Separator coatings as efficient physical and chemical hosts of polysulfides for high-sulfur-loaded rechargeable lithium–sulfur batteries

Lithium-sulfur batteries(LSBs)are promising alternative energy storage devices to the commercial lithium-ion batteries.However,the LSBs have several limitations including the low electronic conductivity of sulfur(5×10^-30S cm^-1),associated lithium polysulfides(PSs),and their migration from the cathode to the anode.In this study,a separator coated with a Ketjen black(KB)/Nafion composite was used in an LSB with a sulfur loading up to 7.88 mg cm^-2to mitigate the PS migration.A minimum specific capacity(Cs)loss of 0.06%was obtained at 0.2 C-rate at a high sulfur loading of 4.39 mg cm^-2.Furthermore,an initial areal capacity up to 6.70 mAh cm^-2 was obtained at a sulfur loading of 7.88 mg cm^-2.The low Cs loss and high areal capacity associated with the high sulfur loading are attributed to the large surface area of the KB and sulfonate group(SO3^-)of Nafion,respectively,which could physically and chemically trap the PSs.

Density Functional Theory for Battery Materials

Batteries are the most widely used energy storage devices, and the lithiumion battery is the most heavily commercialized and most widely used battery type in the industry. However, the current rapid development of society requires a major advancement in battery materials to achieve high capacity,long life cycle, low cost, and reliable safety. Therefore, many new efficient energy storage materials and battery systems are being developed and explored, and their working mechanisms must be clearly understood before industrial application. In recent years, density functional theory (DFT) has been employed in the energy storage field and has made significant contributions to the understanding of electrochemical reaction mechanisms and to virtual screening of promising energy storage materials. In this review,the applications of DFT to battery materials are summarized and exemplified by some representative and up-to-date studies in the literature. The main focuses in this review include the following:1) structural stability estimation by cohesive energy, formation energy, Gibbs free energy, and phonon dispersion spectra calculations;2) the Gibbs free energy calculations for electrochemical reactions, corresponding open-circuit voltage, and theoretical capacity predictions of batteries;3) the analyses of molecule orbitals, band structures, density of states (DOS), and charge distribution of battery materials;4) ion transport kinetics in battery materials;5) simulations of adsorption processes. We conclude the review with the discussion of the assessments and validation of the popular functionals against several benchmarks, and a few suggestions have been given for the selection of density functionals for battery material systems.

Niobium oxyphosphate nanosheet assembled two-dimensional anode material for enhanced lithium storage

The development of high-capacity and high-rate anodes has become an attractive endeavor for achieving high energy and power densities in lithium-ion batteries(LIBs).Herein,a new-type anode material of reduced graphene oxide(rGO) supported niobium oxyphosphate(NbOPO_4) nanosheet assembled twodimensional composite material(NbOPO_4/rGO) is firstly fabricated and presented as a promising highperformance LIB anode material.In-depth electrochemical analyses and in/ex situ characterizations reveal that the intercalation-conversion reaction takes place during the first discharge process,followed by the reversible redox process between amorphous NbPO_4 and Nb which contributes to the reversible capacity in the subsequent cycles.Meanwhile,the lithiation-generated Li3 PO_4,behaving as a good lithium ion conductor,facilitates ion transport.The rGO support further regulates the structural and electron/ion transfer properties of NbOPO_4/rGO composite compared to neat NbOPO_4, resulting in greatly enhanced electrochemical performances.As a result,NbOPO_4/rGO as a new-type LIB anode material achieves a high capacity of 502.5 mAh g^(-1) after 800 cycles and outstanding rate capability of 308.4 mAh g^(-1) at 8 A g^(-1).This work paves the way for the deep understanding and exploration of phosphate-ba sed high-efficiency anode materials for LIBs.

