Unraveling the incompatibility mechanism of ethylene carbonate-based electrolytes in sodium metal anodes

Ethylene carbonate(EC)is widely used in lithium-ion batteries due to its optimal overall performance with satisfactory conductivity,relatively stable solid electrolyte interphase(SEI),and wide electrochemical window.EC is also the most widely used electrolyte solvent in sodium ion batteries.However,compared to lithium metal,sodium metal(Na)shows higher activity and reacts violently with EC-based electrolyte(NaPF_(6)as solute),which leads to the failure of sodium metal batteries(SMBs).Herein,we reveal the electrochemical instability mechanism of EC on sodium metal battery,and find that the com-bination of EC and NaPF_(6) is electrically reduced in sodium metal anode during charging,resulting in the reduction of the first coulombic efficiency,and the continuous consumption of electrolyte leads to the cell failure.To address the above issues,an additive modified linear carbonate-based electrolyte is provided as a substitute for EC based electrolytes.Specifically,ethyl methyl carbonate(EMC)and dimethyl carbon-ate(DMC)as solvents and fluoroethylene carbonate(FEC)as SEI-forming additive have been identified as the optimal solvent for NaFP_(6)based electrolyte and used in Na_(4)Fe_(3)(PO_(4))_(2)(P_(2)O_(7))/Na batteries.The batter-ies exhibit excellent capacity retention rate of about 80%over 1000 cycles at a cut-off voltage of 4.3 V.

控制Na^+转运以及维持Na^+/K^+平衡有助于提高植物的耐盐性

盐害(包括土壤次生盐渍化)造成的日益严重的环境问题已在世界范围内引起了广泛关注。大量针对植物耐盐分子机制的研究已开展,旨在更好地了解植物自身的耐盐机制。到目前为止,已获取了大量关于植物耐盐性机制的信息。同时,人们正在形成一个共识,即植物维持自身细胞离子平衡的能力是其具有耐盐性的关键。Na+/H+、K+/H+和Na+/K+逆向转运蛋白及其同源蛋白在植物细胞维持离子平衡中的关键作用受到了人们越来越多的关注。结合前人的研究结果和最新的研究动态,着重阐述了Na+转运控制和维持细胞离子平衡在植物耐盐过程中的机理及其重要作用。

Na_(2)O对锂铝硅微晶玻璃析晶及性能的影响

采用熔融法制备了不同Na_(2)O含量的透明锂铝硅微晶玻璃,通过DSC、XRD、FESEM等测试方法研究了不同Na_(2)O含量对玻璃析晶及性能的影响。结果表明:Na_(2)O的引入能显著降低玻璃的转变温度和析晶温度,抑制LiAlSi_(4)O_(10)晶相的析出。但Na_(2)O的引入促使微晶玻璃中析出Li_(2)Si_(2)O_(5)新相,并且随着Na_(2)O引入量的增加,Li_(2)Si_(2)O_(5)转变为主晶相。由于晶体尺寸均为纳米级,主晶相的转变对透过率影响较小,微晶玻璃的可见光透过率均高于85%。主晶相的转变有效增强了微晶玻璃的机械性能,其弯曲强度由300 MPa提升至331 MPa。Na_(2)O的引入有效增强了Na-K交换,Na_(2)O含量为4%(质量分数)的Li 2O-Al_(2)O_(3)-SiO_(2)微晶玻璃在410℃的KNO_(3)熔盐中交换6 h后,维氏硬度由7.108 GPa提升至7.403 GPa,弯曲强度由331 MPa提升至470 MPa。

Facile in situ synthesis and characterization of Fe@Si/zeolite Na composites with magnetic core–shell structures from natural materials for enhanced curcumin loading capacity

Curcumin is a natural polyphenol that is used in various traditional medicines.However,its inherent properties,such as its rapid degradation and metabolism,low bioavailability,and short half-life,are serious problems that must be resolved.To this end,a drug carrier incorporating natural magnetic cores in a zeolite framework was developed and applied to the loading of curcumin in ethanol solutions.In this system,curcumin is encapsulated in a zeolite Na(ZNA)magnetic core–shell structure(Fe@Si/ZNA),which can be easily synthesized using an in situ method.Synthesis of Fe_(3)O_(4) nanoparticles was carried out from natural materials using a co-precipitation method.Analysis of the prepared magnetic core–shell structures and composites was carried out using vibrating-sample magnetometery,Fourier transform infrared spectroscopy,transmission electron microscopy,and x-ray diffraction.The cumulative loading of curcumin in the ZNA composite with 9%nanoparticles was found to reach 90.70%with a relatively long half-life of 32.49 min.Stability tests of curcumin loading in the composite showed that adding magnetic particles to the zeolite framework also increased the stability of the composite structure.Adsorption kinetics and isotherm studies also found that the system follows the pseudo-second-order and Langmuir isotherm models.

