Novel Anode(新型阳极)研究综述
Novel Anode 新型阳极 - In this study, we propose a facile one-pot hydrothermal strategy to synthesize silicon-doped FeOOH@reduced graphene oxide (Si-FeOOH@rGO) composites, which integrate the advantages of hybridization and doping engineering as novel anodes for LIBs. [1] Hence, new insight into a novel anode with a surface-preferred (002) crystal plane is provided. [2] The techniques of XRD, XPS, and VSM were used to characterize the elemental composition and the types of the reaction products in order to clarify the interaction between novel anode and phosphate ions. [3] 2 nm (FeVO UNSs) as a novel anode for rapid and reversible sodium-ion storage. [4] Herein, we explore a CuP2/C composite as a novel anode for PIBs, which delivers a high reversible capacity of >450 mA h g−1. [5] The results indicate that 2D AlSi performs great as a novel anode due to the moderate adhesion to Li and low barrier for ion diffusion. [6] Herein, we report a novel anode with a pomegranate-like nanostructure of SnP2O7 particles homogeneously dispersed in the robust N-doped carbon matrix. [7] The results indicate that bilayer phosphorus perform better as a novel anode due to the stronger adhesion to Li and lower barrier for ion diffusion. [8] Herein, a novel anode-free aqueous dual-ion cell is developed with expanded graphite as cathode, inactive current collector as anode replacement and inorganic/organic hybrid zinc salts as electrolyte. [9] Concentrated solar thermionic converters (CSTCs) are proposed by using three-dimensional (3D) Dirac material (DM) as the novel anode, significantly improving device performance. [10] Here, monoclinic CePO4 nanorods is synthesized and firstly evaluated as a novel anode of Li-ions batteries (LIBs). [11] The present study aims to investigate the synergistic effect of MoS2/CNTs nanocomposite as a novel anode-modifying material of MFCs. [12] 9 kg m−3 d−1 is obtained with this novel anode (1. [13] The CoPS@C nanocomposite as a novel anode can maintain a capacity of about 713 mA h g−1 after 50 cycles at a current density of 0. [14] Finally, we made use of these novel anodes for the assembly of Li-ion batteries exhibiting stable cycle life (cycled for over 500 cycles with <50% capacity loss at 0. [15] In this work, we have designed a novel anode of three-dimensional porous interconnected carbon matrix embedded with Sb nanoparticles (Sb ⊂ 3DPC) via a scalable and facile polymer-blowing and galvanic replacement route. [16] Herein, the MoP@C nanocomposite was successfully fabricated via a facile sol–gel approach followed by an annealing process, which demonstrated excellent electrochemical properties as a novel anode for sodium storage. [17] These important synergisms allows finding conditions in which the novel anode can be competitive with the BDD. [18] We report a novel anode with silicon nanoparticles (SiNPs) enclosed in the cross-linked network of Ti3C2Tx, one of the typical two-dimensional transition metal carbides (MXenes), which can encapsulate SiNPs as well as providing void space for the expansion of SiNPs during lithiation. [19] In this study, a simple multiple templates strategy is applied to obtain the hierarchical porous carbon (HPC) material as a novel anode for PIBs after the pyrolysis and washing of polyacrylate (PAA) composed of NaCl crystals and Zn nanoparticles. [20] For practical applications, the power production of MFCs needs to be enhanced and the use of novel anode and cathode catalyst can certainly help in this regard. [21] 94@GO composite can serve as a novel anode for KIBs, and exhibit superior potassium storage performance. [22] The synthesis of this novel anode with promising electrochemical performance reached the simple and effective use of boron, which may also provides new insights into boron-based anode materials for batteries. [23]在这项研究中,我们提出了一种简便的一锅水热策略来合成硅掺杂的 FeOOH@还原氧化石墨烯 (Si-FeOOH@rGO) 复合材料,该复合材料结合了杂化和掺杂工程作为新型 LIB 阳极的优势。 [1] 因此,提供了对具有表面优选(002)晶面的新型阳极的新见解。 [2] 采用 XRD、XPS 和 VSM 技术表征元素组成和反应产物类型,以阐明新型阳极与磷酸根离子之间的相互作用。 [3] 2 nm (FeVO UNSs) 作为用于快速和可逆钠离子存储的新型阳极。 [4] 在此,我们探索了一种 CuP2/C 复合材料作为 PIBs 的新型负极,它具有 >450 mAh g-1 的高可逆容量。 [5] 结果表明,由于对锂的适度粘附和离子扩散的低势垒,2D AlSi 作为一种新型负极表现出色。 [6] 在此,我们报告了一种新型阳极,其具有石榴状纳米结构的 SnP2O7 颗粒,均匀分散在坚固的 N 掺杂碳基体中。 [7] 结果表明,双层磷作为一种新型负极性能更好,因为它对锂的附着力更强,离子扩散的屏障更低。 [8] 在此,开发了一种新型无阳极水系双离子电池,膨胀石墨作为阴极,惰性集流体作为阳极替代物,无机/有机杂化锌盐作为电解质。 [9] 通过使用三维(3D)狄拉克材料(DM)作为新型阳极,提出了聚光太阳能热离子转换器(CSTC),显着提高了器件性能。 [10] 在这里,合成了单斜晶系 CePO4 纳米棒,并首次将其作为锂离子电池 (LIB) 的新型负极进行了评估。 [11] 本研究旨在研究 MoS2/CNTs 纳米复合材料作为新型 MFCs 阳极改性材料的协同效应。 [12] 使用这种新型阳极 (1. [13] CoPS@C 纳米复合材料作为一种新型负极,在电流密度为 0 的情况下,经过 50 次循环后仍可保持约 713 mA h g-1 的容量。 [14] 最后,我们利用这些新型负极组装锂离子电池,表现出稳定的循环寿命(循环超过 500 次,0 时容量损失 <50%。 [15] 在这项工作中,我们通过可扩展且简便的聚合物吹塑和电置换路线设计了一种嵌入 Sb 纳米粒子 (Sb⊂3DPC) 的三维多孔互连碳基质的新型阳极。 [16] 在此,MoP@C 纳米复合材料通过简便的溶胶-凝胶方法和退火工艺成功制备,作为新型钠储存阳极表现出优异的电化学性能。 [17] 这些重要的协同作用允许找到新阳极可以与 BDD 竞争的条件。 [18] 我们报告了一种新型阳极,其硅纳米粒子 (SiNPs) 包裹在 Ti3C2Tx 的交联网络中,这是典型的二维过渡金属碳化物 (MXenes) 之一,它可以封装 SiNPs 并为 SiNPs 的扩展提供空隙空间在锂化过程中。 [19] 在这项研究中,在对由 NaCl 晶体和 Zn 纳米粒子组成的聚丙烯酸酯 (PAA) 进行热解和洗涤后,采用简单的多模板策略获得了分层多孔碳 (HPC) 材料作为 PIBs 的新型阳极。 [20] 对于实际应用,需要增强 MFC 的发电能力,而新型阳极和阴极催化剂的使用肯定会在这方面有所帮助。 [21] 94@GO复合材料可作为KIBs的新型阳极,并表现出优异的钾储存性能。 [22] 这种具有良好电化学性能的新型负极的合成达到了硼的简单有效利用,这也可能为电池用硼基负极材料提供新的见解。 [23]
lithium ion battery
This study reports one dimensional lithium hexaoxotungstate (Li6WO6), with a diameter in the range of 200–500 nm, as a novel anode material for lithium-ion batteries. [1] We report a novel anode consisting of detonation nanodiamond, SiOx nanoparticals and carbon nanosheets, to achieve high performance lithium-ion batteries. [2] To increase energy density in lithium-ion batteries (LIBs), novel anode materials are considered based on conversion and alloying mechanisms as these typically possess far higher storage capacity than graphite, however, cyclability of these compounds is typically poor. [3] As a novel anode for lithium ion batteries (LIBs), the FS/N-HCUF-700S exhibits high initial discharge capacity of 1542. [4] This work details the facile preparation of a hexagonally ordered monolayer electrode with monodispersed hollow C/Fe3O4 microspheres as a novel anode candidate for lithium-ion batteries. [5] Orthoboric acid nanowires with high first discharge capacity are believed to have great prospects for the development of novel anode materials for lithium ion batteries. [6] Two-dimensional (2D) carbon-coated sandwich-like mesoporous SnO2/graphene/mesoporous SnO2 nanosheets (C@SnO2-rGO-SnO2) is conceived and synthesized as a novel anode material towards advanced lithium-ion battery. [7] This study shows that ZnO/ZnFe2O4 has the potential as a novel anode material for lithium ion batteries. [8] It is very important to explore novel anode materials alternative to graphite considering its poor safety and rate performance working at low temperature in lithium ion batteries. [9] Finding novel