Lagrangian eddies in the Northwestern Pacifi c Ocean

The Lagrangian eddies in the western Pacifi c Ocean are identifi ed and analysed based on Maps of Sea Level Anomaly(MSLA)data from 1998 to 2018.By calculating the Lagrangian eddy advected by the AVISO velocity fi eld,we analyzed the variations in Lagrangian eddies and the average transport eff ects on diff erent time scales.By introducing the Niño coeffi cient,the lag response of the Lagrangian eddy to El Niño is found.These data are helpful to further explore the role of mesoscale eddies in ocean energy transfer.Through normalized chlorophyll data,we observed chlorophyll aggregation and hole eff ects caused by Lagrangian eddies.These fi ndings demonstrate the important role of Lagrangian eddies in material transport.The transportation volume of the Lagrangian eddy is calculated quantitatively,and several major transport routes have been identifi ed,which helps us to more accurately and objectively estimate the transport capacity of Lagrangian eddies in the western Pacifi c Ocean.

Interface engineering strategy via electron-defect trimethyl borate additive toward 4.7 V ultrahigh-nickel LiNi_(0.9)Co_(0.05)Mn_(0.05)O_(2)battery

The Li metal battery with ultrahigh-nickel cathode(LiNi_(x)M_(1-x)O_(2),M=Mn,Co,and x≥0.9)under high-voltage is regarded as one of the most promising approaches to fulfill the ambitious target of 400 Wh/kg.However,the practical application is impeded by the instability of electrode/electrolyte interface and Ni-rich cathode itself.Herein we proposed an electron-defect electrolyte additive trimethyl borate(TMB)which is paired with the commercial carbonate electrolyte to construct highly conductive fluorine-and boron-rich cathode electrolyte interface(CEI)on LiNi_(0.9)Co_(0.05)Mn_(0.05)O_(2)(NCM90)surface and solid electrolyte interphase(SEI)on lithium metal surface.The modified CEI effectively mitigates the structural transformation from layered to disordered rock-salt phase,and consequently alleviate the dissolution of transition metal ions(TMs)and its“cross-talk”effect,while the enhanced SEI enables stable lithium plating/striping and thus demonstrated good compatibility between electrolyte and lithium metal anode.As a result,the common electrolyte with 1 wt%TMB enables 4.7 V NCM90/Li cell cycle stably over 100 cycles with 70%capacity retention.This work highlights the significance of the electron-defect boron compounds for designing desirable interfacial chemistries to achieve high performance NCM90/Li battery under high voltage operation.

Li-Ion Transport Mechanisms in Selenide-Based Solid-State Electrolytes in Lithium-Metal Batteries:A Study of Li_(8)SeN_(2),Li_(7)PSe_(6),and Li_(6)PSe_(5)X(X=Cl,Br,I)

To achieve high-energy-density and safe lithium-metal batteries(LMBs),solid-state electrolytes(SSEs)that exhibit fast Li-ion conductivity and good stability against lithium metal are of great importance.This study presents a systematic exploration of selenide-based materials as potential SSE candidates.Initially,Li_(8)SeN_(2)and Li_(7)PSe_(6)were selected from 25 ternary selenides based on their ability to form stable interfaces with lithium metal.Subsequently,their favorable electronic insulation and mechanical properties were verified.Furthermore,extensive theoretical investigations were conducted to elucidate the fundamental mechanisms underlying Li-ion migration in Li_(8)SeN_(2),Li_(7)PSe_(6),and derived Li_(6)PSe_(5)X(X=Cl,Br,I).Notably,the highly favorable Li-ion conduction mechanism of vacancy diffusion was identified in Li6PSe5Cl and Li_(7)PSe_(6),which exhibited remarkably low activation energies of 0.21 and 0.23 eV,and conductivity values of 3.85×10^(-2)and 2.47×10^(-2)S cm^(-1)at 300 K,respectively.In contrast,Li-ion migration in Li_(8)SeN_(2)was found to occur via a substitution mechanism with a significant diffusion energy barrier,resulting in a high activation energy and low Li-ion conductivity of 0.54 eV and 3.6×10^(-6)S cm^(-1),respectively.Throughout this study,it was found that the ab initio molecular dynamics and nudged elastic band methods are complementary in revealing the Li-ion conduction mechanisms.Utilizing both methods proved to be efficient,as relying on only one of them would be insufficient.The discoveries made and methodology presented in this work lay a solid foundation and provide valuable insights for future research on SSEs for LMBs.

