| 1 | Hierarchical Nanowire Host Material for High‐Areal‐Capacity All‐Solid‐State S/SeS<sub>2</sub> Batteries | 17.0 | 7 | Citations (PDF) |
| 2 | Improving Cycling Stability of Ni‐Rich Cathode for Lithium‐Metal Batteries via Interphases Tunning | 22.6 | 15 | Citations (PDF) |
| 3 | Forming Robust and Highly Li‐Ion Conductive Interfaces in High‐Performance Lithium Metal Batteries Using Chloroethylene Carbonate Additive | 5.5 | 11 | Citations (PDF) |
| 4 | Mechanism Behind the Loss of Fast Charging Capability in Nickel‐Rich Cathode Materials | 1.4 | 0 | Citations (PDF) |
| 5 | Mechanism Behind the Loss of Fast Charging Capability in Nickel‐Rich Cathode Materials | 14.4 | 36 | Citations (PDF) |
| 6 | Doping Strategy in Developing Ni-Rich Cathodes for High-Performance Lithium-Ion Batteries | 17.0 | 91 | Citations (PDF) |
| 7 | Heterostructured nickel–cobalt metal alloy and metal oxide nanoparticles as a polysulfide mediator for stable lithium–sulfur full batteries with lean electrolyte 2024, 6, | | 32 | Citations (PDF) |
| 8 | Constructing the Interconnected Charge Transfer Pathways in Sulfur Composite Cathode for All-Solid-State Lithium–Sulfur Batteries | 8.0 | 19 | Citations (PDF) |
| 9 | High Voltage Electrolyte Design Mediated by Advanced Solvation Chemistry Toward High Energy Density and Fast Charging Lithium‐Ion Batteries | 22.6 | 127 | Citations (PDF) |
| 10 | Investigation of treatment volume versus circulating blood volume during Rheocarna treatment | 1.0 | 2 | Citations (PDF) |
| 11 | Unraveling the New Role of Manganese in Nano and Microstructural Engineering of Ni‐Rich Layered Cathode for Advanced Lithium‐Ion Batteries | 22.6 | 31 | Citations (PDF) |
| 12 | Experimental and computational optimization of Prussian blue analogues as high-performance cathodes for sodium-ion batteries: A review | 14.3 | 49 | Citations (PDF) |
| 13 | Wet‐Processable Binder in Composite Cathode for High Energy Density All‐Solid‐State Lithium Batteries | 22.6 | 18 | Citations (PDF) |
| 14 | Tailoring Primary Particle Size Distribution to Suppress Microcracks in Ni-Rich Cathodes via Controlled Grain Coarsening | 17.0 | 27 | Citations (PDF) |
| 15 | Aluminum-distribution-dependent microstructural evolution of NCA cathodes: Is aluminum homogeneity really favorable? | 18.1 | 6 | Citations (PDF) |
| 16 | Pore-Free Single-Crystalline Particles for Durable Na-Ion Battery Cathodes | 8.0 | 10 | Citations (PDF) |
| 17 | Improving reaction uniformity of high‐loading lithium‐sulfur pouch batteries 2024, 6, | | 21 | Citations (PDF) |
| 18 | Toward Practical Li–S Batteries: On the Road to a New Electrolyte | 22.6 | 49 | Citations (PDF) |
| 19 | Microstructure- and Interface-Modified Ni-Rich Cathode for High-Energy-Density All-Solid-State Lithium Batteries | 17.0 | 70 | Citations (PDF) |
| 20 | Long‐lasting, reinforced electrical networking in a high‐loading Li<sub>2</sub>S cathode for high‐performance lithium–sulfur batteries 2023, 5, | | 32 | Citations (PDF) |
| 21 | Long-Lasting Ni-Rich NCMA Cathodes via Simultaneous Microstructural Refinement and Surface Modification | 17.0 | 113 | Citations (PDF) |
| 22 | Multifunctional Doping Strategy to Develop High‐Performance Ni‐Rich Cathode Material | 22.6 | 77 | Citations (PDF) |
| 23 | Optimization of Ni-rich Li[Ni0.92−xCo0.04Mn0.04Alx]O2 cathodes for high energy density lithium-ion batteries | 7.9 | 26 | Citations (PDF) |
| 24 | High-Energy-Density, Long-Life Li-Metal Batteries via Application of External Pressure | 17.0 | 38 | Citations (PDF) |
| 25 | Turning on Lithium–Sulfur Full Batteries at −10 °C | 15.3 | 19 | Citations (PDF) |
| 26 | Mechanism of Doping with High‐Valence Elements for Developing Ni‐Rich Cathode Materials | 22.6 | 150 | Citations (PDF) |
| 27 | High-voltage stability of O3-type sodium layered cathode enabled by preferred occupation of Na in the OP2 phase | 18.1 | 42 | Citations (PDF) |
| 28 | Opening a New Horizon for the Facile Synthesis of Long-Life Ni-Rich Layered Cathode | 17.0 | 41 | Citations (PDF) |
| 29 | Tailoring the Interface between Sulfur and Sulfide Solid Electrolyte for High-Areal-Capacity All-Solid-State Lithium–Sulfur Batteries | 17.0 | 60 | Citations (PDF) |
| 30 | Practical Cathodes for Sodium‐Ion Batteries: Who Will Take The Crown? | 22.6 | 254 | Citations (PDF) |
| 31 | Ni-rich layered cathodes for lithium-ion batteries: From challenges to the future | 18.1 | 142 | Citations (PDF) |
| 32 | Near-surface reconstruction in Ni-rich layered cathodes for high-performance lithium-ion batteries | 50.9 | 188 | Citations (PDF) |
| 33 | Intergranular Shielding for Ultrafine‐Grained Mo‐Doped Ni‐Rich Li[Ni<sub>0.96</sub>Co<sub>0.04</sub>]O<sub>2</sub> Cathode for Li‐Ion Batteries with High Energy Density and Long Life | 14.4 | 41 | Citations (PDF) |
| 34 | Intergranular Shielding for Ultrafine‐Grained Mo‐Doped Ni‐Rich Li[Ni<sub>0.96</sub>Co<sub>0.04</sub>]O<sub>2</sub> Cathode for Li‐Ion Batteries with High Energy Density and Long Life | 1.4 | 4 | Citations (PDF) |
| 35 | Uniformly distributed reaction by 3D host-lithium composite anode for high rate capability and reversibility of Li-O2 batteries | 12.0 | 16 | Citations (PDF) |
| 36 | Microstructure-optimized concentration-gradient NCM cathode for long-life Li-ion batteries | 14.0 | 112 | Citations (PDF) |
| 37 | All-Solid-State Lithium Batteries: Li<sup>+</sup>-Conducting Ionomer Binder for Dry-Processed Composite Cathodes | 17.0 | 143 | Citations (PDF) |
| 38 | Intrinsic weaknesses of Co-free Ni–Mn layered cathodes for electric vehicles | 14.0 | 50 | Citations (PDF) |
| 39 | Hierarchical O3/P2 heterostructured cathode materials for advanced sodium-ion batteries | 18.1 | 176 | Citations (PDF) |
| 40 | Stable Solid Electrolyte Interphase for Long-Life Potassium Metal Batteries | 17.0 | 51 | Citations (PDF) |
| 41 | Geometrical engineering of a SPAN–graphene composite cathode for practical Li–S batteries | 9.3 | 35 | Citations (PDF) |
| 42 | Evolution of a Radially Aligned Microstructure in Boron-Doped Li[Ni<sub>0.95</sub>Co<sub>0.04</sub>Al<sub>0.01</sub>]O<sub>2</sub> Cathode Particles | 8.0 | 40 | Citations (PDF) |
| 43 | High‐Energy Ni‐Rich Cathode Materials for Long‐Range and Long‐Life Electric Vehicles | 22.6 | 102 | Citations (PDF) |
| 44 | Degradation Mechanism of Ni-Rich Cathode Materials: Focusing on Particle Interior | 17.0 | 247 | Citations (PDF) |
| 45 | All-solid-state lithium batteries featuring hybrid electrolytes based on Li+ ion-conductive Li7La3Zr2O12 framework and full-concentration gradient Ni-rich NCM cathode | 12.0 | 27 | Citations (PDF) |
| 46 | Structural Stability of Single-Crystalline Ni-Rich Layered Cathode upon Delithiation | 17.0 | 74 | Citations (PDF) |
| 47 | Morphology-Dependent Battery Performance of Ni-Rich Layered Cathodes: Single-Crystal versus Refined Polycrystal | 17.0 | 90 | Citations (PDF) |
| 48 | A Novel Pentanary Metal Oxide Cathode with P2/O3 Biphasic Structure for High‐Performance Sodium‐Ion Batteries | 17.0 | 160 | Citations (PDF) |
| 49 | Introducing high-valence elements into cobalt-free layered cathodes for practical lithium-ion batteries | 50.9 | 341 | Citations (PDF) |
| 50 | Dipole–Dipole Interaction Induced Electrolyte Interfacial Model To Stabilize Antimony Anode for High-Safety Lithium-Ion Batteries | 17.0 | 174 | Citations (PDF) |
| 51 | Resolving the Incomplete Charging Behavior of Redox-Mediated Li-O<sub>2</sub> Batteries via Sustainable Protection of Li Metal Anode | 8.0 | 8 | Citations (PDF) |
| 52 | Discerning Roles of Interfacial Model and Solid Electrolyte Interphase Layer for Stabilizing Antimony Anode in Lithium-Ion Batteries 2022, 4, 2233-2243 | | 66 | Citations (PDF) |
| 53 | High-Energy-Density Li-Ion Battery Reaching Full Charge in 12 min | 17.0 | 73 | Citations (PDF) |
| 54 | Nanostructured Co‐Free Layered Oxide Cathode that Affords Fast‐Charging Lithium‐Ion Batteries for Electric Vehicles | 22.6 | 58 | Citations (PDF) |
| 55 | Enhanced cycling stability of Sn-doped Li[Ni0.90Co0.05Mn0.05]O2 via optimization of particle shape and orientation | 12.0 | 71 | Citations (PDF) |
| 56 | Diverting Exploration of Silicon Anode into Practical Way: A Review Focused on Silicon-Graphite Composite for Lithium Ion Batteries | 18.1 | 471 | Citations (PDF) |
| 57 | Unraveling the New Role of an Ethylene Carbonate Solvation Shell in Rechargeable Metal Ion Batteries | 17.0 | 185 | Citations (PDF) |
| 58 | Lithium‐Substituted Tunnel/Spinel Heterostructured Cathode Material for High‐Performance Sodium‐Ion Batteries | 17.0 | 43 | Citations (PDF) |
| 59 | Microstrain Alleviation in High-Energy Ni-Rich NCMA Cathode for Long Battery Life | 17.0 | 118 | Citations (PDF) |