荞麦主要拒Na^＋部位及其Na^＋／H^＋逆向转运活性的研究

【目的】确定荞麦(Fagopyrum esculentum Moench)的主要拒Na+部位、质子泵和Na+/H+逆向转运活性与其拒Na+特性的关系。【方法】以耐盐荞麦品种川荞1号和盐敏感荞麦品种TQ-0808为试验材料,采用"压力室"法压取木质部汁液,测定各部位拒Na+能力;采用蔗糖密度梯度离心法分离细胞质膜和液泡膜,测定质子泵和Na+/H+逆向转运活性。【结果】盐敏感品种的主要拒Na+部位在根部,耐盐品种的主要拒Na+部位在根部和茎基部,耐盐品种整体拒Na+能力明显大于盐敏感品种;相同盐浓度处理下,耐盐品种质子泵和Na+/H+逆向转运活性明显大于盐敏感品种,说明耐盐品种主要拒Na+部位细胞的排Na+能力和Na+区隔化能力明显大于盐敏感品种。【结论】耐盐品种主要拒Na+部位Na+的区隔化在限制Na+向地上部运输中发挥了重要作用,是耐盐荞麦品种主要拒Na+部位拒Na+的主要方式。

整株水平上Na^+转运体与植物的抗盐性

植物可以利用不同的机制来维持Na+稳态,从而增强植物的抗盐性。这些机制包括:限制Na+的内流;增大Na+的外排;减少Na+向地上部分的运输;把进入地上部分的Na+分散到特殊部分(如老叶)或通过泌盐结构排出体外或通过韧皮部的再循环回到根部。本文简要介绍整株水平上Na+转运体与植物抗盐性的研究进展。

NaCl与Na_2CO_3胁迫对光果甘草幼苗叶片叶绿体色素含量的影响

以水培光果甘草幼苗作为试验材料,分别进行不同浓度NaCl[0.2%,0.5%,0.8%(w/v)]与Na2CO3[0.01%,0.05%(w/v)]胁迫处理,以完全营养液培养作为对照,在处理第5天后测定各处理叶片中叶绿素a,叶绿素b,类胡萝卜素含量并计算叶绿素a与叶绿素b的比值。结果表明:在NaCl胁迫处理下,甘草叶片chla、chab、car含量均以0.2%NaCl为最高,之后随盐浓度升高而下降,而cha/chlb值则随盐浓度的升高而升高,在Na2CO3处理下,甘草叶片chla、chlb、car含量随Na2CO3胁迫处理浓度的升高而升高,而cha/chlb值则呈现下降的变化趋势。无论是NaCl处理还是Na2CO3处理各处理浓度间上述指标差异均达显著或极显著水平。

2022-2023年山东省A(H1N1)pdm09流感病毒HA、NA基因变异特征分析

目的 了解山东省2022-2023流感监测年度分离的A(H1N1)pdm09亚型流感病毒血凝素(hemagglutinin,HA)和神经氨酸酶(neuraminidase,NA)基因的变异特征,为流感的防控提供科学依据。方法 从流感监测网络实验室分离的流感毒株中按地市随机选取14株A(H1N1)pdm09亚型流感毒株,以WHO推荐的当季疫苗株为参考进行全基因组测序,并采用荧光法开展神经氨酸酶抑制(neuraminidase inhibition,NI)实验以评估药物敏感性。结果 山东省2022-2023年度分离的A(H1N1)pdm09流感病毒属于6B.1A分支中的5a.2a进化簇,核苷酸序列比对分析显示,HA和NA基因与2021-2023年度北半球疫苗株A/Victoria/2570/2019的亲缘关系较为接近,同源性分别为98.5%~98.7%和98.8%~99.1%。氨基酸序列分析显示,HA蛋白有20个位点发生了氨基酸序列变异,并发现1株病毒可能发生抗原漂移,有3株病毒发生了HA蛋白糖基化位点的缺失。NA酶相关重要位点未发生变异。NI实验显示,所测流感毒株均对抗流感病毒药物敏感。结论 所监测毒株与疫苗株整体同源性很高,但氨基酸存在一定程度变异,今后有必要持续开展流感病毒基因变异特征监测以了解流感流行的风险,以及评价基因变异对流感疫苗和治疗药物效果的影响。

