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.

钠离子电池正极材料Na_(4)Fe_(3-x)Cr_(x)(PO_(4))_(2)P_(2)O_(7)/C@CNT的制备及电化学性能研究

为改善钠离子电池正极材料Na_(4)Fe_(3)(PO_(4))_(2)P_(2)O_(7)的导电性,提高其充放电性能,采用Cr^(3+)掺杂提高正极材料本征导电性,采用包覆碳和复合碳纳米管(CNT)构筑高效导电网络以加快纳米活性物颗粒间的电子传导,制备并探究了Na_(4)Fe_(3-x)Cr_(x)(PO_(4))_(2)P_(2)O_(7)/C@CNT复合材料的结构与电化学性能。结果表明,当Cr^(3+)掺杂量x为0.075、CNT添加质量分数为3%时,所制备材料表现出较小的电荷传递阻抗和优异的高倍率充放电性能。其0.1 C和20 C倍率下的放电比容量分别达到120.64 mAh/g和87.11 mAh/g,10 C倍率下循环500次后容量保持率高达92.37%。

Preparation of Na_(3)V_(2)(PO_(4))_(3) Cathode Materials by Hydrothermal Assisted Sol-Gel Method for Sodium -Ion Batteries

Na_(3)V_(2)(PO_(4))_(3)(NVP)cathode material of the sodium ion battery(1 C=117 mAh g-1)has a NASICON-type structure,which not only facilitates the rapid migration of sodium ions,but also has a small volume deformation during sodium ion de-intercalation and the main frame mechanism remains unchanged,and thus is seen as an energy storage material for a wide range of applications,but has a limited electronic conductivity due to its structure.In this paper,NVP cathode materials with finer primary particles are successfully prepared using a simple hydrothermal treatment-assisted sol-gel method.The increased pore size of the NVP materials prepared under the hydrothermal process allows for more active sites and more effective resistance to the volume deformation of sodium ions during insertion/extraction processes,effectively facilitating the diffusion of ions and electrons.The Na_(3)V_(2)(PO_(4))_(3) material obtained by the optimized process exhibited good crystallinity in XRD characterization,as well as superior electrochemical properties in a series of electrochemical tests.A specific capacitance of 106.3 mAh g^(-1) at 0.2 C is demonstrated,compared to 96.5 mAh g^(-1) for Na_(3)V_(2)(PO_(4))_(3) without hydrothermal treatment,and cycling performance is also improved with 93%capacity retention.The calculated sodium ion diffusion coefficient(DNa=5.68×10^(-14))obtained after EIS curve fitting of the improved sample illustrates that the pore structure is beneficial to the performance of the Na_(3)V_(2)(PO_(4))_(3)cathode material.

In-situ structural evolution analysis of Zr-doped Na_(3)V_(2)(PO_(4))_(2)F_(3) coated by N-doped carbon layer as high-performance cathode for sodium-ion batteries

With great superiorities in energy density,rate capability and structural stability,Na_(3)V_(2)(PO_(4))_(2) F_(3)(NVPF)has attracted much attentions as cathode of sodium ion battery(SIB),but it also faces challenges on its poor intrinsic electronic conductivity and the controversial de/sodiation mechanism.Herein,a series of Zr-doped NVPF coated by N-doped carbon layer(~5 nm in thickness,homogenously)materials are fabricated by a sol-gel method,and the optimized heteroatom-doping amounts of Zr and N doping improve intrinsic properties on enlarging lattice distance and enhancing electronic conductivity,respectively.Specifically,among all samples of Na_(3) V_(2-x)Zr_(x)(PO_(4))_(2) F_(3)/NC(NVPF-Zr-x/NC,x=0,0.01,0.02,0.05,and 0.1),the optimized electrode of NVPF-Zr-0.02/NC delivers high reversible capacities(119.2 mAh g^(-1) at0.5 C),superior rate capability(98.1 mA h g^(-1) at 20 C)and excellent cycling performance.The structural evolution of NVPF-Zr-0.02/NC electrode,in-situ monitored by X-ray diffractometer,follows a step-wise Na-extraction/intercalation mechanism with reversible multi-phase changes,not just a solid-solutionreaction one.Full cells of NVPF-Zr-0.02/NC//hard carbon demonstrate high capacity(99.8 mA h g^(-1) at 0.5 C),high out-put voltage(3.5 V)and good cycling stability.This work is favorable to accelerate the development of high-performance cathode materials and explore possible redox reaction mechanisms of SIBs.