| 60 | WO3 Nanowire/Carbon Nanotube Interlayer as a Chemical Adsorption Mediator for High-Performance Lithium-Sulfur Batteries | 4.3 | 19 | Citations (PDF) |
| 61 | Cation ordered Ni-rich layered cathode for ultra-long battery life | 30.9 | 163 | Citations (PDF) |
| 62 | Electrolyte‐Mediated Stabilization of High‐Capacity Micro‐Sized Antimony Anodes for Potassium‐Ion Batteries | 24.5 | 140 | Citations (PDF) |
| 63 | Optimized Ni‐Rich NCMA Cathode for Electric Vehicle Batteries | 22.6 | 124 | Citations (PDF) |
| 64 | Enhanced Cycling Stability of O3-Type Na[Ni<sub>0.5</sub>Mn<sub>0.5</sub>]O<sub>2</sub> Cathode through Sn Addition for Sodium-Ion Batteries | 3.1 | 26 | Citations (PDF) |
| 65 | Critical Role of Functional Groups Containing N, S, and O on Graphene Surface for Stable and Fast Charging Li‐S Batteries | 11.6 | 39 | Citations (PDF) |
| 66 | Long-Lasting Solid Electrolyte Interphase for Stable Li-Metal Batteries | 17.0 | 52 | Citations (PDF) |
| 67 | Microstructure Engineered Ni‐Rich Layered Cathode for Electric Vehicle Batteries | 22.6 | 156 | Citations (PDF) |
| 68 | Electrolyte Chemistry in 3D Metal Oxide Nanorod Arrays Deciphers Lithium Dendrite-Free Plating/Stripping Behaviors for High-Performance Lithium Batteries | 4.2 | 29 | Citations (PDF) |
| 69 | Closely Coupled Binary Metal Sulfide Nanosheets Shielded Molybdenum Sulfide Nanorod Hierarchical Structure via Eco-Benign Surface Exfoliation Strategy towards Efficient Lithium and Sodium-ion Batteries | 18.1 | 38 | Citations (PDF) |
| 70 | Capacity Fading Mechanisms in Ni-Rich Single-Crystal NCM Cathodes | 17.0 | 522 | Citations (PDF) |
| 71 | Achieving High-Performance Li–S Batteries via Polysulfide Adjoining Interface Engineering | 8.0 | 31 | Citations (PDF) |
| 72 | Multiscale Understanding of Covalently Fixed Sulfur–Polyacrylonitrile Composite as Advanced Cathode for Metal–Sulfur Batteries | 12.7 | 49 | Citations (PDF) |
| 73 | Gifts from Nature: Bio‐Inspired Materials for Rechargeable Secondary Batteries | 24.5 | 80 | Citations (PDF) |
| 74 | Interfacial Model Deciphering High‐Voltage Electrolytes for High Energy Density, High Safety, and Fast‐Charging Lithium‐Ion Batteries | 24.5 | 229 | Citations (PDF) |
| 75 | Cationic and transition metal co-substitution strategy of O3-type NaCrO2 cathode for high-energy sodium-ion batteries | 18.1 | 76 | Citations (PDF) |
| 76 | Ultra-stable cycling of multi-doped (Zr,B) Li[Ni0.885Co0.100Al0.015]O2 cathode | 7.9 | 33 | Citations (PDF) |
| 77 | State-of-the-art anodes of potassium-ion batteries: synthesis, chemistry, and applications | 7.1 | 39 | Citations (PDF) |
| 78 | High-performance Ni-rich Li[Ni<sub>0.9–<i>x</i></sub>Co<sub>0.1</sub>Al<sub><i>x</i></sub>]O<sub>2</sub> cathodes <i>via</i> multi-stage microstructural tailoring from hydroxide precursor to the lithiated oxide | 30.9 | 99 | Citations (PDF) |
| 79 | In Situ Oriented Mn Deficient ZnMn<sub>2</sub>O<sub>4</sub>@C Nanoarchitecture for Durable Rechargeable Aqueous Zinc‐Ion Batteries | 12.7 | 149 | Citations (PDF) |
| 80 | Quasi-compensatory effect in emerging anode-free lithium batteries | 32.1 | 84 | Citations (PDF) |
| 81 | High-Energy Cathodes via Precision Microstructure Tailoring for Next-Generation Electric Vehicles | 17.0 | 104 | Citations (PDF) |
| 82 | Transition metal-doped Ni-rich layered cathode materials for durable Li-ion batteries | 13.9 | 386 | Citations (PDF) |
| 83 | Ultrafine-grained Ni-rich layered cathode for advanced Li-ion batteries | 30.9 | 184 | Citations (PDF) |
| 84 | Facile migration of potassium ions in a ternary P3-type K0.5[Mn0.8Fe0.1Ni0.1]O2 cathode in rechargeable potassium batteries | 18.1 | 86 | Citations (PDF) |
| 85 | Controllable and stable organometallic redox mediators for lithium oxygen batteries | 10.3 | 23 | Citations (PDF) |
| 86 | Na<sub>2.3</sub>Cu<sub>1.1</sub>Mn<sub>2</sub>O<sub>7−δ</sub> nanoflakes as enhanced cathode materials for high-energy sodium-ion batteries achieved by a rapid pyrosynthesis approach | 9.3 | 24 | Citations (PDF) |
| 87 | The dominant role of Mn2+ additive on the electrochemical reaction in ZnMn2O4 cathode for aqueous zinc-ion batteries | 18.1 | 287 | Citations (PDF) |
| 88 | Cobalt‐Free High‐Capacity Ni‐Rich Layered Li[Ni<sub>0.9</sub>Mn<sub>0.1</sub>]O<sub>2</sub> Cathode | 22.6 | 244 | Citations (PDF) |
| 89 | Ni‐Rich Layered Cathode Materials with Electrochemo‐Mechanically Compliant Microstructures for All‐Solid‐State Li Batteries | 22.6 | 221 | Citations (PDF) |
| 90 | Nano/Microstructured Silicon–Carbon Hybrid Composite Particles Fabricated with Corn Starch Biowaste as Anode Materials for Li-Ion Batteries | 8.7 | 247 | Citations (PDF) |
| 91 | High-Energy W-Doped Li[Ni0.95Co0.04Al0.01]O2 Cathodes for Next-Generation Electric Vehicles | 18.1 | 154 | Citations (PDF) |
| 92 | Recent Progress and Perspective of Advanced High‐Energy Co‐Less Ni‐Rich Cathodes for Li‐Ion Batteries: Yesterday, Today, and Tomorrow | 22.6 | 353 | Citations (PDF) |
| 93 | Role of Li‐Ion Depletion on Electrode Surface: Underlying Mechanism for Electrodeposition Behavior of Lithium Metal Anode | 22.6 | 165 | Citations (PDF) |
| 94 | Investigation of superior sodium storage and reversible Na<sub>2</sub>S conversion reactions in a porous NiS<sub>2</sub>@C composite using <i>in operando</i> X-ray diffraction | 9.3 | 26 | Citations (PDF) |
| 95 | Model-Based Design of Graphite-Compatible Electrolytes in Potassium-Ion Batteries | 17.0 | 124 | Citations (PDF) |
| 96 | Understanding the Capacity Fading Mechanisms of O3‐Type Na[Ni<sub>0.5</sub>Mn<sub>0.5</sub>]O<sub>2</sub> Cathode for Sodium‐Ion Batteries | 22.6 | 131 | Citations (PDF) |
| 97 | Model-Based Design of Stable Electrolytes for Potassium Ion Batteries | 17.0 | 107 | Citations (PDF) |
| 98 | Heuristic solution for achieving long-term cycle stability for Ni-rich layered cathodes at full depth of discharge | 50.9 | 480 | Citations (PDF) |
| 99 | Tungsten Oxide/Zirconia as a Functional Polysulfide Mediator for High-Performance Lithium–Sulfur Batteries | 17.0 | 60 | Citations (PDF) |
| 100 | Additives Engineered Nonflammable Electrolyte for Safer Potassium Ion Batteries | 17.0 | 130 | Citations (PDF) |
| 101 | Co-Free Layered Cathode Materials for High Energy Density Lithium-Ion Batteries | 17.0 | 164 | Citations (PDF) |
| 102 | Oxidation Stability of Organic Redox Mediators as Mobile Catalysts in Lithium–Oxygen Batteries | 17.0 | 39 | Citations (PDF) |
| 103 | New Class of Ni‐Rich Cathode Materials Li[Ni<i><sub>x</sub></i>Co<i><sub>y</sub></i>B<sub>1−</sub><i><sub>x</sub></i><sub>−</sub><i><sub>y</sub></i>]O<sub>2</sub> for Next Lithium Batteries | 22.6 | 167 | Citations (PDF) |
| 104 | Multidimensional Na<sub>4</sub>VMn<sub>0.9</sub>Cu<sub>0.1</sub>(PO<sub>4</sub>)<sub>3</sub>/C cotton-candy cathode materials for high energy Na-ion batteries | 9.3 | 86 | Citations (PDF) |
| 105 | Multi-Doped (Ga,B) Li[Ni<sub>0.885</sub>Co<sub>0.100</sub>Al<sub>0.015</sub>]O<sub>2</sub>Cathode | 3.1 | 16 | Citations (PDF) |
| 106 | High-energy O3-Na<sub>1−2x</sub>Ca<sub>x</sub>[Ni<sub>0.5</sub>Mn<sub>0.5</sub>]O<sub>2</sub> cathodes for long-life sodium-ion batteries | 9.3 | 107 | Citations (PDF) |
| 107 | Perpendicularly aligned TiC-coated carbon cloth cathode for high-performance Li-O2 batteries | 12.0 | 19 | Citations (PDF) |
| 108 | Manganese and Vanadium Oxide Cathodes for Aqueous Rechargeable Zinc-Ion Batteries: A Focused View on Performance, Mechanism, and Developments | 17.0 | 450 | Citations (PDF) |
| 109 | Density Functional Theory Investigation of Mixed Transition Metals in Olivine and Tavorite Cathode Materials for Li-Ion Batteries | 8.0 | 39 | Citations (PDF) |
| 110 | Lithium–Oxygen Batteries and Related Systems: Potential, Status, and Future | 52.7 | 886 | Citations (PDF) |
| 111 | Investigation of K-ion storage performances in a bismuth sulfide-carbon nanotube composite anode | 4.4 | 7 | Citations (PDF) |
| 112 | A highly stabilized Ni-rich NCA cathode for high-energy lithium-ion batteries | 14.0 | 236 | Citations (PDF) |
| 113 | Limited effects of a redox mediator in lithium–oxygen batteries: indecomposable by-products | 9.3 | 18 | Citations (PDF) |
| 114 | Electrolyte Engineering Enables High Stability and Capacity Alloying Anodes for Sodium and Potassium Ion Batteries | 17.0 | 197 | Citations (PDF) |
| 115 | An Empirical Model for the Design of Batteries with High Energy Density | 17.0 | 176 | Citations (PDF) |
| 116 | Development of Novel Cathode with Large Lithium Storage Mechanism Based on Pyrophosphate‐Based Conversion Reaction for Rechargeable Lithium Batteries | 9.0 | 7 | Citations (PDF) |
| 117 | Toward the Sustainable Lithium Metal Batteries with a New Electrolyte Solvation Chemistry | 22.6 | 154 | Citations (PDF) |