Na盐修饰的Cu/SiO_(2)催化丙烯环氧化反应研究

通过浸渍法制备了6种Na盐修饰的Cu/SiO_(2)催化剂,利用XRD、TEM和XPS对其晶相结构、粒径大小和Cu物种价态进行了分析,考察了Na盐促进剂种类和摩尔分数对Cu/SiO_(2)催化剂上丙烯氧气环氧化反应性能的影响。结果表明,6种Na盐可以不同程度地还原Cu^(2+)物种,生成不同含量的Cu^(0)或Cu^(+)物种。6种Na盐都可以提高Cu/SiO_(2)的丙烯环氧化活性,而且Na_(2)CO_(3)最有利于环氧丙烷的生成。适量的Na_(2)CO_(3)可以促进Cu^(+)物种的形成,有利于丙烯环氧化反应的进行,但过量的Na_(2)CO_(3)会导致Cu~0物种的产生以及Cu物种的聚集,反而不利于环氧丙烷的生成。Cu^(+)物种摩尔分数越高,Cu/SiO_(2)的丙烯环氧化活性和环氧丙烷的形成速率也越大。小粒径的Cu^(+)物种具有最高的丙烯环氧化活性,是丙烯氧气环氧化反应的活性中心。

基于Na-BP-DME@C阳极的长寿命准固态钠-空气电池

钠-空气电池因其能量密度高、成本低而成为金属-空气电池领域的研究热点。然而,以金属钠为阳极的钠-空气电池存在钠枝晶生长、金属钠界面稳定性差以及金属钠的反应活性高等问题,限制了钠-空气电池的快速发展。为解决上述问题,将联苯钠与导电炭黑复合材料Na-BP-DME@C作为阳极,单壁碳纳米角(SWCHNs)作为催化剂,构建准固态钠-空气电池。基于Na-BP-DME@C阳极的准固态钠-空气电池表现出优异的电化学性能,其电压差为1.5 V,功率密度为3.32 mW/cm^(2),在0.1 mA/cm^(2)电流密度下可稳定循环459 h(约459次)。

Na-Mn共掺对磷酸铁锂正极材料结构与性能的影响

利用碳热还原法成功制备了Li_(0.97)Na_(0.03)Fe_(7/8)Mn_(1/8)PO_(4)正极材料,运用XRD、SEM、EDS和电化学测试等手段对其晶体结构、形貌、元素分布和电化学性能进行研究,并结合第一性原理计算分析材料性能提升的机理。结果表明,Na-Mn掺杂一方面导致LiFePO_(4)晶格畸变,晶格体积增大,扩大了锂离子迁移通道,为锂离子嵌入/脱出提供更大的空间;另一方面使材料在电化学性能上表现出优异的高倍率性能和循环稳定性。Na-Mn掺杂有利于提高材料的锂离子扩散系数和电导率,从而提高其电化学性能。基于第一性原理计算结果表明,Na-Mn共掺杂使LiFePO_(4)晶格膨胀,晶格体积增大,并促使带隙宽度减小,增强了费米能级附近的电子态密度,提高了材料的电子电导率和锂离子迁移率。

基于NAS和教学诊改的多模态教学大数据存储访问优化研究

本文提出一种基于网络附加存储(NAS)和教学诊断与改进(诊改)的多模态教学大数据存储与访问优化方案。该方案通过NAS实现多模态教学资源的集中存储、高效管理和安全共享,利用这些多模态教学数据实现教学活动的持续诊断改进和教育质量的提升。本文分析了NAS和多模态教学数据的特点、存储要求以及NAS在其中的应用。在此基础上,本文结合教学诊改流程,设计了基于NAS的多模态教学大数据存储优化方案。

Designing Conformal Electrode-electrolyte Interface by Semi-solid NaK Anode for Sodium Metal Batteries