水热-微波烧结法制备Na_(3)V_(2)(PO_(4))_(2)F_(3)钠离子电池正极材料

具有钠超导三维结构的氟磷酸钒钠(Na_(3)V_(2)(PO_(4))_(2)F_(3),NVPF)因其拥有高工作电压和理论比容量而被应用于钠离子电池正极材料。本研究以偏钒酸铵(NH_(4)VO_(3))为钒源,磷酸二氢铵(NH_(4)H_(2)PO_(4))为磷源、氟化钠(NaF)为氟源和钠源、无水柠檬酸为还原剂,分别添加0.2、1.0、2.0 g和0 g聚乙烯吡咯烷酮K30(PVP)进行碳包覆,用水热-微波法成功制备出氟磷酸钒钠正极材料NVPF/C-1、NVPF/C-2、NVPF/C-3和NVPF,采用X-射线衍射(XRD)、X射线光电子能谱(XPS)、傅里叶红外光谱(FT-IR)、扫描电镜(SEM)以及透射电镜(TEM)对其进行结构和形貌表征,通过恒流充放电测试其电化学性能。实验结果表明,NVPF/C-2呈直径为350~500 nm的球形,其电荷转移电阻为219.4Ω,钠离子扩散系数是NVPF的33倍,在1.0 C电流密度下初始放电容量为104.0 mA·h·g^(-1),经过100次充放电后容量维持在74.3 mA·h·g^(-1)。此外,结果表明PVP能够有效控制NVPF的微粒粒径以及团聚现象,同时其本身存在的大量官能团可有效降低NVPF的电荷转移电阻,提高了钠离子扩散系数,进而有效提升NVPF的电化学性能。

AQP2、γ-ENaC、NHE3在阴虚水肿证大鼠肾脏的表达改变及意义

目的观察水通道蛋白2 (AQP2)、γ型上皮钠通道(γ-ENaC)、Na^+/H^+交换体3 (NHE3)在"阴虚水肿"证大鼠肾脏中的表达及其意义。方法尾静脉注射阿霉素复制"水肿"状态,继予优甲乐灌胃制作"阴虚水肿"证大鼠模型,观察空白组、阴虚水肿组大鼠肾脏AQP2、γ-ENaC、NHE3表达。结果尾静脉注射阿霉素2周大鼠阴囊水肿明显,第4周阴虚水肿组大鼠皮肤含水量高于空白组(P<0.05),提示水肿形成,连续优甲乐灌胃2周阴虚水肿组大鼠活动频繁,躁动不安,易激惹,肛温、TT3、TT4高于空白组(P<0.05),符合"阴虚"表现。AQP2蛋白表达量第2周最高(P<0.05),γ-ENaC、NHE3蛋白表达量第4周最高(P<0.05)。结论 AQP2、γ-ENaC、NHE3参与"阴虚水肿"证大鼠水肿的发生发展。

Composite solid electrolyte of Na3PS4-PEO for all-solid-state SnS2/Na batteries with excellent interfacial compatibility between electrolyte and Na metal

High ionic conductivity and superior interfacial stability of solid electrolytes at the electrodes are crucial factors for high-performance all-solid-state sodium batteries. Herein, a composite solid electrolyte Na3PS4-polyethylene oxide is synthesized by the solution-phase reaction method with an improved ionic conductivity up to 9.4 × 10-5 S/cm at room temperature. Moreover, polyethylene oxide polymer layer is wrapped homogeneously on the surface of Na3PS4 particles, which could effectively avoid the direct contact between Na3PS4 electrolyte and sodium metal, thus alleviate their side reactions. We demonstrate that all-solid-state battery SnS2/Na with the composite solid electrolyte Na3PS4-polyethylene oxide delivers an enhanced electrochemical performance with 230 m Ah/g after 40 cycles.