| 118 | Quasi-solid-state zinc-ion battery based on α-MnO2 cathode with husk-like morphology | 5.3 | 35 | Citations (PDF) |
| 119 | Engineering Sodium-Ion Solvation Structure to Stabilize Sodium Anodes: Universal Strategy for Fast-Charging and Safer Sodium-Ion Batteries | 8.7 | 149 | Citations (PDF) |
| 120 | A New Type of Ni-Rich Cathode for High-Energy Lithium-Ion Batteries | 0.0 | 0 | Citations (PDF) |
| 121 | Microstructure-Tailored Ni-Rich NCA Cathode for Next Electric Vehicles | 0.0 | 0 | Citations (PDF) |
| 122 | A 4 V Class Potassium Metal Battery with Extremely Low Overpotential | 15.3 | 102 | Citations (PDF) |
| 123 | Mutual Conservation of Redox Mediator and Singlet Oxygen Quencher in Lithium–Oxygen Batteries | 12.4 | 44 | Citations (PDF) |
| 124 | Degradation Mechanism of Highly Ni-Rich Li[Ni<sub><i>x</i></sub>Co<sub><i>y</i></sub>Mn<sub>1–<i>x</i>–<i>y</i></sub>]O<sub>2</sub> Cathodes with <i>x</i> > 0.9 | 8.0 | 218 | Citations (PDF) |
| 125 | Highly wrinkled carbon tubes as an advanced anode for K-ion full batteries | 9.3 | 33 | Citations (PDF) |
| 126 | Suppressing detrimental phase transitions <i>via</i> tungsten doping of LiNiO<sub>2</sub> cathode for next-generation lithium-ion batteries | 9.3 | 247 | Citations (PDF) |
| 127 | A single layer of Fe<sub>3</sub>O<sub>4</sub>@TiO<sub>2</sub> submicron spheres as a high-performance electrode for lithium-ion microbatteries | 3.9 | 11 | Citations (PDF) |
| 128 | Li[Ni<sub>0.9</sub>Co<sub>0.09</sub>W<sub>0.01</sub>]O<sub>2</sub>: A New Type of Layered Oxide Cathode with High Cycling Stability | 22.6 | 156 | Citations (PDF) |
| 129 | Tungsten doping for stabilization of Li[Ni0.90Co0.05Mn0.05]O2 cathode for Li-ion battery at high voltage | 7.9 | 180 | Citations (PDF) |
| 130 | New Insight on the Role of Electrolyte Additives in Rechargeable Lithium Ion Batteries | 17.0 | 265 | Citations (PDF) |
| 131 | Nano-compacted Li<sub>2</sub>S/Graphene Composite Cathode for High-Energy Lithium–Sulfur Batteries | 17.0 | 45 | Citations (PDF) |
| 132 | Layered K<sub>0.28</sub>MnO<sub>2</sub>·0.15H<sub>2</sub>O as a Cathode Material for Potassium-Ion Intercalation | 8.0 | 32 | Citations (PDF) |
| 133 | Capacity Fading of Ni-Rich NCA Cathodes: Effect of Microcracking Extent | 17.0 | 455 | Citations (PDF) |
| 134 | A new P2-type layered oxide cathode with superior full-cell performances for K-ion batteries | 9.3 | 84 | Citations (PDF) |
| 135 | A method of increasing the energy density of layered Ni-rich Li[Ni<sub>1−2x</sub>Co<sub>x</sub>Mn<sub>x</sub>]O<sub>2</sub> cathodes (<i>x</i> = 0.05, 0.1, 0.2) | 9.3 | 168 | Citations (PDF) |
| 136 | A dendrite- and oxygen-proof protective layer for lithium metal in lithium–oxygen batteries | 9.3 | 75 | Citations (PDF) |
| 137 | Understanding on the structural and electrochemical performance of orthorhombic sodium manganese oxides | 9.3 | 52 | Citations (PDF) |
| 138 | Quaternary Layered Ni-Rich NCMA Cathode for Lithium-Ion Batteries | 17.0 | 306 | Citations (PDF) |
| 139 | Potassium vanadate as a new cathode material for potassium-ion batteries | 7.9 | 60 | Citations (PDF) |
| 140 | Adiponitrile (C<sub>6</sub>H<sub>8</sub>N<sub>2</sub>): A New Bi‐Functional Additive for High‐Performance Li‐Metal Batteries | 17.0 | 176 | Citations (PDF) |
| 141 | Degradation Mechanism of Ni-Enriched NCA Cathode for Lithium Batteries: Are Microcracks Really Critical? | 17.0 | 377 | Citations (PDF) |
| 142 | Customizing a Li–metal battery that survives practical operating conditions for electric vehicle applications | 30.9 | 165 | Citations (PDF) |
| 143 | Molecular-Scale Interfacial Model for Predicting Electrode Performance in Rechargeable Batteries | 17.0 | 181 | Citations (PDF) |
| 144 | Trimethylsilyl azide (C<sub>3</sub>H<sub>9</sub>N<sub>3</sub>Si): a highly efficient additive for tailoring fluoroethylene carbonate (FEC) based electrolytes for Li-metal batteries | 9.3 | 44 | Citations (PDF) |
| 145 | K0.54[Co0.5Mn0.5]O2: New cathode with high power capability for potassium-ion batteries | 16.3 | 160 | Citations (PDF) |
| 146 | Deactivation of redox mediators in lithium-oxygen batteries by singlet oxygen | 13.9 | 95 | Citations (PDF) |
| 147 | High-performance Ti-doped O3-type Na[Tix(Ni0.6Co0.2Mn0.2)1-x]O2 cathodes for practical sodium-ion batteries | 7.9 | 81 | Citations (PDF) |
| 148 | A New P2‐Type Layered Oxide Cathode with Extremely High Energy Density for Sodium‐Ion Batteries | 22.6 | 213 | Citations (PDF) |
| 149 | Triple Hierarchical Porous Carbon Spheres as Effective Cathodes for Li–O<sub>2</sub> Batteries | 3.1 | 9 | Citations (PDF) |
| 150 | Verification for trihalide ions as redox mediators in Li-O2 batteries | 18.1 | 30 | Citations (PDF) |
| 151 | Microstructure‐Controlled Ni‐Rich Cathode Material by Microscale Compositional Partition for Next‐Generation Electric Vehicles | 22.6 | 236 | Citations (PDF) |
| 152 | Compositionally and structurally redesigned high-energy Ni-rich layered cathode for next-generation lithium batteries | 14.0 | 159 | Citations (PDF) |
| 153 | A zero fading sodium ion battery: High compatibility microspherical patronite in ether-based electrolyte | 18.1 | 33 | Citations (PDF) |
| 154 | New Insights Related to Rechargeable Lithium Batteries: Li Metal Anodes, Ni Rich LiNi<sub>x</sub>Co<sub>y</sub>Mn<sub>z</sub>O<sub>2</sub> Cathodes and Beyond Them | 3.1 | 42 | Citations (PDF) |
| 155 | Carbon-Free TiO<sub>2</sub> Microspheres as Anode Materials for Sodium Ion Batteries | 17.0 | 86 | Citations (PDF) |
| 156 | Shedding Light on the Oxygen Reduction Reaction Mechanism in Ether-Based Electrolyte Solutions: A Study Using Operando UV–Vis Spectroscopy | 8.0 | 11 | Citations (PDF) |
| 157 | Quaternary Transition Metal Oxide Layered Framework: O3-Type Na[Ni<sub>0.32</sub>Fe<sub>0.13</sub>Co<sub>0.15</sub>Mn<sub>0.40</sub>]O<sub>2</sub> Cathode Material for High-Performance Sodium-Ion Batteries | 3.1 | 55 | Citations (PDF) |
| 158 | Structural transformation and electrochemical study of layered MnO2 in rechargeable aqueous zinc-ion battery | 5.3 | 287 | Citations (PDF) |
| 159 | Sodium‐Ion Batteries: Building Effective Layered Cathode Materials with Long‐Term Cycling by Modifying the Surface via Sodium Phosphate | 17.0 | 212 | Citations (PDF) |
| 160 | Aqueous rechargeable Zn-ion batteries: an imperishable and high-energy Zn<sub>2</sub>V<sub>2</sub>O<sub>7</sub> nanowire cathode through intercalation regulation | 9.3 | 359 | Citations (PDF) |
| 161 | Cation Ordering of Zr-Doped LiNiO<sub>2</sub> Cathode for Lithium-Ion Batteries | 6.7 | 218 | Citations (PDF) |
| 162 | Toward High-Safety Potassium–Sulfur Batteries Using a Potassium Polysulfide Catholyte and Metal-Free Anode | 17.0 | 118 | Citations (PDF) |
| 163 | Extracting maximum capacity from Ni-rich Li[Ni<sub>0.95</sub>Co<sub>0.025</sub>Mn<sub>0.025</sub>]O<sub>2</sub>cathodes for high-energy-density lithium-ion batteries | 9.3 | 250 | Citations (PDF) |
| 164 | Bioinspired Surface Layer for the Cathode Material of High‐Energy‐Density Sodium‐Ion Batteries | 22.6 | 129 | Citations (PDF) |
| 165 | Capacity Fading of Ni-Rich Li[Ni<sub><i>x</i></sub>Co<sub><i>y</i></sub>Mn<sub>1–<i>x</i>–<i>y</i></sub>]O<sub>2</sub> (0.6 ≤ <i>x</i> ≤ 0.95) Cathodes for High-Energy-Density Lithium-Ion Batteries: Bulk or Surface Degradation? | 6.7 | 1,508 | Citations (PDF) |
| 166 | Achieving high mass loading of Na3V2(PO4)3@carbon on carbon cloth by constructing three-dimensional network between carbon fibers for ultralong cycle-life and ultrahigh rate sodium-ion batteries | 16.3 | 163 | Citations (PDF) |
| 167 | Optimized Concentration of Redox Mediator and Surface Protection of Li Metal for Maintenance of High Energy Efficiency in Li–O<sub>2</sub> Batteries | 22.6 | 98 | Citations (PDF) |
| 168 | Clarification of Solvent Effects on Discharge Products in Li–O<sub>2</sub> Batteries through a Titration Method | 8.0 | 32 | Citations (PDF) |
| 169 | Multiwalled Carbon Nanotubes Anode in Lithium-Ion Battery with LiCoO<sub>2</sub>, Li[Ni<sub>1/3</sub>Co<sub>1/3</sub>Mn<sub>1/3</sub>]O<sub>2</sub>, and LiFe<sub>1/4</sub>Mn<sub>1/2</sub>Co<sub>1/4</sub>PO<sub>4</sub> Cathodes | 6.9 | 57 | Citations (PDF) |
| 170 | Revealing the Reaction Mechanism of Na–O<sub>2</sub> Batteries using Environmental Transmission Electron Microscopy | 17.0 | 38 | Citations (PDF) |
| 171 | Ni3V2O8 nanoparticles as an excellent anode material for high-energy lithium-ion batteries | 3.9 | 42 | Citations (PDF) |
| 172 | New Insights on Graphite Anode Stability in Rechargeable Batteries: Li Ion Coordination Structures Prevail over Solid Electrolyte Interphases | 17.0 | 334 | Citations (PDF) |
