准、快速控制单个神经元活动的手段。为了对神经元实现光遗传调控,将光安全、高效地导入脑内,需要专门的光电极(Optrode)给予支持。光电极是光遗传工具应用的重要组成部分,其功能是把光导入脑内调控神经元活动,同时记录神经元电信号在光调控下变化情况的一种植入式神经接口器件。随着光遗传技术在神经环路、认知与记忆等神经科学研究中应用的深入,以及其在癫痫、感官功能损伤等疾病治疗方面的探索,与光遗传技术相配合的光电极从材料选择、器件结构、给光方式和集成工艺等方面都呈现出百花齐放的发展态势,本文将按照现有植入式光电极的结构特点,将光电极器件分成基于波导型和基于微发光二极管型两大类,论述不同类别光电极器件优缺点及演进方向,对未来植入式光电极的理想结构形态及亟待解决的问题进行了讨论和展望。

轻掺杂硅基神经电极的光噪声消减

硅基神经电极是记录神经细胞放电活动的一种实用工具。使用标准的集成电路加工技术,在宽度仅为70μm的单个硅基针上能排布上千个电极记录位点。光遗传学的发展使控制神经元活动更加精确,通过在给予光刺激的同时记录神经元的电活动,可以获取更丰富的脑活动信息。当使用黄光或蓝光刺激神经元时,光子的能量大于硅衬底的禁带宽度,价带电子被激发到导带,从而生成电子-空穴对。因此,在光刺激下使用硅基神经电极时,硅基板中的光生载流子将严重干扰电极的信噪比。为满足在光刺激同时记录电活动的应用需求,必须减少光对硅基神经电极的噪声干扰。传统的降噪方法是使用重掺杂硅作为衬底材料,通过增加杂质浓度来降低载流子寿命,从而降低硅电极的光学噪声。但是,重掺杂的硅衬底比轻掺杂的硅衬底具有更多的晶格缺陷,这使得硅基电极更加脆弱,并且该方法与标准的集成电路加工技术不兼容。通过分析在轻掺杂硅衬底上制造电极的光致噪声机理,我们发现由光激发产生的载流子的不均匀分布将使轻掺杂硅衬底极化。由光致极化引起的电势将影响在其上制造的电极。将轻掺杂硅衬底金属化和接地将有效降低极化电位。使用这种方法,由光诱发的噪声幅度将下降到原始值的0.87%。为了确保神经元的放电率,将光刺激脉冲频率选择为20 Hz。在1 mW·mm^(-2)的光照下,电极的背景噪声可控制在45μV以下,可以满足一般光遗传学应用的需求。经过上述方式改造后的轻掺杂硅衬底将满足光遗传学应用对神经探针的要求。与传统的通过重掺杂整个衬底降低光噪声方法不同,该方法与标准的集成电路加工技术兼容,为利用标准集成电路加工技术制备高密度、高通量硅电极提供了噪声消除方法。

Research progress of in-situ gelling ophthalmic drug delivery system

Blindness and vision impairment are the most devastating global health problems resulting in a substantial economic and social burden.Delivery of drug to particular parts of the anterior or posterior segment has been a major challenge due to various protective barriers and elimination mechanisms associated with the unique anatomical and physiological nature of the ocular system.Drug administration to the eye by conventional delivery systems results in poor ocular bioavailability(<5%).The designing of a novel approach for a safe,simple,and effective ocular drug delivery is a major concern and requires innovative strategies to combat the problem.Over the past decades,several novel approaches involving different strategies have been developed to improve the ocular delivery system.Among these,the ophthalmic in-situ gel has attained a great attention over the past few years.This review discussed and summarized the recent and the promising research progress of in-situ gelling in ocular drug delivery system.