Progress and prospect for NASICON-type Na3V2(PO4)3 forelectrochemical energy storage

Sodium-ion batteries （SIBs） have attracted increasing attention in the past decades, because of high over-all abundance of precursors, their even geographical distribution, and low cost. Na3V2（PO4）3 （NVP）, atypical sodium super ion conductor （NASlCON）-based electrode material, exhibits pronounced structuralstability, exceptionally high ion conductivity, rendering it a most promising electrode for sodium storage.However. the comparatively low electronic conductivity makes the theoretical capacity of NVP cannot befully accessible even at comparatively low rates, presenting a major drawback for further practical ap-plications, especially when high rate capability is especially important. Thus, many endeavors have beenconformed to increase the surface and intrinsic electrical conductivity of NVP by coating the active mate-rials with a conductive carbon layer, downsizing the NVP particles, combining the NVP particle with vari-ous carbon materials and ion doping strategy. In this review, to get a better understanding on the sodiumstorage in NVP, we firstly present 4 distinct crystal structures in the temperature range of-30℃-225℃ namely α-NVP, β-NVP, β′-NVP and γ-NVP. Moreover, we give an overview of recent approaches to en-hance the surface electrical conductivity and intrinsic electrical conductivity of NVP. Finally, some poten-tial applications of NVP such as in all-climate environment and PHEV, EV fields have been prospected.

The application of carbon materials in nonaqueous Na‐O2 batteries

Na‐O2 batteries are advantageous as the candidates of next‐generation electric vehicles due to their ultrahigh theoretical energy density and have attracted enormous attention recently.Tremendous efforts have been devoted to improve the Na‐O2 battery performance by designing advanced electrodes with various carbonbased materials.Carbon materials used in Na‐O2 batteries not only function as the air electrode to provide active sites and accommodate discharge products but also as Na anode protectors against dendrite growth and chemical/electrochemical corrosion.In this review,we mainly focus on the application of various carbonbased materials in Na‐O2 batteries and highlight their advances.The scientific understanding on the fundamental design of the material microstructure and chemistry in relation to the battery performance are summarized.Finally,perspectives on enhancing the overall battery performance based on the optimization and rational design of carbon‐based cell components are also briefly anticipated.

Carbon dioxide reforming of methane on monolithic Ni/Al_2O_3-based catalysts

Nickel-alumina catalysts supported on cordierite monoliths of honeycomb structure surpass essentially the conventional granulated ones with respect to the output in carbon dioxide reforming of methane. Adjusting the surface acid-base properties of catalysts by introduction of alkali metal （Na, K） oxides inhibits the carbonization and as a result, improves the operational stability of these catalysts. An effect of promotion of nickel-alumina based composite doped by lanthanum oxide is found. This effect, caused by an additional route for the CO2 activation on Ni-La2O3/Al2O3/cordierite catalyst, is displayed in increase of methane conversion under conditions of an oxidant excess.