| 173 | Stabilization of Lithium-Metal Batteries Based on the in Situ Formation of a Stable Solid Electrolyte Interphase Layer | 8.0 | 106 | Citations (PDF) |
| 174 | Pyrosynthesis of Na<sub>3</sub>V<sub>2</sub>(PO<sub>4</sub>)<sub>3</sub>@C Cathodes for Safe and Low‐Cost Aqueous Hybrid Batteries | 6.2 | 57 | Citations (PDF) |
| 175 | High‐Capacity Concentration Gradient Li[Ni<sub>0.865</sub>Co<sub>0.120</sub>Al<sub>0.015</sub>]O<sub>2</sub> Cathode for Lithium‐Ion Batteries | 22.6 | 186 | Citations (PDF) |
| 176 | Na<sub>2</sub>V<sub>6</sub>O<sub>16</sub>·3H<sub>2</sub>O Barnesite Nanorod: An Open Door to Display a Stable and High Energy for Aqueous Rechargeable Zn-Ion Batteries as Cathodes | 8.7 | 553 | Citations (PDF) |
| 177 | Low‐Polarization Lithium–Oxygen Battery Using [DEME][TFSI] Ionic Liquid Electrolyte | 6.2 | 43 | Citations (PDF) |
| 178 | Designing a High‐Performance Lithium–Sulfur Batteries Based on Layered Double Hydroxides–Carbon Nanotubes Composite Cathode and a Dual‐Functional Graphene–Polypropylene–Al<sub>2</sub>O<sub>3</sub> Separator | 17.0 | 161 | Citations (PDF) |
| 179 | Controlling the Wettability between Freestanding Electrode and Electrolyte for High Energy Density Lithium-Sulfur Batteries | 3.1 | 43 | Citations (PDF) |
| 180 | Recent Progress in Rechargeable Potassium Batteries | 17.0 | 618 | Citations (PDF) |
| 181 | Dandelion-shaped manganese sulfide in ether-based electrolyte for enhanced performance sodium-ion batteries | 5.6 | 55 | Citations (PDF) |
| 182 | Variation of Electronic Conductivity within Secondary Particles Revealing a Capacity-Fading Mechanism of Layered Ni-Rich Cathode | 17.0 | 107 | Citations (PDF) |
| 183 | Present and Future Perspective on Electrode Materials for Rechargeable Zinc-Ion Batteries | 17.0 | 838 | Citations (PDF) |
| 184 | Microstructural Degradation of Ni‐Rich Li[Ni<i><sub>x</sub></i>Co<i><sub>y</sub></i>Mn<sub>1</sub><i><sub>−x−y</sub></i>]O<sub>2</sub> Cathodes During Accelerated Calendar Aging | 11.6 | 107 | Citations (PDF) |
| 185 | High-Performance Cells Containing Lithium Metal Anodes, LiNi<sub>0.6</sub>Co<sub>0.2</sub>Mn<sub>0.2</sub>O<sub>2</sub> (NCM 622) Cathodes, and Fluoroethylene Carbonate-Based Electrolyte Solution with Practical Loading | 8.0 | 89 | Citations (PDF) |
| 186 | Microstructure Evolution of Concentration Gradient Li[Ni<sub>0.75</sub>Co<sub>0.10</sub>Mn<sub>0.15</sub>]O<sub>2</sub> Cathode for Lithium‐Ion Batteries | 17.0 | 86 | Citations (PDF) |
| 187 | Superior lithium/potassium storage capability of nitrogen-rich porous carbon nanosheets derived from petroleum coke | 9.3 | 94 | Citations (PDF) |
| 188 | High-Performance LiNiO<sub>2</sub> Cathodes with Practical Loading Cycled with Li metal Anodes in Fluoroethylene Carbonate-Based Electrolyte Solution | 5.4 | 47 | Citations (PDF) |
| 189 | Minimizing the Electrolyte Volume in Li–S Batteries: A Step Forward to High Gravimetric Energy Density | 22.6 | 86 | Citations (PDF) |
| 190 | Development of P3-K<sub>0.69</sub>CrO<sub>2</sub> as an ultra-high-performance cathode material for K-ion batteries | 30.9 | 192 | Citations (PDF) |
| 191 | High performance potassium–sulfur batteries based on a sulfurized polyacrylonitrile cathode and polyacrylic acid binder | 9.3 | 119 | Citations (PDF) |
| 192 | Improved Cycling Stability of Li[Ni<sub>0.90</sub>Co<sub>0.05</sub>Mn<sub>0.05</sub>]O<sub>2</sub> Through Microstructure Modification by Boron Doping for Li‐Ion Batteries | 22.6 | 462 | Citations (PDF) |
| 193 | Aqueous Magnesium Zinc Hybrid Battery: An Advanced High-Voltage and High-Energy MgMn<sub>2</sub>O<sub>4</sub> Cathode | 17.0 | 208 | Citations (PDF) |
| 194 | K<sub>2</sub>V<sub>6</sub>O<sub>16</sub>·2.7H<sub>2</sub>O nanorod cathode: an advanced intercalation system for high energy aqueous rechargeable Zn-ion batteries | 9.3 | 278 | Citations (PDF) |
| 195 | A 4 V Li‐Ion Battery using All‐Spinel‐Based Electrodes | 6.2 | 13 | Citations (PDF) |
| 196 | Review—A Comparative Evaluation of Redox Mediators for Li-O<sub>2</sub>Batteries: A Critical Review | 3.1 | 73 | Citations (PDF) |
| 197 | Simultaneous MgO coating and Mg doping of Na[Ni<sub>0.5</sub>Mn<sub>0.5</sub>]O<sub>2</sub> cathode: facile and customizable approach to high-voltage sodium-ion batteries | 9.3 | 165 | Citations (PDF) |
| 198 | Recent research trends in Li–S batteries | 9.3 | 247 | Citations (PDF) |
| 199 | Recent progress of advanced binders for Li-S batteries | 7.9 | 110 | Citations (PDF) |
| 200 | Self-Passivation of a LiNiO<sub>2</sub> Cathode for a Lithium-Ion Battery through Zr Doping | 17.0 | 211 | Citations (PDF) |
| 201 | Redox Mediators for Li–O<sub>2</sub> Batteries: Status and Perspectives | 24.5 | 317 | Citations (PDF) |
| 202 | Large‐Scale LiO<sub>2</sub> Pouch Type Cells for Practical Evaluation and Applications | 17.0 | 40 | Citations (PDF) |
| 203 | Novel strategy to improve the Li-storage performance of micro silicon anodes | 7.9 | 47 | Citations (PDF) |
| 204 | Cu3Si-doped porous-silicon particles prepared by simplified chemical vapor deposition method as anode material for high-rate and long-cycle lithium-ion batteries | 6.0 | 46 | Citations (PDF) |
| 205 | Electrochemical Zinc Intercalation in Lithium Vanadium Oxide: A High-Capacity Zinc-Ion Battery Cathode | 6.7 | 562 | Citations (PDF) |
| 206 | Hollandite-type Al-doped VO<sub>1.52</sub>(OH)<sub>0.77</sub> as a zinc ion insertion host material | 9.3 | 149 | Citations (PDF) |
| 207 | Effect of carbon-sulphur bond in a sulphur/dehydrogenated polyacrylonitrile/reduced graphene oxide composite cathode for lithium-sulphur batteries | 7.9 | 35 | Citations (PDF) |
| 208 | An Advanced Separator for Li–O<sub>2</sub> Batteries: Maximizing the Effect of Redox Mediators | 22.6 | 118 | Citations (PDF) |
| 209 | Formation and Inhibition of Metallic Lithium Microstructures in Lithium Batteries Driven by Chemical Crossover | 15.3 | 190 | Citations (PDF) |
| 210 | Structural Stability of LiNiO<sub>2</sub> Cycled above 4.2 V | 17.0 | 389 | Citations (PDF) |
| 211 | Monoclinic-Orthorhombic Na<sub>1.1</sub>Li<sub>2.0</sub>V<sub>2</sub>(PO<sub>4</sub>)<sub>3</sub>/C Composite Cathode for Na<sup>+</sup>/Li<sup>+</sup> Hybrid-Ion Batteries | 6.7 | 23 | Citations (PDF) |
| 212 | Graphene Decorated by Indium Sulfide Nanoparticles as High-Performance Anode for Sodium-Ion Batteries | 8.0 | 62 | Citations (PDF) |
| 213 | High-Energy Density Core–Shell Structured Li[Ni<sub>0.95</sub>Co<sub>0.025</sub>Mn<sub>0.025</sub>]O<sub>2</sub> Cathode for Lithium-Ion Batteries | 6.7 | 149 | Citations (PDF) |
| 214 | Sodium-ion batteries: present and future | 37.8 | 4,811 | Citations (PDF) |
| 215 | Improved electrochemical performance of boron-doped carbon-coated lithium titanate as an anode material for sodium-ion batteries | 9.3 | 94 | Citations (PDF) |
| 216 | Na Storage Capability Investigation of a Carbon Nanotube-Encapsulated Fe<sub>1–<i>x</i></sub>S Composite | 17.0 | 201 | Citations (PDF) |
| 217 | Superior Li/Na-storage capability of a carbon-free hierarchical CoSx hollow nanostructure | 16.3 | 167 | Citations (PDF) |
| 218 | Nickel-Rich Layered Cathode Materials for Automotive Lithium-Ion Batteries: Achievements and Perspectives | 17.0 | 1,285 | Citations (PDF) |
| 219 | Micro-Intertexture Carbon-Free Iron Sulfides as Advanced High Tap Density Anodes for Rechargeable Batteries | 8.0 | 50 | Citations (PDF) |
| 220 | Effect of Mn in Li<sub>3</sub>V<sub>2–<i>x</i></sub>Mn<sub><i>x</i></sub>(PO<sub>4</sub>)<sub>3</sub> as High Capacity Cathodes for Lithium Batteries | 8.0 | 34 | Citations (PDF) |
| 221 | Self-assembled nickel-cobalt oxide microspheres from rods with enhanced electrochemical performance for sodium ion battery | 5.3 | 13 | Citations (PDF) |
| 222 | Facile synthesis and the exploration of the zinc storage mechanism of β-MnO<sub>2</sub> nanorods with exposed (101) planes as a novel cathode material for high performance eco-friendly zinc-ion batteries | 9.3 | 382 | Citations (PDF) |
| 223 | Antimony Selenide Nanorods Decorated on Reduced Graphene Oxide with Excellent Electrochemical Properties for Li-Ion Batteries | 3.1 | 34 | Citations (PDF) |
| 224 | Tunnel-type β-FeOOH cathode material for high rate sodium storage via a new conversion reaction | 16.3 | 48 | Citations (PDF) |
| 225 | Electrochemical Properties of Sulfurized-Polyacrylonitrile Cathode for Lithium–Sulfur Batteries: Effect of Polyacrylic Acid Binder and Fluoroethylene Carbonate Additive | 4.2 | 116 | Citations (PDF) |
| 226 | Resolving the degradation pathways of the O3-type layered oxide cathode surface through the nano-scale aluminum oxide coating for high-energy density sodium-ion batteries | 9.3 | 163 | Citations (PDF) |