基于数值模拟的流势分析技术在缝洞型油藏开发中的应用

油藏中流体所具有的能量决定流体流动方向,为研究缝洞型油藏流体能量分布规律,建立了缝洞型油藏流势理论模型,确定三维流体势表征方法。通过单洞底水、单洞边水、双洞底水、双洞边水4种典型缝洞结构的机理模型研究流势变化规律,并确定了5种影响流势调整效果的主控因素,最终结合流势分析技术开展了剩余油挖潜研究。结果表明:单洞底水模型进行流势调整,生产井受效最好;模型水体倍数为决定性因素,水体倍数小于10倍时调流势效果好;排液量越大,对于生产井控水效果越好。提出的数学模型能够真实地反映出地层中流体能量分布变化规律,结合流势分析技术提出了挖潜方案,应用于现场效果明显。

以开设体外诊断产业特色方向培养医学检验创业人才的探索

体外诊断(in vitro diagnosis,IVD)产业发展迅猛,我国IVD每年复合增长率保持在15%~20%,增速明显高于全球平均水平,IVD企业急需大量医学检验体外诊断复合型人才。然而,近40多年来,我国高校医学检验专业办学模式、培养目标及课程体系设置等变化不大,培养目标单一,课程设置同质化严重,医学检验专业人才培养与岗位需求严重脱节。为培养体外诊断产业复合型医学检验人才,以行业发展和岗位需求为导向,我院设置了“体外诊断产业”特色拓展方向,与体外诊断企业共同成立“体外诊断现代产业学院”,修订了人才培养方案,优化了课程体系,主编了相应课程创新特色教材,组织牵头全国高校医学检验专业毕业生体外诊断企业在线招聘会,效果显著。

低氧环境诱发的脂质代谢异常在肺动脉高压疾病过程中的意义

目的探讨低氧环境诱发的脂质代谢异常在诊治肺动脉高压疾病过程中的意义。方法选取SPF级雄性C57BL/6小鼠30只,随机分为模型组和对照组,每组15只,模型组小鼠制备低氧性肺动脉高压模型,对照组给予常氧饲养,采用右心导管法测量2组小鼠右心室收缩压,Masson染色观察肺小血管重塑情况,ELISA法检测高密度脂蛋白(HDL-C)、胆固醇(TC)和低密度脂蛋白(LDL-C)水平,采用实时定量PCR检测肝组织HMG-Co A还原酶(HMGCR)、低密度脂蛋白受体(LDLR)基因的表达。结果模型组右心室收缩压和右心室肥大指数分别为(40.12±8.22)mmHg(1 mmHg=0.133 kPa)和0.352±0.050,明显高于对照组(P<0.05);模型组肺小动脉血管壁明显比对照组增厚;模型组HDL-C为(262.0±37.3)mg/L,明显低于对照组(P<0.05);模型组和对照组中TC和LDL-C差异无统计学意义(P>0.05);模型组ABCA1基因和LDLR基因表达分别为0.974±0.301和1.038±0.322,明显高于对照组(P<0.05);右心室收缩压与HDL-C、LDLR基因表达呈负相关(r=-0.571、-0.422和-0.317,P<0.05);右心室肥大指数与LDL-C、HDL-C、TC及脂质代谢相关基因水平无相关性(P>0.05)。结论低氧性肺动脉高压小鼠体内脂质代谢异常可能参与了小鼠低氧性肺动脉高压的发生发展。

磁共振成像系统软硬件故障维修两例

磁共振成像(Magnetic Resonance Imaging,MRI)系统是非常重要的影像诊断设备,其故障会对医院造成较大的影响。MRI系统主要由硬件和软件两部分组成,本文分别分析了MRI硬件和软件方面的两例典型故障,在两例故障中,分别对报错信息与报错现象进行分析,结合维修手册与维修经验,进行了逐步分析,最终故障得以解决。本文提供的维修方法可以为工程师提供参考。