氮掺杂碳包覆Na_(3)V_(2)(PO_(4))_(2)F_(3)钠离子电池正极材料的制备与性能

锂储量的有限性和不断攀升的锂资源价格限制了锂离子电池在大规模能源存储领域的应用发展,亟需发展可替代锂离子电池的低成本储能技术。在诸多新型二次电池储能体系中,钠离子电池由于钠资源丰富及与锂离子电池相似的储能机制受到了广泛关注。在钠离子电池正极材料中,钠超离子导体材料Na_(3)V_(2)(PO_(4))_(2)F_(3)(NVPF)不仅具有高的工作电压和放电容量,还表现出良好的热稳定性和较小的体积效应,因而具有广阔的应用前景。本工作采用低温水热反应和后续煅烧法制备NVPF,通过在水热过程中添加尿素和柠檬酸制备了氮掺杂碳包覆NVPF的复合材料(NVPF@C-N)。氮元素掺杂改善了碳包覆层的孔道结构和电导率,NVPF@C-N复合材料作为钠离子电池正极材料表现出高的可逆容量以及优异的倍率性能,在1 C下的初始放电比容量为121 mAh/g,10 C下的放电比容量为110 mAh/g,甚至在90 C的高电流密度下放电比容量仍具有66 mAh/g。此外,NVPF@C-N正极材料展示了高的循环稳定性,在1 C下循环200次后的充放电平台能够得到充分保持,且放电比容量仍高达111 mAh/g;特别地,NVPF@C-N在10 C下循环1000次后的容量保持率高达87%,在6000次循环后的容量保持率为54%。

碳纳米纤维修饰Na_(3)V_(2)(PO_(4))_(3)电极材料的研究

本研究采用静电纺丝工艺和煅烧工艺制备碳纳米纤维修饰Na_(3)V_(2)(PO_(4))_(3)材料。所制备的Na_(3)V_(2)(PO_(4))_(3)纳米粒子均匀嵌入在碳纳米纤维中,可以加快充放电循环中的电子和离子传输速率。所制备的钠离子电池复合电极具有良好的电性能,在较低的放电速率(0.1C)下,可提供110 mAh·g^(-1)的高放电容量,约为理论容量的93.7%。当达到5C,可以能提供86 mAh·g^(-1)的初始可逆容量,经过100次循环后仍保持96%的容量。

碳纳米管修饰NaTi_(2)(PO_(4))_(3)电极材料的制备及应用

本文采用溶胶-凝胶法制备复合材料,通过加入碳纳米管来改善其电导率。SEM和TEM分析表明,结晶良好的NaTi_(2)(PO_(4))_(3)@C颗粒均匀地分散并嵌入碳纳米管中,复合材料由于碳层和碳纳米管构成的导电网络可以极大地促进电子/离子的传输。因此,所制备的电极在0.2C下可逆容量高达128.1 mAh·g^(-1),在10C下可逆容量高达94.3 mAh·g^(-1),循环性能优良,在2C下循环200次后容量保持率可达94.2%。从实验结果可以看出该材料应用前景广泛。

两步碳修饰法提高NaTi_2(PO_4)_3负极材料的储钠性能（英文）

NASICON型结构的NaTi_2(PO_4)_3被认为是非水溶液和水溶液钠离子电池极具应用前景的负极材料,但是其储钠性能受到自身电子电导率低的严重制约。本文采用预先制备的碳球和酚醛树脂作为碳源对其进行分步改性以提高其电化学性能。实验结果显示,目标材料的电化学性能明显优于单纯用酚醛树脂修饰的材料。该材料在0.5C倍率下可以输出126.7mA·h/g的放电比容量,并且倍率性能和循环稳定性能优越,在1C,10C,20C下放电比容量分别为115.1,95.5,80.8 mA·h/g,在5C下循环1000次后容量保持率高达92.4%。由于两步碳修饰法的采用,材料电子电导率得到显著提升,再加上材料粒径分布更均匀以及完善的导电网络协同作用,材料倍率性能和循环稳定性均得到明显改善。

High-rate performance and super long-cycle stability of Na_(3)V_(2)(PO_(4))_(3)cathode material coated by diatomic doped carbon