| 227 | Synergistic Integration of Soluble Catalysts with Carbon-Free Electrodes for Li–O<sub>2</sub> Batteries | 12.4 | 21 | Citations (PDF) |
| 228 | Synthetic Control of Kinetic Reaction Pathway and Cationic Ordering in High‐Ni Layered Oxide Cathodes | 24.5 | 168 | Citations (PDF) |
| 229 | Self-Rearrangement of Silicon Nanoparticles Embedded in Micro-Carbon Sphere Framework for High-Energy and Long-Life Lithium-Ion Batteries | 8.7 | 160 | Citations (PDF) |
| 230 | Sodium oxygen batteries: one step further with catalysis by ruthenium nanoparticles | 9.3 | 32 | Citations (PDF) |
| 231 | Synthesis and Electrochemical Reaction of Tin Oxalate-Reduced Graphene Oxide Composite Anode for Rechargeable Lithium Batteries | 8.0 | 42 | Citations (PDF) |
| 232 | Extending the Battery Life Using an Al-Doped Li[Ni<sub>0.76</sub>Co<sub>0.09</sub>Mn<sub>0.15</sub>]O<sub>2</sub> Cathode with Concentration Gradients for Lithium Ion Batteries | 17.0 | 200 | Citations (PDF) |
| 233 | Optimized Bicompartment Two Solution Cells for Effective and Stable Operation of Li–O<sub>2</sub> Batteries | 22.6 | 69 | Citations (PDF) |
| 234 | 2,4-Dimethoxy-2,4-dimethylpentan-3-one: An Aprotic Solvent Designed for Stability in Li–O<sub>2</sub> Cells | 15.0 | 45 | Citations (PDF) |
| 235 | High-Energy Ni-Rich Li[Ni<sub><i>x</i></sub>Co<sub><i>y</i></sub>Mn<sub>1<i>–x–y</i></sub>]O<sub>2</sub> Cathodes via Compositional Partitioning for Next-Generation Electric Vehicles | 6.7 | 236 | Citations (PDF) |
| 236 | A new perspective of the ruthenium ion: a bifunctional soluble catalyst for high efficiency Li–O<sub>2</sub>batteries | 9.3 | 23 | Citations (PDF) |
| 237 | Feasibility of Full (Li-Ion)–O<sub>2</sub> Cells Comprised of Hard Carbon Anodes | 8.0 | 34 | Citations (PDF) |
| 238 | The Application of Metal Sulfides in Sodium Ion Batteries | 22.6 | 590 | Citations (PDF) |
| 239 | Walnut-like ZnO@Zn2TiO4 multicore-shell submicron spheres with a thin carbon layer: Fine synthesis, facile structural control and solar light photocatalytic application | 8.7 | 36 | Citations (PDF) |
| 240 | Remarkably Improved Electrochemical Performance of Li- and Mn-Rich Cathodes upon Substitution of Mn with Ni | 8.0 | 45 | Citations (PDF) |
| 241 | Fabrication of flower-like tin/carbon composite microspheres as long-lasting anode materials for lithium ion batteries | 4.5 | 7 | Citations (PDF) |
| 242 | Microsphere Na<sub>0.65</sub>[Ni<sub>0.17</sub>Co<sub>0.11</sub>Mn<sub>0.72</sub>]O<sub>2</sub> Cathode Material for High-Performance Sodium-Ion Batteries | 8.0 | 55 | Citations (PDF) |
| 243 | (Battery Division Technology Award Address) Progress in High-Capacity
Gradient Layered Li[NixCoyMnz]O2 Cathodes for Lithium-ion Batteries | 0.0 | 0 | Citations (PDF) |
| 244 | Freestanding Bilayer Carbon–Sulfur Cathode with Function of Entrapping Polysulfide for High Performance Li–S Batteries | 17.0 | 94 | Citations (PDF) |
| 245 | A Long‐Life Lithium Ion Battery with Enhanced Electrode/Electrolyte Interface by Using an Ionic Liquid Solution | 3.4 | 56 | Citations (PDF) |
| 246 | High-energy-density lithium-ion battery using a carbon-nanotube–Si composite anode and a compositionally graded Li[Ni<sub>0.85</sub>Co<sub>0.05</sub>Mn<sub>0.10</sub>]O<sub>2</sub> cathode | 30.9 | 306 | Citations (PDF) |
| 247 | Effect of nickel and iron on structural and electrochemical properties of O3 type layer cathode materials for sodium-ion batteries | 7.9 | 84 | Citations (PDF) |
| 248 | An Alternative Approach to Enhance the Performance of High Sulfur-Loading Electrodes for Li–S Batteries | 17.0 | 77 | Citations (PDF) |
| 249 | Nanostructured lithium sulfide materials for lithium-sulfur batteries | 7.9 | 85 | Citations (PDF) |
| 250 | Li–O<sub>2</sub> cells with LiBr as an electrolyte and a redox mediator | 30.9 | 261 | Citations (PDF) |
| 251 | Synthesis and Electrochemical Performance of Nickel-Rich Layered-Structure LiNi<sub>0.65</sub>Co<sub>0.08</sub>Mn<sub>0.27</sub>O<sub>2</sub>Cathode Materials Comprising Particles with Ni and Mn Full Concentration Gradients | 3.1 | 22 | Citations (PDF) |
| 252 | Novel Cathode Materials for Na‐Ion Batteries Composed of Spoke‐Like Nanorods of Na[Ni<sub>0.61</sub>Co<sub>0.12</sub>Mn<sub>0.27</sub>]O<sub>2</sub> Assembled in Spherical Secondary Particles | 17.0 | 98 | Citations (PDF) |
| 253 | A comprehensive study of the role of transition metals in O3-type layered Na[Ni<sub>x</sub>Co<sub>y</sub>Mn<sub>z</sub>]O<sub>2</sub> (x = 1/3, 0.5, 0.6, and 0.8) cathodes for sodium-ion batteries | 9.3 | 141 | Citations (PDF) |
| 254 | Vanadium dioxide – Reduced graphene oxide composite as cathode materials for rechargeable Li and Na batteries | 7.9 | 49 | Citations (PDF) |
| 255 | Compositionally Graded Cathode Material with Long‐Term Cycling Stability for Electric Vehicles Application | 22.6 | 166 | Citations (PDF) |
| 256 | Nanostructured metal phosphide-based materials for electrochemical energy storage | 9.3 | 281 | Citations (PDF) |
| 257 | A Scaled‐Up Lithium (Ion)‐Sulfur Battery: Newly Faced Problems and Solutions | 5.9 | 33 | Citations (PDF) |
| 258 | Unveiling the sodium intercalation properties in Na1.86□0.14Fe3(PO4)3 | 7.9 | 41 | Citations (PDF) |
| 259 | Understanding problems of lithiated anodes in lithium oxygen full-cells | 9.3 | 33 | Citations (PDF) |
| 260 | Comparative Study of Ni-Rich Layered Cathodes for Rechargeable Lithium Batteries: Li[Ni<sub>0.85</sub>Co<sub>0.11</sub>Al<sub>0.04</sub>]O<sub>2</sub> and Li[Ni<sub>0.84</sub>Co<sub>0.06</sub>Mn<sub>0.09</sub>Al<sub>0.01</sub>]O<sub>2</sub> with Two-Step Full Concentration Gradients | 17.0 | 126 | Citations (PDF) |
| 261 | Nickel oxalate dihydrate nanorods attached to reduced graphene oxide sheets as a high-capacity anode for rechargeable lithium batteries | 7.5 | 67 | Citations (PDF) |
| 262 | Transition metal carbide-based materials: synthesis and applications in electrochemical energy storage | 9.3 | 224 | Citations (PDF) |
| 263 | Comparison between Na-Ion and Li-Ion Cells: Understanding the Critical Role of the Cathodes Stability and the Anodes Pretreatment on the Cells Behavior | 8.0 | 175 | Citations (PDF) |
| 264 | Iron–cobalt bimetal decorated carbon nanotubes as cost-effective cathode catalysts for Li–O<sub>2</sub>batteries | 9.3 | 45 | Citations (PDF) |
| 265 | High‐Energy, High‐Rate, Lithium–Sulfur Batteries: Synergetic Effect of Hollow TiO<sub>2</sub>‐Webbed Carbon Nanotubes and a Dual Functional Carbon‐Paper Interlayer | 22.6 | 345 | Citations (PDF) |
| 266 | Mechanistic Role of Li<sup>+</sup> Dissociation Level in Aprotic Li–O<sub>2</sub> Battery | 8.0 | 134 | Citations (PDF) |
| 267 | Silver nanowires as catalytic cathodes for stabilizing lithium-oxygen batteries | 7.9 | 31 | Citations (PDF) |
| 268 | Neutron diffraction studies of the Na-ion battery electrode materials NaCoCr2(PO4)3, NaNiCr2(PO4)3, and Na2Ni2Cr(PO4)3 | 3.3 | 26 | Citations (PDF) |
| 269 | Rational design of silicon-based composites for high-energy storage devices | 9.3 | 191 | Citations (PDF) |
| 270 | Electrochemical performance of a thermally rearranged polybenzoxazole nanocomposite membrane as a separator for lithium-ion batteries at elevated temperature | 7.9 | 28 | Citations (PDF) |
| 271 | High-Performance Lithium–Sulfur Batteries with a Self-Assembled Multiwall Carbon Nanotube Interlayer and a Robust Electrode–Electrolyte Interface | 8.0 | 118 | Citations (PDF) |
| 272 | Epicyanohydrin as an Interface Stabilizer Agent for Cathodes of Li-Ion Batteries | 3.1 | 39 | Citations (PDF) |
| 273 | High-power lithium polysulfide-carbon battery | 10.7 | 23 | Citations (PDF) |
| 274 | Synthesis of full concentration gradient cathode studied by high energy X-ray diffraction | 16.3 | 78 | Citations (PDF) |
| 275 | Study of the Most Relevant Aspects Related to Hard Carbons as Anode Materials for Na‐ion Batteries, Compared with Li‐ion Systems | 2.0 | 35 | Citations (PDF) |
| 276 | Advanced Concentration Gradient Cathode Material with Two‐Slope for High‐Energy and Safe Lithium Batteries | 17.0 | 137 | Citations (PDF) |
| 277 | In Situ Formation of a Cathode–Electrolyte Interface with Enhanced Stability by Titanium Substitution for High Voltage Spinel Lithium‐Ion Batteries | 4.1 | 70 | Citations (PDF) |
| 278 | Improved capacity and stability of integrated Li and Mn rich layered-spinel Li<sub>1.17</sub>Ni<sub>0.25</sub>Mn<sub>1.08</sub>O<sub>3</sub> cathodes for Li-ion batteries | 9.3 | 32 | Citations (PDF) |
| 279 | Improved Performances of Li[Ni<sub>0.65</sub>Co<sub>0.08</sub>Mn<sub>0.27</sub>]O<sub>2</sub>Cathode Material with Full Concentration Gradient for Li-Ion Batteries | 3.1 | 34 | Citations (PDF) |
| 280 | Nanoconfinement of low-conductivity products in rechargeable sodium–air batteries | 16.3 | 68 | Citations (PDF) |