关于双源CT临床应用现状的探讨

随着医疗设备的迅速更新发展,临床各疾病的检查方式开始有了新的选择。近年来双源电子计算机断层扫描(DSCT)技术受到的关注越来越多,这一新技术在临床诊断、评估疾病的应用上突破了传统CT的多项技术弊端。本文介绍了DSCT的技术原理及部分功能,如估计组织内的成分及含量、去骨及钙化技术、进行完全同步的双能量CT(DECT)扫描,并对DSCT目前的临床应用做以综述。

SLM成型件表面球化程度表征方法及等级检测

球化现象是选区激光熔化(SLM)成型过程中最常发生的缺陷,同时影响了最终成型部件的疲劳寿命和物理性能。合理控制部件成型过程中球化现象的发生,对维持成型过程的持续进行以及获得高质量的成型部件具有重大意义。本文在研究SLM成型过程中部件表面球化特征提取方法的基础上提出了球化程度表征方法,并通过正交实验验证了球化程度表征方法的有效性,建立了球化程度与激光能量密度之间的关联关系。同时对球化程度等级做了界定,最终构建了深度卷积神经网络(CNN)模型自动识别部件表面球化程度等级,以辅助实验及生产人员做出相应的决策。模型识别结果表明,在小的图像分割集上,网络识别精度达到了96.4%,当在所采集的全局显微图像集上,其识别精度达到了100%,取得了良好的识别效果。本研究将为SLM成型过程中成型质量的实时控制提供有效实现途径。

彩色多普勒超声的常见故障与维修进展

随着当今现代先进技术的发展,使得彩色多普勒超声凭借着自身经济和无创等临床特点能够广泛应用于临床疾病诊治中,且已经成为当今现代医学影像疾病诊断技术中的重要组成部分。但是,彩色多普勒超声也会出现不同的故障,影响其应用,导致彩色多普勒超声出现故障的常见原因就是忽视器械维护以及设备本身原件老化等。故而,本文对彩色多普勒超声的常见故障与维修进行综述。

校-企(院)协同在医学检验特色拓展方向人才分类培养中的探索

以医学检验技术专业教育国家质量标准及检验行业、产业发展为依据,以就业岗位需求为导向,设立“形态学检验”“IVD产业”“科研与创新(含研究生应考)”三个拓展方向,开设相关方向特色课程模块,主编相关教材;学校与IVD企业(医院)产学研合作,共同制订人才培养方案,实施导师制,协同培养拓展方向人才;学生除了完成医学检验专业所必须完成的课程外,同时,学生根据自己的兴趣、志向与职业规划,选择其中的一个方向作为自己拓展方向,选修相关方向特色课程模块,完成见习、实习环节,让自己学有专长。

CLCA1在结肠癌组织中的表达及临床意义

目的:探讨CLCA1在结肠癌组织中的表达水平及其与肿瘤进展和预后的关系。方法:随机选取西安交通大学第一附属医院及第四军医大学西京医院行手术切除的临床结肠癌病例239例,应用免疫组织化学方法检测结肠癌组织及癌旁组织中CLCA1的表达情况,使用统计学方法分析CLCA1在结肠癌中的表达与肿瘤临床病理特征及预后的相关性。结果:CLCA1在肿瘤中的表达较癌旁组织显著降低(P<0.05),CLCA1在结肠癌中表达与原发肿瘤浸润深度、淋巴转移和肿瘤TNM分期显著相关(P<0.05),而且CLCA1低表达组患者总体生存期较高表达组显著缩短(P<0.001),多因素分析显示CLCA1的表达可作为结肠癌的独立预后因素。结论:CLCA1在结肠癌中表达下调,CLCA1的低表达与肿瘤的侵袭转移和临床预后密切相关,有望作为结肠癌个体化治疗靶点。