Na_(3)V_(2)(PO_(4))_(3)is considered as one of the most promising cathodes for sodium ion batteries due to its excellent thermal stability,long cycle life and high energy density.However,the inferior intrinsic electronic conductivity which brings about the poor rate capability and cycling performance hinders its commercial application.Herein,the S-N co-doped carbon-coated Na_(3)V_(2)(PO_(4))_(3)(NVP@SNC)has been synthesized to resolve the problem.The prepared NVP@SNC forms a hierarchical structure assembled with nanosheets,which is in favor of the electrolyte infiltration and shortening the Na^(+)transmission distance.Numerous lattice defects can be induced in carbon layer by the co-doped elements(S-N),which reduce the Na^(+)diffusion energy barriers and provide adequate Na^(+)migration channels,thus jointly boosting the Na^(+)diffusion coefficient.Consequently,the NVP@SNC cathode shows a high reversible capacity with outstanding rate performance and super long-cycle stability.When discharged at 2.0C,it delivers the capacity near to the theoretical value with a capacity retention of 88.7%after 400cycles.Even if the current is as high as 50.0C,a high capacity of 58.6 mAh·g^(-1)has been released,and41.4 mAh·g^(-1)has been remained after the super long cycling of 4000 circles.This study is expected to supply a new thought of developing high-performance cathodes by diatomic doping for sodium ion battery.

Polydopamine-derived N-doped carbon-wrapped Na3V2(PO4)3 cathode H with superior rate capability and cycling stability for sodium-ion I batteries

Na superionic conductor (NASICON)-type Na3V2(PO4)3 (NVP) has been regarded as a promising cathode material for sodium-ion batteries (SIBs). However, NVP suffers from poor cyclability and rate capability because of its intrinsically low electronic conductivity. Herein, we successfully syn thesized N-doped carb on-wrapped Na3V2(PO4)3 (NC@NVP) through the carb on izati on of polydopami ne, which is rich in nitrogen species. The strong adhesion properties of the polydopamine lead to effective and homogeneous wrapping of NVP particles, and it I is further turned into a con ductive N-doped carb on n etwork itself, providi ng facile diffusi on of electr ons and Na+ i ons duri ng battery operation. NC@NVP displays remarkable electrochemical performanee, even under harsh operating conditions, such as a high rate capability (discharge capacity of 70.88, 49.21 mA·h·g^-1 at 50 and 100 C), long-term cycling stability (capacity retention of 94.77% over 1,000 cycles at 20 C), and high-temperature cycling (capacity retention of 92.0% after 500 cycles at 60 ℃).

MoS2 embedded in 3D interconnected carbon nanofiber film as a free-standing anode for sodium-ion batteries

As a typical two-dimensional transition metal dichalcogenide, molybdenum disulfide （MoS2） is considered a potential anode material for sodium-ion batteries （NIBs）, due to its relatively high theoretical capacity （~ 670 mAh·g--1）. However, the low electrical conductivity of MoS2 and its dramatic volume change during charge/discharge lead to severe capacity degradation and poor cycling stability. In this work, we developed a facile, scalable, and effective synthesis method to embed nanosized MoS2 into a thin film of three-dimensional （3D）-interconnected carbon nanofibers （CNFs）, producing a MoS2/CNFs film. The free-standing MoS2/CNFs thin film can be used as anode for NIBs without additional binders or carbon black. The MoS2/CNFs electrode exhibits a high reversible capacity of 260 mAh·g^-1, with an extremely low capacity loss of 0.05 mAh·g^-1 per cycle after 2,600 cycles at a current density of 1 A·g^-1. This enhanced sodium storage performance is attributed to the synergistic effect and structural advantages achieved by embedding MoS2 in the 3D-interconnected carbon matrix.