Solid-state Na metal batteries(SSNBs),known for its low cost,high safety,and high energy density,hold a significant position in the next generation of rechargeable batteries.However,the urgent challenge of poor interfacial contact in solid-state electrolytes has hindered the commercialization of SSNBs.Driven by the concept of intimate electrode-electrolyte interface design,this study employs a combination of NaK alloy and carbon nanotubes to prepare a semi-solid NaK(NKC)anode.Unlike traditional Na anodes,the paintable paste-like NKC anode exhibits superior adhesion and interface compatibility with both current collectors and gel electrolytes,significantly enhancing the intimate contact of electrode-electrolyte interface.Additionally,the filling of SiO_(2)nanoparticles improves the wettability of NaK alloy on gel polymer electrolytes,further achieving a conformal interface contact.Consequently,the overpotential of the NKC symmetric cell is markedly lower than that of the Na symmetric cell when subjected to a long cycle of 300 h.The full cell coupled with Na_(3)V_(3)(PO_(4))_(2)cathodes had an initial discharge capacity of 106.8 mAh·g^(-1)with a capacity retention of 89.61%after 300 cycles,and a high discharge capacity of 88.1 mAh·g^(-1)even at a high rate of 10 C.The outstanding electrochemical performance highlights the promising application potential of the NKC electrode.

基于NAS私有云的医院档案电子信息自动管理平台

常规的医院档案电子信息自动管理平台主要使用HTMLPHP(Hyper Text Markup LanguageHypertext Preprocessor)超文本预处理语言生成多选项表单,易受服务器Post混乱作用的影响,导致综合运行性能低下,因此,提出一种基于NAS私有云的医院档案电子信息自动管理平台。硬件部分设计HGYUI4033处理芯片和KLOPA1存储器,软件部分利用NAS搭建档案电子信息管理私有云,生成档案电子信息自动管理架构,从而实现电子档案信息的自动管理。平台测试结果表明,文章设计的医院档案电子信息自动管理平台在不同状态下均能有序运行,综合性能良好,具有可靠性,有一定的应用价值,为提高档案综合管理效率、实现档案数字化管理升级作出一定的贡献。

行为m-NA随机变量阵列的完全收敛性

利用截尾方法和矩不等式,在更一般的条件下对m-NA阵列行和的收敛性进行了研究,并得到了m-NA阵列的完全收敛性.所得结果改进了文献[6]的研究结果。

低盐水体Na^(+)/K^(+)对凡纳滨对虾生长、体成分与肝胰腺、鳃组织结构的影响

缺钾在内陆低盐度盐碱水中经常发生,为探究低盐水体中不同钾缺乏程度对凡纳滨对虾生长、存活、体成分以及鳃和肝胰腺组织结构的影响,实验参照海水离子组成配置盐度为2的低盐度水体,在Na^(+)/K^(+)(mg/mg)比值为27、47、67、87、107 (分别记为A、B、C、D、E组)的条件下,对体重为(1.04±0.23) g的凡纳滨对虾幼虾开展了为期60 d的养殖实验。结果显示,E组对虾的存活率为44.64%±20.95%,显著低于A、B、D三组;E组体重为(4.86±0.66) g,显著低于其他4组;A~D组之间的湿重、增重率、特定生长率差异不显著,但均大于E组且差异显著;在饲料系数上,E组最高并与A、D组差异显著。在体成分上,各组全虾钾含量、灰分含量差异不显著,E组的水分含量高于其他组,并与A、B组差异显著;E组粗蛋白含量最低,且与B组差异显著。E组对虾鳃组织角质层明显受损,红细胞数量减少,空泡增多,肝胰腺B细胞及其内部转运泡体积增大,肝小管结构受损。研究表明,低盐条件下严重缺钾引起了对虾鳃和肝胰腺损伤,降低了对虾的存活率和生长率;水体缺钾在前期即可对对虾的生长产生明显影响,而对存活的影响随养殖时间的增加而增大。实验结果有助于为内陆低盐度盐碱水养殖凡纳滨对虾提供理论依据。

Na^(+)通道在锰神经细胞毒性中的作用

目的初步探讨Na^(+)通道在锰神经细胞毒性中对γ-氨基丁酸(GABA)的作用。方法SH-SY5Y细胞建立锰暴露模型,并分为空白对照组、0.25 mmol/L MnCl_(2)、0.50 mmol/L MnCl_(2)、1.00 mmol/L MnCl_(2)。河豚毒素(tetrodotoxin,TTX)0.10μmol/L、0.20μmol/L进行干预,MTT法测其细胞存活率、光学显微镜进行形态学观察、蛋白质印迹法检测Na^(+)通道中Nav1.1通道蛋白和GABA的标记酶谷氨酸脱羧酶65(GAD65)蛋白的表达水平。结果MnCl_(2)可抑制细胞增殖,0.25 mmol/L MnCl_(2)、0.50 mmol/L MnCl_(2)、1.00 mmol/L MnCl_(2)均可显著降低细胞存活率,差异均具有统计学意义(P<0.05);TTX可改善锰暴露所致的神经元损伤,提高细胞存活率,差异具有统计学意义(P<0.05);锰暴露可上调神经元GAD65蛋白表达水平,差异具有统计学意义(P<0.05),但锰暴露未改变神经元细胞Nav1.1蛋白的表达水平,差异无统计学意义(P>0.05)。结论锰暴露所致神经元损伤及GABA能损伤可能与其Nav1.1蛋白表达无关。