| 281 | Carbothermal synthesis of molybdenum(IV) oxide as a high rate anode for rechargeable lithium batteries | 7.9 | 19 | Citations (PDF) |
| 282 | Carbon-coated anatase titania as a high rate anode for lithium batteries | 7.9 | 23 | Citations (PDF) |
| 283 | Carbon-coated Li4Ti5O12 nanowires showing high rate capability as an anode material for rechargeable sodium batteries | 16.3 | 114 | Citations (PDF) |
| 284 | Nanostructured cathode materials for rechargeable lithium batteries | 7.9 | 104 | Citations (PDF) |
| 285 | Study on the Catalytic Activity of Noble Metal Nanoparticles on Reduced Graphene Oxide for Oxygen Evolution Reactions in Lithium–Air Batteries | 8.7 | 168 | Citations (PDF) |
| 286 | A carbon-free ruthenium oxide/mesoporous titanium dioxide electrode for lithium-oxygen batteries | 7.9 | 35 | Citations (PDF) |
| 287 | Ultrafast sodium storage in anatase TiO2 nanoparticles embedded on carbon nanotubes | 16.3 | 140 | Citations (PDF) |
| 288 | Improvement of Electrochemical Properties of Lithium–Oxygen Batteries Using a Silver Electrode | 3.1 | 23 | Citations (PDF) |
| 289 | High surface area, mesoporous carbon for low-polarization, catalyst-free lithium oxygen battery | 3.1 | 14 | Citations (PDF) |
| 290 | Fluorine-doped porous carbon-decorated Fe3O4-FeF2 composite versus LiNi0.5Mn1.5O4 towards a full battery with robust capability | 5.3 | 34 | Citations (PDF) |
| 291 | A new synthetic method of titanium oxyfluoride and its application as an anode material for rechargeable lithium batteries | 7.9 | 20 | Citations (PDF) |
| 292 | Understanding the behavior of Li–oxygen cells containing LiI | 9.3 | 206 | Citations (PDF) |
| 293 | Radially aligned hierarchical columnar structure as a cathode material for high energy density sodium-ion batteries | 13.9 | 290 | Citations (PDF) |
| 294 | NaCrO<sub>2</sub> cathode for high-rate sodium-ion batteries | 30.9 | 372 | Citations (PDF) |
| 295 | Highly monodisperse magnetite/carbon composite microspheres with a mesoporous structure as high-performance lithium-ion battery anodes | 4.4 | 8 | Citations (PDF) |
| 296 | Electrochemical Performance of a Layered-Spinel Integrated Li[Ni<sub>1/3</sub>Mn<sub>2/3</sub>]O<sub>2</sub> as a High Capacity Cathode Material for Li-Ion Batteries | 6.7 | 51 | Citations (PDF) |
| 297 | A Mo<sub>2</sub>C/Carbon Nanotube Composite Cathode for Lithium–Oxygen Batteries with High Energy Efficiency and Long Cycle Life | 15.3 | 219 | Citations (PDF) |
| 298 | Highly Cyclable Lithium–Sulfur Batteries with a Dual-Type Sulfur Cathode and a Lithiated Si/SiO<sub><i>x</i></sub> Nanosphere Anode | 8.7 | 133 | Citations (PDF) |
| 299 | Interphase Evolution of a Lithium-Ion/Oxygen Battery | 8.0 | 56 | Citations (PDF) |
| 300 | A high-capacity Li[Ni<sub>0.8</sub>Co<sub>0.06</sub>Mn<sub>0.14</sub>]O<sub>2</sub>positive electrode with a dual concentration gradient for next-generation lithium-ion batteries | 9.3 | 95 | Citations (PDF) |
| 301 | Effect of titanium addition as nickel oxide formation inhibitor in nickel-rich cathode material for lithium-ion batteries | 7.9 | 62 | Citations (PDF) |
| 302 | Evaluation of (CF<sub>3</sub>SO<sub>2</sub>)<sub>2</sub>N<sup>−</sup>(TFSI) Based Electrolyte Solutions for Mg Batteries | 3.1 | 358 | Citations (PDF) |
| 303 | Green Strategy to Single Crystalline Anatase TiO<sub>2</sub> Nanosheets with Dominant (001) Facets and Its Lithiation Study toward Sustainable Cobalt-Free Lithium Ion Full Battery | 6.9 | 35 | Citations (PDF) |
| 304 | Review—Understanding and Mitigating Some of the Key Factors that Limit Non-Aqueous Lithium-Air Battery Performance | 3.1 | 30 | Citations (PDF) |
| 305 | Review—High-Capacity Li[Ni<sub>1-</sub><i><sub>x</sub></i>Co<i><sub>x</sub></i><sub>/2</sub>Mn<i><sub>x</sub></i><sub>/2</sub>]O<sub>2</sub>(<i>x</i>= 0.1, 0.05, 0) Cathodes for Next-Generation Li-Ion Battery | 3.1 | 141 | Citations (PDF) |
| 306 | Catalytic Behavior of Lithium Nitrate in Li-O<sub>2</sub> Cells | 8.0 | 149 | Citations (PDF) |
| 307 | Effect of Lithium in Transition Metal Layers of Ni-Rich Cathode Materials on Electrochemical Properties | 3.1 | 17 | Citations (PDF) |
| 308 | Highly lithium-ion conductive battery separators from thermally rearranged polybenzoxazole | 3.4 | 36 | Citations (PDF) |
| 309 | A sustainable iron-based sodium ion battery of porous carbon–Fe<sub>3</sub>O<sub>4</sub>/Na<sub>2</sub>FeP<sub>2</sub>O<sub>7</sub> with high performance | 4.4 | 82 | Citations (PDF) |
| 310 | The Lithium/Air Battery: Still an Emerging System or a Practical Reality? | 24.5 | 590 | Citations (PDF) |
| 311 | Effect of outer layer thickness on full concentration gradient layered cathode material for lithium-ion batteries | 7.9 | 26 | Citations (PDF) |
| 312 | Amorphous iron phosphate: potential host for various charge carrier ions | 7.5 | 249 | Citations (PDF) |
| 313 | Effectively suppressing dissolution of manganese from spinel lithium manganate via a nanoscale surface-doping approach | 13.9 | 303 | Citations (PDF) |
| 314 | Lithiation of an Iron Oxide‐Based Anode for Stable, High‐Capacity Lithium‐Ion Batteries of Porous Carbon–Fe<sub>3</sub>O<sub>4</sub>/Li[Ni<sub>0.59</sub>Co<sub>0.16</sub>Mn<sub>0.25</sub>]O<sub>2</sub> | 3.4 | 50 | Citations (PDF) |
| 315 | Simple fabrication and electrochemical performance of porous and double-shelled macroporous CuO nanomaterials with a thin carbon layer | 4.4 | 3 | Citations (PDF) |
| 316 | Comparison of Nanorod‐Structured Li[Ni<sub>0.54</sub>Co<sub>0.16</sub>Mn<sub>0.30</sub>]O<sub>2</sub> with Conventional Cathode Materials for Li‐Ion Batteries | 6.2 | 41 | Citations (PDF) |
| 317 | High dispersion of TiO<sub>2</sub>nanocrystals within porous carbon improves lithium storage capacity and can be applied batteries to LiNi<sub>0.5</sub>Mn<sub>1.5</sub>O<sub>4</sub> | 9.3 | 24 | Citations (PDF) |
| 318 | Improved lithium-ion battery performance of LiNi0.5Mn1.5−xTixO4 high voltage spinel in full-cells paired with graphite and Li4Ti5O12 negative electrodes | 7.9 | 48 | Citations (PDF) |
| 319 | Thermal properties of fully delithiated olivines | 7.9 | 13 | Citations (PDF) |
| 320 | Anatase Titania Nanorods as an Intercalation Anode Material for Rechargeable Sodium Batteries | 8.7 | 443 | Citations (PDF) |
| 321 | Effect of Residual Lithium Compounds on Layer Ni-Rich Li[Ni<sub>0.7</sub>Mn<sub>0.3</sub>]O<sub>2</sub> | 3.1 | 335 | Citations (PDF) |
| 322 | Sodium‐Ion Battery based on an Electrochemically Converted NaFePO<sub>4</sub> Cathode and Nanostructured Tin–Carbon Anode | 1.9 | 67 | Citations (PDF) |
| 323 | A High‐Energy Li‐Ion Battery Using a Silicon‐Based Anode and a Nano‐Structured Layered Composite Cathode | 17.0 | 152 | Citations (PDF) |
| 324 | Aprotic and Aqueous Li–O<sub>2</sub> Batteries | 52.7 | 1,076 | Citations (PDF) |
| 325 | Electrochemical Properties of Polyaniline-Coated Li-Rich Nickel Manganese Oxide and Role of Polyaniline Coating Layer | 3.1 | 32 | Citations (PDF) |
| 326 | Optimization of Layered Cathode Material with Full Concentration Gradient for Lithium-Ion Batteries | 3.1 | 47 | Citations (PDF) |
| 327 | An Advanced Lithium–Air Battery Exploiting an Ionic Liquid-Based Electrolyte | 8.7 | 214 | Citations (PDF) |
| 328 | Stable, High Voltage Li<sub>0.85</sub>Ni<sub>0.46</sub>Cu<sub>0.1</sub>Mn<sub>1.49</sub>O<sub>4</sub> Spinel Cathode in a Lithium-Ion Battery Using a Conversion-Type CuO Anode | 8.0 | 42 | Citations (PDF) |
| 329 | Migration of Mn cations in delithiated lithium manganese oxides | 2.7 | 24 | Citations (PDF) |
| 330 | The binder effect on an oxide-based anode in lithium and sodium-ion battery applications: the fastest way to ultrahigh performance | 3.4 | 74 | Citations (PDF) |
| 331 | A Physical Pulverization Strategy for Preparing a Highly Active Composite of CoO<sub><i>x</i></sub> and Crushed Graphite for Lithium–Oxygen Batteries | 1.9 | 10 | Citations (PDF) |
| 332 | Effect of the size-selective silver clusters on lithium peroxide morphology in lithium–oxygen batteries | 13.9 | 201 | Citations (PDF) |
| 333 | Nanorod and Nanoparticle Shells in Concentration Gradient Core–Shell Lithium Oxides for Rechargeable Lithium Batteries | 6.2 | 27 | Citations (PDF) |
| 334 | High Electrochemical Performances of Microsphere C-TiO<sub>2</sub> Anode for Sodium-Ion Battery | 8.0 | 215 | Citations (PDF) |
| 335 | High Capacity O3-Type Na[Li<sub>0.05</sub>(Ni<sub>0.25</sub>Fe<sub>0.25</sub>Mn<sub>0.5</sub>)<sub>0.95</sub>]O<sub>2</sub> Cathode for Sodium Ion Batteries | 6.7 | 226 | Citations (PDF) |
| 336 | High-Energy Layered Oxide Cathodes with Thin Shells for Improved Surface Stability | 6.7 | 49 | Citations (PDF) |