Phase-pure Na3V2(PO4)2F3 embedded in carbon matrix through a facile polyol synthesis as a potential cathode for high performance sodium-ion batteries

In this study,a pseudo-layered Na super-ionic conductor of Na3V2(PO4)2F3 (NVPF)/C cathode for sodium-ion batteries is prepared successfully using a facile polyol refluxing process without any impurity phases.The X-ray diffraction and Rietveld refinement results confirm that NVPF possesses tetragonal NASICON-type lattice with a space group of P42/mnm.In this preparative method,polyol is utilized as a solvent as well as a carbon source.The presence of nanosized NVPF particles in the carbon network is confirmed by field-emission scanning electron microscopy (FE-SEM) and high-resolution transmission electron microscopy (HR-TEM).The existence of carbon is analyzed by Raman scattering and elemental analysis.When applied as a Na-storage material in a potential window of 2.0-4.3 V,the electrode exhibits two flat voltage plateaus at 3.7 and 4.2 V with an electrochemically active V^3+/V^4+ redox couple.In addition,Na3V2(PO4)2F3/C composite achieved a retention capacity of ~ 88% even after 1,500 cycles at 15 C.Moreover,at high current densities of 30 and 50 C,Na3V2(PO4)2F3/C cathode retains the specific discharge capacities of 108.4 and 105.9 mAh·g-1,respectively,revealing the structural stability of the material prepared through a facile polyol refluxing method.

Nitrogen-doped Carbon Coated Na3V2(PO4)3 with Superior Sodium Storage Capability

Cathodes with high cycling stability and rate capability are required for ambient temperature sodium ion batteries in renewable energy storage application.Na3V2(PO4)3 is an attractive cathode material with excellent electrochemical stability and fast ion diffusion coefficient within the 3D NASICON structure.Nevertheless,the practical application of Na3V2(PO4)3 is seriously hindered by its intrinsically poor electronic conductivity.Herein,solvent evaporation method is presented to obtain the nitrogen-doped carbon coated Na3V2(PO4)3 cathode material,delivering cnhanced clectrochemical performances.N-Doped carbon layer coating servfes as a highly conducting pathway,and creates numerous extrinsic defects and active sites,which can facilitate the storage and diffusion of Na^+.Morcover,the N-doped carbon layer can provide a stable framework to accommodate the agglomeration of the electrode upon electrode cycling.N-Doped carbon coated Na3V2(PO4)3(NC-NVP)exhibits excellent long cycling life and superior rate performances than bare Na3V2(PO4)3 without carbon coating.NC-NVP delivers a stable capacity of 95.9mA·h/g after 500 cycles at 1C rate,which corresponds to high capacity retention(94.6%)with respect to the initial capacity(101.4mA·h/g).Over 91.3% of the initial capacity is retained after 500 cycles at 5C,and the capacity can reach 85mA·h/g at 30C rate.

In situ fabrication of Na3V2（PO4）3 quantum dots in hard carbon nanosheets by using lignocelluloses for sodium ion batteries

The rational assembly of quantum dots on two-dimensional(2 D) carbonaceous materials is very promising to produce materials, but remains a challenge. Here, we develop an assembly strategy of growing Na3 V2(PO4)3 quantum dots with superlattice structure(NVP-QDs-SL) for obtaining precise control of the size, distribution and crystallinity. The multifunctional lignocelluloses(LCs) used as a hard carbon source induce heterogeneous nucleation and confined growth of NVP-QDs-SL, leading to the uniform distribution of NVP-QDs-SL in H/S-doped hard carbon ultra-thin nanosheets(HCS). Detailed electrochemical analysis results from sodium-ion batteries of NVP-QDs-SL show that NVP-QDs-SL could trap the electrons inside HCS, significantly enhancing Na ion storage and transfer kinetics. Compared to the common Na3 V2(PO4)3 nanoparticle cathode, the NVP-QDs-SL/HCS cathode exhibits a high reversible capacity of 149.2 m A h g^-1 at a 0.1 C rate, which is far beyond the theoretical capacity of Na3 V2(PO4)3(117.6 m A h g^-1).At the ultrahigh current rate of 100 C, this cathode still remains a high discharge capacity of 40 m A h g-1.Even after cycling at 20 C over 3000 cycles, an ultrahigh coulombic efficiency close to 100% is still obtained,highlighting its excellent long cycling life, remarkable rate performance and energy density.