anode materials in place of the current commonly used but performance-limited graphite is the top priority for the remarkable development of lithium-ion batteries (LIBs). [10] The good electrochemical performance for Zn3V3O8 two-dimensional micro sheets make it possible to be used as novel anode for lithium ion battery application. [11] In this work, platinum single atom enhanced mushroom-based carbon (Pt1/MC) materials have been facilely synthesized and served as novel anode materials in lithium ion batteries (LIBs). [12] Copper vanadates have received considerable attention as the novel anode materials for lithium ion battery. [13] 8 is reported as a novel anode active material for lithium-ion batteries. [14] Na2TiSiO5 is investigated as a novel anode of the lithium ion battery for the first time. [15] Cobalt sulfides (including CoS, CoS2, Co3S4, Co9S8 and nonstoichiometric Co1−xS) are deemed to a kind of novel anode material for lithium ion batteries due to their large specific capacities. [16] As a consequence, the comprehensive fabrication of the Si–SiO2@Fe/NC composite from industrial wastes could provide a promising idea to develop novel anodes for lithium ion batteries. [17] A facile and inexpensive synthesis process is developed to derive carbonaceous nanomaterials from dumped bicycle's inner rubber tube as a novel anode material for lithium ion batteries. [18]本研究报告了直径在 200-500 nm 范围内的一维六钨酸锂 (Li6WO6) 作为锂离子电池的新型负极材料。 [1] 我们报告了一种由爆轰纳米金刚石、SiOx 纳米颗粒和碳纳米片组成的新型阳极,以实现高性能锂离子电池。 [2] nan [3] nan [4] nan [5] nan [6] nan [7] nan [8] nan [9] nan [10] nan [11] nan [12] nan [13] nan [14] nan [15] nan [16] nan [17] nan [18]
high specific capacity 高比容量
Hard carbon materials are employed as a novel anode material in lithium ion batteries (LIBs) due to its large specific surface area, high specific capacity and stable cycle performance. [1] This work paves the ideas for the design of novel anode materials with high specific capacity, good cycling stability and outstanding rate capability for PIBs. [2] The flexible amorphous coatings, well dispersed and ultrafine active particles, as well as highly conductive networks in the constructed architecture endows this novel anode materials a good long-cycle stability and rate performance, so that a high specific capacity of 400 mAh g-1 can be retained at 2 C (1. [3]硬碳材料具有比表面积大、比容量高、循环性能稳定等优点,被用作锂离子电池(LIBs)的新型负极材料。 [1] 这项工作为设计具有高比容量、良好循环稳定性和出色倍率性能的PIBs新型负极材料铺平了思路。 [2] nan [3]
Develop Novel Anode 开发新型阳极
This study proposes an effective strategy to develop novel anodes with excellent cycling and rate properties for SIBs by encapsulating active nanoparticles into carbon matrix. [1] It is urgent to develop novel anode materials with high energy density and facile synthetic procedures, since the development of commercial lithium ions batteries (LIBs) is limited by the unsatisfied capacity of graphite. [2] Thus, there is an urgent need to develop novel anode materials that are suitable for K ions. [3] As a consequence, the comprehensive fabrication of the Si–SiO2@Fe/NC composite from industrial wastes could provide a promising idea to develop novel anodes for lithium ion batteries. [4]本研究提出了一种有效的策略,通过将活性纳米粒子封装到碳基质中来开发具有优异循环和倍率性能的新型负极。 [1] 由于石墨容量不足,限制了商业锂离子电池(LIB)的发展,因此迫切需要开发具有高能量密度和简便合成工艺的新型负极材料。 [2] nan [3] nan [4]
Explore Novel Anode