| 337 | α-Fe<sub>2</sub>O<sub>3</sub>Submicron Spheres with Hollow and Macroporous Structures as High-Performance Anode Materials for Lithium Ion Batteries | 3.1 | 86 | Citations (PDF) |
| 338 | Differentiating allotropic LiCoO2/Li2Co2O4: A structural and electrochemical study | 7.9 | 28 | Citations (PDF) |
| 339 | Surfactant-Assisted Synthesis of Fe<sub>2</sub>O<sub>3</sub>Nanoparticles and F-Doped Carbon Modification toward an Improved Fe<sub>3</sub>O<sub>4</sub>@CF<sub><i>x</i></sub>/LiNi<sub>0.5</sub>Mn<sub>1.5</sub>O<sub>4</sub>Battery | 8.0 | 73 | Citations (PDF) |
| 340 | Low Temperature Electrochemical Properties of Li[Ni<sub>x</sub>Co<sub>y</sub>Mn<sub>1-x-y</sub>]O<sub>2</sub>Cathode Materials for Lithium-Ion Batteries | 3.1 | 32 | Citations (PDF) |
| 341 | Development of Microstrain in Aged Lithium Transition Metal Oxides | 8.7 | 199 | Citations (PDF) |
| 342 | Characteristics of Li2S8-tetraglyme catholyte in a semi-liquid lithium–sulfur battery | 7.9 | 74 | Citations (PDF) |
| 343 | Role of the Lithium Salt in the Performance of Lithium–Oxygen Batteries: A Comparative Study | 2.9 | 50 | Citations (PDF) |
| 344 | Advanced Na[Ni<sub>0.25</sub>Fe<sub>0.5</sub>Mn<sub>0.25</sub>]O<sub>2</sub>/C–Fe<sub>3</sub>O<sub>4</sub> Sodium-Ion Batteries Using EMS Electrolyte for Energy Storage | 8.7 | 308 | Citations (PDF) |
| 345 | A Lithium-Ion Sulfur Battery Based on a Carbon-Coated Lithium-Sulfide Cathode and an Electrodeposited Silicon-Based Anode | 8.0 | 135 | Citations (PDF) |
| 346 | Recent advances in the Si-based nanocomposite materials as high capacity anode materials for lithium ion batteries | 14.0 | 155 | Citations (PDF) |
| 347 | An effective method to reduce residual lithium compounds on Ni-rich Li[Ni0.6Co0.2Mn0.2]O2 active material using a phosphoric acid derived Li3PO4 nanolayer | 8.6 | 348 | Citations (PDF) |
| 348 | An Advanced Lithium‐Sulfur Battery | 17.0 | 321 | Citations (PDF) |
| 349 | Formation of a Continuous Solid‐Solution Particle and its Application to Rechargeable Lithium Batteries | 17.0 | 41 | Citations (PDF) |
| 350 | Compatibility of lithium salts with solvent of the non-aqueous electrolyte in Li–O2 batteries | 2.7 | 77 | Citations (PDF) |
| 351 | Interactions of Dimethoxy Ethane with Li<sub>2</sub>O<sub>2</sub> Clusters and Likely Decomposition Mechanisms for Li–O<sub>2</sub> Batteries | 3.1 | 80 | Citations (PDF) |
| 352 | Assembling metal oxide nanocrystals into dense, hollow, porous nanoparticles for lithium-ion and lithium–oxygen battery application | 5.0 | 42 | Citations (PDF) |
| 353 | A nanostructured cathode architecture for low charge overpotential in lithium-oxygen batteries | 13.9 | 400 | Citations (PDF) |
| 354 | Black anatase titania enabling ultra high cycling rates for rechargeable lithium batteries | 30.9 | 234 | Citations (PDF) |
| 355 | Nanostructured TiO2 microspheres for dye-sensitized solar cells employing a solid state polymer electrolyte | 5.3 | 21 | Citations (PDF) |
| 356 | Synthesis of Porous Carbon Supported Palladium Nanoparticle Catalysts by Atomic Layer Deposition: Application for Rechargeable Lithium–O<sub>2</sub> Battery | 8.7 | 191 | Citations (PDF) |
| 357 | Progress in Lithium–Sulfur Batteries: The Effective Role of a Polysulfide‐Added Electrolyte as Buffer to Prevent Cathode Dissolution | 6.2 | 77 | Citations (PDF) |
| 358 | Rattle type α-Fe2O3 submicron spheres with a thin carbon layer for lithium-ion battery anodes | 9.3 | 32 | Citations (PDF) |
| 359 | Sodium salt effect on hydrothermal carbonization of biomass: a catalyst for carbon-based nanostructured materials for lithium-ion battery applications | 9.1 | 71 | Citations (PDF) |
| 360 | Cobalt-Free Nickel Rich Layered Oxide Cathodes for Lithium-Ion Batteries | 8.0 | 279 | Citations (PDF) |
| 361 | Ordered Mesoporous Carbon Electrodes for Li–O<sub>2</sub> Batteries | 8.0 | 73 | Citations (PDF) |
| 362 | Mn(II) deposition on anodes and its effects on capacity fade in spinel lithium manganate–carbon systems | 13.9 | 487 | Citations (PDF) |
| 363 | Self-assembled hollow mesoporous Co3O4 hybrid architectures: a facile synthesis and application in Li-ion batteries | 9.3 | 42 | Citations (PDF) |
| 364 | Alternative materials for sodium ion–sulphur batteries | 9.3 | 156 | Citations (PDF) |
| 365 | An advanced sodium-ion rechargeable battery based on a tin–carbon anode and a layered oxide framework cathode | 2.7 | 93 | Citations (PDF) |
| 366 | Iron trifluoride synthesized via evaporation method and its application to rechargeable lithium batteries | 7.9 | 54 | Citations (PDF) |
| 367 | Magnetism in Lithium–Oxygen Discharge Product | 6.2 | 28 | Citations (PDF) |
| 368 | Synthesis of Fe3O4/C composite microspheres for a high performance lithium-ion battery anode | 7.9 | 37 | Citations (PDF) |
| 369 | Improved rate capability of lithium-ion batteries with Ag nanoparticles deposited onto silicon/carbon composite microspheres as an anode material | 3.1 | 30 | Citations (PDF) |
| 370 | Investigation of the carbon electrode changes during lithium oxygen cell operation in a tetraglyme-based electrolyte | 3.9 | 21 | Citations (PDF) |
| 371 | Monodispersed hollow carbon/Fe3O4 composite microspheres for high performance anode materials in lithium-ion batteries | 7.9 | 34 | Citations (PDF) |
| 372 | Comparison of the structural and electrochemical properties of layered Li[NixCoyMnz]O2 (x = 1/3, 0.5, 0.6, 0.7, 0.8 and 0.85) cathode material for lithium-ion batteries | 7.9 | 2,139 | Citations (PDF) |
| 373 | Encapsulation of Metal Oxide Nanocrystals into Porous Carbon with Ultrahigh Performances in Lithium-Ion Battery | 8.0 | 56 | Citations (PDF) |
| 374 | Improvement of long-term cycling performance of Li[Ni0.8Co0.15Al0.05]O2 by AlF3 coating | 7.9 | 260 | Citations (PDF) |
| 375 | Cathode Material with Nanorod Structure—An Application for Advanced High-Energy and Safe Lithium Batteries | 6.7 | 162 | Citations (PDF) |
| 376 | Improving the electrochemical performance of LiMn0.85Fe0.15PO4–LiFePO4 core–shell materials based on an investigation of carbon source effect | 7.9 | 23 | Citations (PDF) |
| 377 | Influence of Temperature on Lithium–Oxygen Battery Behavior | 8.7 | 76 | Citations (PDF) |
| 378 | Ruthenium-Based Electrocatalysts Supported on Reduced Graphene Oxide for Lithium-Air Batteries | 15.3 | 380 | Citations (PDF) |
| 379 | Unique core–shell structured SiO<sub>2</sub>(Li<sup>+</sup>) nanoparticles for high-performance composite polymer electrolytes | 9.3 | 53 | Citations (PDF) |
| 380 | Cycling characteristics of lithium metal batteries assembled with a surface modified lithium electrode | 7.9 | 85 | Citations (PDF) |
| 381 | Evidence for lithium superoxide-like species in the discharge product of a Li–O2 battery | 2.7 | 196 | Citations (PDF) |
| 382 | A high energy and power density hybrid supercapacitor based on an advanced carbon-coated Li4Ti5O12 electrode | 7.9 | 197 | Citations (PDF) |
| 383 | 3 Dimensional Carbon Nanostructures for Li-ion Battery Anode | 0.1 | 1 | Citations (PDF) |
| 384 | Highly reversible conversion-capacity of MnOx-loaded ordered mesoporous carbon nanorods for lithium-ion battery anodes | 7.3 | 64 | Citations (PDF) |
| 385 | Fe-Fe<sub>3</sub>O<sub>4</sub>Composite Electrode for Lithium Secondary Batteries | 3.1 | 21 | Citations (PDF) |
| 386 | Nickel-Layer Protected, Carbon-Coated Sulfur Electrode for Lithium Battery | 3.1 | 27 | Citations (PDF) |
| 387 | 3-dimensional carbon nanotube for Li-ion battery anode | 7.9 | 58 | Citations (PDF) |
| 388 | Improved Co-substituted, LiNi0.5−Co2Mn1.5−O4 lithium ion battery cathode materials | 7.9 | 54 | Citations (PDF) |
| 389 | Reversible NaFePO4 electrode for sodium secondary batteries | 3.9 | 404 | Citations (PDF) |
| 390 | Lithiumbatterien und elektrische Doppelschichtkondensatoren: aktuelle Herausforderungen | 1.4 | 188 | Citations (PDF) |
| 391 | Challenges Facing Lithium Batteries and Electrical Double‐Layer Capacitors | 14.4 | 2,604 | Citations (PDF) |
| 392 | Olivine LiCoPO4–carbon composite showing high rechargeable capacity | 7.3 | 54 | Citations (PDF) |
| 393 | A Metal-Free, Lithium-Ion Oxygen Battery: A Step Forward to Safety in Lithium-Air Batteries | 8.7 | 158 | Citations (PDF) |
| 394 | Fine control of titania deposition to prepare C@TiO2 composites and TiO2 hollow particles for photocatalysis and lithium-ion battery applications | 7.3 | 62 | Citations (PDF) |
| 395 | A Transmission Electron Microscopy Study of the Electrochemical Process of Lithium–Oxygen Cells | 8.7 | 109 | Citations (PDF) |
| 396 | A Long Life, High Capacity, High Rate Lithium-Air Battery Using a Stable
Glyme Electrolyte | 0.0 | 0 | Citations (PDF) |
| 397 | An improved high-performance lithium–air battery | 18.8 | 1,068 | Citations (PDF) |