NaCl胁迫对盐芥和拟南芥K^+、Na^+吸收的影响(简报)

盐胁迫下植物对K+和Na+的选择性吸收能够代表植物对盐胁迫的适应性。本研究以盐生植物盐芥和甜土植物拟南芥为材料,研究了NaCl胁迫下盐芥和拟南芥幼苗的生长,K+、Na+在根与叶中的含量。结果表明,叶中拟南芥Na+含量逐渐增加,K+含量逐渐减少,K+/Na+逐渐降低;盐芥则完全不同,盐浓度从0逐渐增加到300mmol/L,Na+含量基本没有变化,K+含量先增加然后逐渐减少,K+/Na+先升高然后逐渐降低,100和200 mmol/LNaCl胁迫下,盐芥的K+/Na+分别比拟南芥的高2和5倍。随着NaCl浓度从0逐渐增加到200 mmol/L,盐芥和拟南芥根中Na+和K+的增加和降低趋势相同,盐芥K+的含量随着盐浓度的增加先增加随后逐渐降低,拟南芥K+的含量逐渐降低,相同浓度下根的K+/Na+始终是盐芥高于拟南芥。盐芥表现出盐生植物吸钾拒钠的特性。SNa+/K+值表明盐芥限制地上部分吸收Na+的能力比拟南芥更强。分析结果发现盐胁迫下拟南芥中的Na+与K+含量变化极显著正相关,因此推断它们的吸收通道或载体为单一竞争性。盐芥吸收的Na+与K+含量完全不相关,具有各自独立的载体或通道系统。

Evaluation of the Level of Pollution by Heavy Metals of Market Garden Soils along the Chari River in Ndjamena: Case of the 9th and 7th Districts

The main aim of this study was to characterize the metal content of soils used for market gardening along the Chari river: the 7th and 9th districts of NDjaména. To achieve this, two sites were selected: Gassi and Walia, and two control sites (Gassi and Walia). A total of fifty (50) soil samples were taken (24 from the Gassi site, 24 from the Walia site and 2 as control soils) and then analyzed to determine a number of physico-chemical parameters (pH, OM and electrical conductivity) and heavy metal concentrations in the various soils. The TME content (As, Cd, Cu, Cr, Ni, Pb, Hg and Zn) of the soils was determined by plasma-coupled Atomic Emission Spectrometry. In order to assess the level of contamination in Gassi and Walia soils, the geoaccumulation index (GeoIndex), contamination factor and degree of contamination were calculated. Results for physico-chemical parameters revealed that pH ranged from acidic (4.6) to moderately neutral (6.5), electrical conductivity was higher in cultivated soils (mean 292.14 μs/cm) than in control soils (mean 149.33 μs/cm), and soils were rich in organic matter. Overall, heavy metal concentrations in cultivated soils were higher than in control soils. The pollution estimate shows that soils in the area have no moderate contamination. The increase in TME concentrations in cultivated soils is thought to be due to the input of agricultural inputs to the soil. However, these levels are below the Average shale reference and Canadian guidelines for agricultural soil quality. Principal component analysis shows that metals are positively and significantly correlated with each other, and negatively and moderately significantly correlated with each other.

Oxidation process of low-grade vanadium slag in presence of Na_(2)CO_3

The oxidation process of low-grade vanadium slag in the presence of Na2CO3 was investigated by XRD,SEM/EDS and TG-DSC techniques.The results show that the vanadium slag is oxidized in a temperature range from 273 to 700 °C.Olivine phases and spinel phases are completely decomposed at 500 and 600 °C,respectively.Most of water-soluble sodium vanadates are formed between 500 and 600 °C.When roasting temperature reaches above 700 °C,the vanadium-rich phases of sodium vanadates can be obviously observed.However,at temperature above 800 °C,the samples are sintered.Most of the vanadium is enwrapped by glassy phase compounds which lead to the decrease of the leaching rate of vanadium.At the same time,the effect of roasting temperature on extraction of vanadium and characterization of leach residues were discussed.