The single-phase binary nickel vanadate Ni2V2O7 was successfully synthesized by a simple solid-state method to explore novel anode materials for lithium-ion batteries. [1] It is very important to explore novel anode materials alternative to graphite considering its poor safety and rate performance working at low temperature in lithium ion batteries. [2]通过简单的固态方法成功合成了单相二元钒酸镍 Ni2V2O7,以探索锂离子电池的新型负极材料。 [1] nan [2]
Fabricate Novel Anode 制造新型阳极
It is important to design and fabricate novel anode materials with stable structure and high capacity for sodium ion batteries (SIBs). [1] Herein, a simplified and economical method is developed to treat spent lithium-ion batteries (LIBs) by utilizing LiFePO4 cathode scraps as the raw precursors to fabricate novel anode material Fe2P2O7. [2]设计和制造具有稳定结构和高容量钠离子电池(SIB)的新型负极材料非常重要。 [1] 在此,开发了一种简化且经济的方法来处理废旧锂离子电池 (LIB),该方法利用 LiFePO4 正极废料作为原料前体制备新型负极材料 Fe2P2O7。 [2]
Developing Novel Anode 开发新型阳极
Developing novel anode materials with highly efficient and earth-abundant for electrochemical energy storage are vitally paramount, but extremely challenging for the enhancement of alkali ions storage performance. [1] Developing novel anode materials with high OER activity and stability is imperative. [2]开发用于电化学储能的高效且储量丰富的新型负极材料至关重要,但对于提高碱离子存储性能却极具挑战性。 [1] 开发具有高 OER 活性和稳定性的新型负极材料势在必行。 [2]
novel anode material 新型负极材料
High-energy ball milling (HEBM) is used to synthesize zinc telluride (ZnTe) and amorphous C (ZnTe-C) nanocomposites as novel anode materials for sodium-ion batteries (SIBs). [1] The single-phase binary nickel vanadate Ni2V2O7 was successfully synthesized by a simple solid-state method to explore novel anode materials for lithium-ion batteries. [2] Next‐generation Li‐ion batteries (LIBs) with higher energy density adopt some novel anode materials, which generally have the potential to exhibit higher capacity, superior rate performance as well as better cycling durability than conventional graphite anode, while on the other hand always suffer from larger active lithium loss (ALL) in the first several cycles. [3] Although novel anode materials made of transition metal hydroxide can initially exhibit high capacity, their cycling performances would rapidly decline due to the poor structural stability and low electrical conductivity. [4] Herein, we design a core-shell structure consisting of an active bismuth sulfide core and a highly conductive sulfur-doped carbon shell (Bi2S3@SC) as a novel anode material for PIBs. [5] Here, a novel anode material La0. [6] The main objective of the present study was to examine the effect of zinc foil modified with zinc oxide as a novel anode material to enhance power generation in a microfluidic MFC using oxalate as a substrate. [7] Hard carbon materials are employed as a novel anode material in lithium ion batteries (LIBs) due to its large specific surface area, high specific capacity and stable cycle performance. [8] As a novel anode material for sodium-ion batteries (SIBs), TiO2@HCNF retains a specific capacity of 193 mA h g-1 over 100 cycles at a current density of 0. [9] Designing a novel anode material with suitable elemental composition and bonding structure for improving the limited capacity and poor lithium-ion conductivity of lithium-ion batteries (LIBs) is still challenging. [10] Herein, a novel anode material capable of in-situ exsolution of nanoparticles, Sr1. [11] Herein, a novel anode material is constructed by wrapping SiOx into PVA derived carbon layer and N-doped carbon (NC) nanosheets derived from exfoliated chitin nanosheets. [12] In