内镜下金属钛夹联合组织胶注射治疗胃静脉曲张的疗效研究

目的探讨内镜下金属钛夹联合组织胶注射治疗对GOV1、GOV2、IGV1型胃静脉曲张的临床疗效。方法回顾性分析2017年1月1日-2020年12月31日于西安交通大学第一附属医院住院治疗的150例GOV1、GOV2、IGV1型胃静脉曲张患者。依据治疗方案分为对照组(组织胶治疗,105例)、观察组(钛夹联合组织胶治疗,45例),对比分析两组的临床疗效、再出血率、并发症等。按0、1、3、6个月行随访序贯治疗,共计10个月。结果观察组合并胃/脾肾分流率为22.2%,显著高于对照组0%(P<0.001);观察组胃静脉曲张条数为3(3,3)条,显著高于对照组3(2,3)条(P=0.028);观察组术中平均组织胶用量为(3.29±1.0)mL,显著低于对照组[(4.11±1.51)mL,P=0.020];观察组术后再出血率为11.1%,显著低于对照组(27.6%,P=0.027)。两组内镜治疗次数、组织胶点数、有效率、静脉曲张根除/基本消失率、术后胸骨后疼痛及发热发生率等差异均无统计学意义(P>0.05),两组均未发生菌血症、异位栓塞等严重并发症。结论钛夹联合组织胶注射治疗可减少组织胶用量、降低术后再出血发生率,并可能阻断胃/脾肾分流者异位栓塞的发生,是GOV1、GOV2、IGV1型胃静脉曲张的有效治疗方式。

Interface enhanced well-dispersed Co9S8 nanocrystals as an efficient polysulfide host in lithium–sulfur batteries

The high specific capacity and energy density of lithium-sulfur batteries have attracted strong considerations on their fundamental mechanism and energy applications.However,polysulfide shuttle is still the key issue that impedes the development of Li-S batteries.Exploring nanocrystal hosts for polysulfide immobilization and conversion is a promising way.In this contribution,we have investigated well-dispersed Co9S8 nanocrystals grown on graphene oxide(GO)nanosheets with different degrees of dispersion as cathode host materials for Li-S batteries.The Co9S8-GO composite with 1 wt%GO(GCS1)has an average crystal size of 76 nm and shows the strongest adsorption capability toward lithium polysulfides.When used as the host material for the cathode of Li-S batteries,the GCS1-sulfur composite exhibits an initial specific capacity of^-1000 mAh g^-1 at 0.5 C and shows an average decay rate of 0.11%for 500 cycles.This work on the dispersion control of Co9S8 nanocrystals may inspire more investigations on well-dispersed nanocrystal based hosts for Li-S batteries.

优质稻N两优769试种表现及栽培技术要点

N两优769是福建省南平市农业科学研究所与武夷山科力兴种业有限公司联合利用母本N15S、父本南恢769杂交育成的晚籼型两系杂交水稻新品种,2021年通过福建省农作物品种审定。2021年分别在建阳区莒口镇后山村、武夷山市岚谷乡吴屯村作晚稻种植,均表现出分蘖力强、高产稳产、米质优、适应性广等优良特性。总结了N两优769在建阳区和武夷山市等地的种植表现和栽培要点。

浅析偏位预应力管桩竖向承载力的影响因素

本文通过对倾斜预应力管桩竖向承载力的分析,研究了桩长和桩倾斜角对预应力管桩承载能力的影响情况,为工程中倾斜预应力管桩的处理和分析提供了参照.结果表明:预应力混凝土管桩极限承载力与倾角之间的关系是,只有在倾斜角度达到一定值时,倾角才会对管桩极限承载能力产生影响。

结肠癌患者循环miR-630的表达及其临床意义

目的:探讨结肠癌患者外周血中microRNA-630(miR-630)的表达,进一步分析其表达对评估结肠癌进展及预后的价值。方法:使用实时荧光定量PCR(Real time PCR)检测55例结肠癌及21例正常对照者外周血中miR-630的表达,采用统计学方法分析miR-630在结肠癌外周血中的表达及其与肿瘤进展和预后的关系。结果:分析Real time PCR检测结果发现,结肠癌患者外周血中miR-630的表达显著高于正常对照(P<0.05),外周血中miR-630表达与结肠癌的侵袭、转移和分期显著相关(P<0.05),单因素和多因素生存分析发现外周血中miR-630的表达上调与结肠癌预后不良显著相关(P<0.05)。结论:结肠癌患者循环miR-630表达显著上调,与结肠癌侵袭和转移密切相关,并可作为结肠癌的独立预后标记分子。