the present work, the sulfur and nitrogen dual-doped carbon nanofiber (S-NCNF) membrane was synthesized as a novel anode material of SICs. [13] It is important to design and fabricate novel anode materials with stable structure and high capacity for sodium ion batteries (SIBs). [14] Developing novel anode materials with highly efficient and earth-abundant for electrochemical energy storage are vitally paramount, but extremely challenging for the enhancement of alkali ions storage performance. [15] This work paves the ideas for the design of novel anode materials with high specific capacity, good cycling stability and outstanding rate capability for PIBs. [16] Helical carbon nanofibers (HCNFs) modified with Fe2O3 (Fe2O3/HCNFs) with a particle size of about 10-20 nm were first introduced for potential use as a novel anode material for lithium-ion batteries (LIBs). [17] Herein, a simplified and economical method is developed to treat spent lithium-ion batteries (LIBs) by utilizing LiFePO4 cathode scraps as the raw precursors to fabricate novel anode material Fe2P2O7. [18] Herein, dual-carbon-confined hydrangea-like SiO clusters are developed via chemical vapor deposition (CVD) growth, followed by a spray drying approach as a novel anode material for high-performance and stable lithium ion batteries. [19] It is urgent to develop novel anode materials with high energy density and facile synthetic procedures, since the development of commercial lithium ions batteries (LIBs) is limited by the unsatisfied capacity of graphite. [20] The work provides new thinking for the application of the novel anode material of LICs. [21] The present study aims to introduce Niobium pentoxide-Titanium nanotube (Nb2O5-TNTs) composite as a novel anode material synthesized through hydrothermal method. [22] Fe-Mn oxides/C composites with foamed porous structure have been synthesized successfully by a green and efficient method and employed as novel anode materials for lithium-ion batteries. [23] Addressing at this issue, we herein report a nanophase MnV2O4 material as a novel anode material for lithium-ion batteries. [24] Thus, there is an urgent need to develop novel anode materials that are suitable for K ions. [25] We report CoFe2O4 and carbon nanotubes hybrid aerogels as a novel anode material for potassium ion batteries (KIBs). [26] The flexible amorphous coatings, well dispersed and ultrafine active particles, as well as highly conductive networks in the constructed architecture endows this novel anode materials a good long-cycle stability and rate performance, so that a high specific capacity of 400 mAh g-1 can be retained at 2 C (1. [27] This study suggests a practical strategy to prepare novel anode material with abundant natural resource and facile synthetic route, and the optimized hybrid anode with outstanding Li+ storage properties provides hopeful application prospect in advanced LIBs and other energy storage devices. [28] Developing novel anode materials with high OER activity and stability is imperative. [29] We report a simple approach for synthesizing Cu/SbxOy/Sb nanocomposite materials possessing yolk-shell structures for use as novel anode materials for Li-ion batteries. [30] Lead-based perovskites (PbTiO3 and PbZrO3) are introduced as novel anode materials for non-aqueous M-ion rechargeable batteries (M = Li, Na, K). [31] This study reports one dimensional lithium hexaoxotungstate (Li6WO6), with a diameter in the range of 200–500 nm, as a novel anode material for lithium-ion batteries. [32] The results indicate that NbSe2 may be a promising anode for sodium-ion and potassium-ion batteries as a novel anode material. [33] To increase energy density in lithium-ion batteries (LIBs), novel anode materials are considered based on conversion and alloying mechanisms as these typically possess far higher storage capacity than graphite, however, cyclability of these compounds is typically poor. [34] In this paper, we reported a novel anode material, CeVO3, which can be used for both LIBs and sodium ions batteries (SIBs). [35] The present work may provide an insight into the design of novel anode materials for high-performance ASCs. [36] These results demonstrate that the Ni–BCYN+GDC composite anode is a potential novel anode material candidate for hydrocarbon-fueled SOFC. [37] In this study, a novel anode material of SnS hollow nanofibers (SnS HNFs) was rationally synthesized by a facile process and demonstrated to be a promising anode candidate for sodium-ion batteries. [38] This paper introduces the novel anode material which is Li4Ti5O12/Si prepared by gas-stated method, mainly spray-pyrolysis technique. [39] Orthoboric acid nanowires with high first discharge capacity are believed to have great prospects for the development of novel anode materials for lithium ion batteries. [40] Such high-performance novel anode material together with the new findings in electrochemical mechanism in this work may open a way for the design of future energy storage devices. [41] A novel anode material based on Li4Ti5O12 prepared using the combination of poly-3,4-ethylenedioxythiophene/polystyrene sulfonate and carboxymethylcellulose for the conducting polymer binder was developed. [42] Two-dimensional (2D) carbon-coated sandwich-like mesoporous SnO2/graphene/mesoporous SnO2 nanosheets (C@SnO2-rGO-SnO2) is conceived and synthesized as a novel anode material towards advanced lithium-ion battery. [43] Herein, for the first time, we report an anatase TiO2-derived Magnéli phase Ti6O11 as a novel anode material for KIBs. [44] The results found in the present study will help in the design optimization of novel anode materials to deliver improved PD from MFCs. [45] This rational design on heterojunction structure sheds light on further constructing novel anode material for secondary ion batteries. [46] This study shows that ZnO/ZnFe2O4 has the potential as a novel anode material for lithium ion batteries. [47] It is very important to explore novel anode materials alternative to graphite considering its poor safety and rate performance working at low temperature in lithium ion batteries. [48] Finding novel anode materials in place of the current commonly used but performance-limited graphite is the top priority for the remarkable development of lithium-ion batteries (LIBs). [49] A novel anode material with a delicate composite structure, which is assembled by growing 3D MoSe2 nanoflowers onto the hierarchically anisotropic carbon architecture, is designed for the first time. [50]高能球磨 (HEBM) 用于合成碲化锌 (ZnTe) 和无定形碳 (ZnTe-C) 纳米复合材料作为钠离子电池 (SIB) 的新型负极材料。 [1] 通过简单的固态方法成功合成了单相二元钒酸镍 Ni2V2O7,以探索锂离子电池的新型负极材料。 [2] 具有更高能量密度的下一代锂离子电池(LIBs)采用了一些新型负极材料,这些负极材料通常具有比传统石墨负极更高的容量、优异的倍率性能和更好的循环耐久性,而另一方面总是在前几个循环中遭受较大的活性锂损失(ALL)。 [3] nan [4] 在此,我们设计了一种由活性硫化铋核和高导电硫掺杂碳壳 (Bi2S3@SC) 组成的核壳结构,作为 PIB 的新型负极材料。 [5] 这里,一种新型负极材料 La0. [6] 本研究的主要目的是研究用氧化锌改性的锌箔作为一种新型阳极材料在以草酸盐为基材的微流控 MFC 中增强发电的效果。 [7] 硬碳材料具有比表面积大、比容量高、循环性能稳定等优点,被用作锂离子电池(LIBs)的新型负极材料。 [8] 作为钠离子电池 (SIB) 的新型负极材料,TiO2@HCNF 在电流密度为 0 的情况下,经过 100 次循环后仍保持 193 mAh g-1 的比容量。 [9] 设计一种具有合适元素组成和键合结构的新型负极材料,以改善锂离子电池 (LIB) 的有限容量和较差的锂离子电导率仍然具有挑战性。 [10] 在此,一种能够原位脱溶纳米颗粒的新型阳极材料,Sr1。 [11] 在此,一种新型阳极材料是通过将 SiOx 包裹到 PVA 衍生的碳层和从剥离的几丁质纳米片衍生的 N 掺杂碳 (NC) 纳米片中构建的。 [12] 在目前的工作中,合成了硫氮双掺杂碳纳米纤维(S-NCNF)膜作为SICs的新型负极材料。 [13] 设计和制造具有稳定结构和高容量钠离子电池(SIB)的新型负极材料非常重要。 [14] 开发用于电化学储能的高效且储量丰富的新型负极材料至关重要,但对于提高碱离子存储性能却极具挑战性。 [15] 这项工作为设计具有高比容量、良好循环稳定性和出色倍率性能的PIBs新型负极材料铺平了思路。 [16] 首次引入粒径约为 10-20 nm 的 Fe2O3 (Fe2O3/HCNFs) 修饰的螺旋状碳纳米纤维 (HCNFs) 作为锂离子电池 (LIBs) 的新型负极材料。 [17] 在此,开发了一种简化且经济的方法来处理废旧锂离子电池 (LIB),该方法利用 LiFePO4 正极废料作为原料前体制备新型负极材料 Fe2P2O7。 [18] 在此,通过化学气相沉积 (CVD) 生长开发了双碳约束绣球状 SiO 簇,然后采用喷雾干燥方法作为高性能和稳定锂离子电池的新型负极材料。 [19] 由于石墨容量不足,限制了商业锂离子电池(LIB)的发展,因此迫切需要开发具有高能量密度和简便合成工艺的新型负极材料。 [20] 该工作为新型 LICs 负极材料的应用提供了新思路。 [21] 本研究旨在介绍五氧化二铌-钛纳米管(Nb2O5-TNTs)复合材料作为一种通过水热法合成的新型负极材料。 [22] 通过绿色高效的方法成功合成了具有泡沫多孔结构的铁锰氧化物/碳复合材料,并将其用作锂离子电池的新型负极材料。 [23] 针对这个问题,我们在此报告了一种纳米相 MnV2O4 材料作为锂离子电池的新型负极材料。 [24] nan [25] 我们报告了 CoFe2O4 和碳纳米管混合气凝胶作为钾离子电池 (KIB) 的新型阳极材料。 [26] nan [27] nan [28] 开发具有高 OER 活性和稳定性的新型负极材料势在必行。 [29] 我们报告了一种合成具有蛋黄壳结构的 Cu/SbxOy/Sb 纳米复合材料的简单方法,可用作锂离子电池的新型负极材料。 [30] 铅基钙钛矿(PbTiO3 和 PbZrO3)被引入作为非水 M 离子可充电电池(M = Li、Na、K)的新型负极材料。 [31] 本研究报告了直径在 200-500 nm 范围内的一维六钨酸锂 (Li6WO6) 作为锂离子电池的新型负极材料。 [32] 结果表明,作为新型负极材料,NbSe2 可能是钠离子和钾离子电池的有前途的负极材料。 [33] nan [34] nan [35] nan [36] nan [37] nan [38] nan [39] nan [40] nan [41] nan [42] nan [43] nan [44] nan [45] nan [46] nan [47] nan [48] nan [49] nan [50]
novel anode electrode 新型阳极电极
Various works have recently been directed to growing novel anode electrodes with superior electrochemical capability. [1] This leads to synthesize a novel anode electrode material. [2] Aiming to alleviate this problem, in this work a novel anode electrode structure is proposed, in which a microporous layer containing Nafion polymer is added between the catalyst layer and the microporous layer with PTFE. [3] Finally, the F-doped Al20P21 was proposed as novel anode electrode in K-ion battery with the highest performance. [4] Finally, the TeO2-SiNT (9, 0) as novel anode electrodes in Li-ion batteries and Na-ion batteries are proposed with high performance. [5] Finally, the C84-SnO2 as novel anode electrodes in LIB and KIB with the highest Vcell was proposed to use in electrical machines. [6]最近,各种工作都针对生长具有优异电化学能力的新型阳极电极。 [1] 这导致合成了一种新型的阳极电极材料。 [2] 为了缓解这个问题,在这项工作中,提出了一种新型的阳极电极结构,其中在催化剂层和具有 PTFE 的微孔层之间添加了含有 Nafion 聚合物的微孔层。 [3] 最后,提出了将 F 掺杂的 Al20P21 作为 K 离子电池中具有最高性能的新型负极。 [4] nan [5] nan [6]
novel anode design
Furthermore, the carbon matrix structure in the electrode provides the conductive path for electrons, so no additional conductive agents are required in this novel anode design. [1] Enhancing microbial electrocatalysis through novel anode design is essential to the efficient and stable operation of microbial fuel cells. [2]此外,电极中的碳基质结构为电子提供了导电路径,因此在这种新型阳极设计中不需要额外的导电剂。 [1] 通过新型阳极设计增强微生物电催化对于微生物燃料电池的高效稳定运行至关重要。 [2]
novel anode active
58O4-δ HEO nanocrystalline powder with high concentration of oxygen vacancies is successfully prepared by the method of solution combustion synthesis (SCS), and explored as a novel anode active material for LIBs. [1] 8 is reported as a novel anode active material for lithium-ion batteries. [2]采用溶液燃烧合成(SCS)的方法成功制备了具有高浓度氧空位的58O4-δ HEO纳米晶粉末,并将其作为新型LIBs负极活性材料进行了探索。 [1] nan [2]