| 398 | Double‐Structured LiMn<sub>0.85</sub>Fe<sub>0.15</sub>PO<sub>4</sub> Coordinated with LiFePO<sub>4</sub> for Rechargeable Lithium Batteries | 1.4 | 17 | Citations (PDF) |
| 399 | A tetraethylene glycol dimethylether-lithium bis(oxalate)borate (TEGDME-LiBOB) electrolyte for advanced lithium ion batteries | 3.9 | 33 | Citations (PDF) |
| 400 | Composite gel polymer electrolytes containing core-shell structured SiO2(Li+) particles for lithium-ion polymer batteries | 3.9 | 107 | Citations (PDF) |
| 401 | Improved electrochemical performances of LiM0.05Co0.95O1.95F0.05 (M=Mg, Al, Zr) at high voltage | 5.3 | 43 | Citations (PDF) |
| 402 | Hollow Fe3O4 microspheres as anode materials for lithium-ion batteries | 5.3 | 67 | Citations (PDF) |
| 403 | Synthesis and electrochemical properties of nanorod-shaped LiMn1.5Ni0.5O4 cathode materials for lithium-ion batteries | 4.5 | 9 | Citations (PDF) |
| 404 | A contribution to the progress of high energy batteries: A metal-free, lithium-ion, silicon–sulfur battery | 7.9 | 157 | Citations (PDF) |
| 405 | Synthesis of Li[Li1.19Ni0.16Co0.08Mn0.57]O2 cathode materials with a high volumetric capacity for Li-ion batteries | 7.9 | 66 | Citations (PDF) |
| 406 | The Role of AlF<sub>3</sub> Coatings in Improving Electrochemical Cycling of Li‐Enriched Nickel‐Manganese Oxide Electrodes for Li‐Ion Batteries | 24.5 | 679 | Citations (PDF) |
| 407 | Double‐Structured LiMn<sub>0.85</sub>Fe<sub>0.15</sub>PO<sub>4</sub> Coordinated with LiFePO<sub>4</sub> for Rechargeable Lithium Batteries | 14.4 | 122 | Citations (PDF) |
| 408 | Effect of Mo-doped LiFePO<sub>4</sub>Positive Electrode Material for Lithium Batteries | 2.9 | 2 | Citations (PDF) |
| 409 | Bottom-up in situ formation of Fe3O4 nanocrystals in a porous carbon foam for lithium-ion battery anodes | 7.3 | 215 | Citations (PDF) |
| 410 | Composition-Tailored Synthesis of Gradient Transition Metal Precursor Particles for Lithium-Ion Battery Cathode Materials | 6.7 | 118 | Citations (PDF) |
| 411 | Electrochemical Properties of Sol–Gel Prepared Li2ZrxTi1–x(PO4)3 Electrodes for Lithium Secondary Batteries | 3.1 | 11 | Citations (PDF) |
| 412 | Mechanism of capacity fade of MCMB/Li1.1[Ni1/3Mn1/3Co1/3]0.9O2 cell at elevated temperature and additives to improve its cycle life | 7.3 | 96 | Citations (PDF) |
| 413 | Advanced cathode materials for lithium-ion batteries | 4.1 | 42 | Citations (PDF) |
| 414 | A high-rate long-life Li4Ti5O12/Li[Ni0.45Co0.1Mn1.45]O4 lithium-ion battery | 13.9 | 341 | Citations (PDF) |
| 415 | Ultrathin alumina-coated carbon nanotubes as an anode for high capacity Li-ion batteries | 7.3 | 70 | Citations (PDF) |
| 416 | Co-precipitation synthesis of micro-sized spherical LiMn0.5Fe0.5PO4 cathode material for lithium batteries | 7.3 | 89 | Citations (PDF) |
| 417 | Microscale spherical carbon-coated Li4Ti5O12 as ultra high power anode material for lithium batteries | 30.9 | 442 | Citations (PDF) |
| 418 | A novel concentration-gradient Li[Ni0.83Co0.07Mn0.10]O2 cathode material for high-energy lithium-ion batteries | 7.3 | 138 | Citations (PDF) |
| 419 | Spherical core-shell Li[(Li0.05Mn0.95)0.8(Ni0.25Mn0.75)0.2]2O4 spinels as high performance cathodes for lithium batteries | 30.9 | 64 | Citations (PDF) |
| 420 | Increased Stability Toward Oxygen Reduction Products for Lithium-Air Batteries with Oligoether-Functionalized Silane Electrolytes | 3.1 | 171 | Citations (PDF) |
| 421 | Effect of Mn Content in Surface on the Electrochemical Properties of Core-Shell Structured Cathode Materials | 3.1 | 35 | Citations (PDF) |
| 422 | A lithium ion battery using nanostructured Sn–C anode, LiFePO4 cathode and polyethylene oxide-based electrolyte | 3.1 | 38 | Citations (PDF) |
| 423 | Effect of 1-butyl-1-methylpyrrolidinium hexafluorophosphate as a flame-retarding additive on the cycling performance and thermal properties of lithium-ion batteries | 5.3 | 32 | Citations (PDF) |
| 424 | Synthesis of silicon/carbon, multi-core/shell microspheres using solution polymerization for a high performance Li ion battery | 5.3 | 25 | Citations (PDF) |
| 425 | An Advanced Lithium Ion Battery Based on High Performance Electrode Materials | 15.0 | 398 | Citations (PDF) |
| 426 | Rechargeable lithium sulfide electrode for a polymer tin/sulfur lithium-ion battery | 7.9 | 146 | Citations (PDF) |
| 427 | Development of high power lithium-ion batteries: Layer Li[Ni0.4Co0.2Mn0.4]O2 and spinel Li[Li0.1Al0.05Mn1.85]O4 | 7.9 | 18 | Citations (PDF) |
| 428 | Improvement of electrochemical properties of Li1.1Al0.05Mn1.85O4 achieved by an AlF3 coating | 7.9 | 59 | Citations (PDF) |
| 429 | Nanostructured TiO<sub>2</sub> and Its Application in Lithium‐Ion Storage | 17.0 | 158 | Citations (PDF) |
| 430 | Micrometer‐Sized, Nanoporous, High‐Volumetric‐Capacity LiMn<sub>0.85</sub>Fe<sub>0.15</sub>PO<sub>4</sub> Cathode Material for Rechargeable Lithium‐Ion Batteries | 24.5 | 196 | Citations (PDF) |
| 431 | Effect of an organic additive on the cycling performance and thermal stability of lithium-ion cells assembled with carbon anode and LiNi1/3Co1/3Mn1/3O2 cathode | 7.9 | 53 | Citations (PDF) |
| 432 | AlF3-coated LiCoO2 and Li[Ni1/3Co1/3Mn1/3]O2 blend composite cathode for lithium ion batteries | 7.9 | 104 | Citations (PDF) |
| 433 | Effects of manganese and cobalt on the electrochemical and thermal properties of layered Li[Ni0.52Co0.16+Mn0.32−]O2 cathode materials | 7.9 | 28 | Citations (PDF) |
| 434 | Enhanced electrochemical performance of carbon–LiMn1−Fe PO4 nanocomposite cathode for lithium-ion batteries | 7.9 | 102 | Citations (PDF) |
| 435 | Ni3(PO4)2-coated Li[Ni0.8Co0.15Al0.05]O2 lithium battery electrode with improved cycling performance at 55 °C | 7.9 | 219 | Citations (PDF) |
| 436 | Micron-sized, carbon-coated Li4Ti5O12 as high power anode material for advanced lithium batteries | 7.9 | 123 | Citations (PDF) |
| 437 | High specific capacity and excellent stability of interface-controlled MWCNT based anodes in lithium ion battery | 0.1 | 0 | Citations (PDF) |
| 438 | Pitch Carbon-coated Lithium Sulfide Electrode for Advanced, Lithium-metal Free-sulfur Batteries | 0.0 | 5 | Citations (PDF) |
| 439 | High-Voltage Performance of Li[Ni[sub 0.55]Co[sub 0.15]Mn[sub 0.30]]O[sub 2] Positive Electrode Material for Rechargeable Li-Ion Batteries | 3.1 | 33 | Citations (PDF) |
| 440 | One-Pot Synthesis of Alkyl-Terminated Silicon Nanoparticles by Solution Reduction | 0.2 | 1 | Citations (PDF) |
| 441 | Anatase TiO2 spheres with high surface area and mesoporous structure via a hydrothermal process for dye-sensitized solar cells | 5.3 | 62 | Citations (PDF) |
| 442 | Synthesis and electrochemical performances of core-shell structured Li[(Ni1/3Co1/3Mn1/3)0.8(Ni1/2Mn1/2)0.2]O2 cathode material for lithium ion batteries | 7.9 | 48 | Citations (PDF) |
| 443 | Electrochemical behavior of Al in a non-aqueous alkyl carbonate solution containing LiBOB salt | 7.9 | 30 | Citations (PDF) |
| 444 | A Novel Cathode Material with a Concentration‐Gradient for High‐Energy and Safe Lithium‐Ion Batteries | 17.0 | 272 | Citations (PDF) |
| 445 | High‐Performance Carbon‐LiMnPO<sub>4</sub> Nanocomposite Cathode for Lithium Batteries | 17.0 | 318 | Citations (PDF) |
| 446 | Double Carbon Coating of LiFePO<sub>4</sub> as High Rate Electrode for Rechargeable Lithium Batteries | 24.5 | 383 | Citations (PDF) |
| 447 | Nanostructured Anode Material for High‐Power Battery System in Electric Vehicles | 24.5 | 386 | Citations (PDF) |
| 448 | Improved electrochemical properties of BiOF-coated 5V spinel Li[Ni0.5Mn1.5]O4 for rechargeable lithium batteries | 7.9 | 101 | Citations (PDF) |
| 449 | Surface modification of LiNi0.5Mn1.5O4 by ZrP2O7 and ZrO2 for lithium-ion batteries | 7.9 | 244 | Citations (PDF) |
| 450 | Spinel lithium manganese oxide synthesized under a pressurized oxygen atmosphere | 5.3 | 10 | Citations (PDF) |
| 451 | Polyvinylpyrrolidone-assisted synthesis of microscale C-LiFePO4 with high tap density as positive electrode materials for lithium batteries | 5.3 | 60 | Citations (PDF) |
| 452 | High-voltage performance of concentration-gradient Li[Ni0.67Co0.15Mn0.18]O2 cathode material for lithium-ion batteries | 5.3 | 102 | Citations (PDF) |
| 453 | Thermally Annealed Co[sub 2]MnAl Thin-Film Electrode for Lithium Secondary Batteries | 3.1 | 2 | Citations (PDF) |
| 454 | Effect of Manganese Content on the Electrochemical and Thermal Stabilities of Li[Ni[sub 0.58]Co[sub 0.28−x]Mn[sub 0.14+x]]O[sub 2] Cathode Materials for Lithium-Ion Batteries | 3.1 | 27 | Citations (PDF) |
| 455 | Nanostructured Lithium Nickel Manganese Oxides for Lithium-Ion Batteries | 3.1 | 82 | Citations (PDF) |
| 456 | High Capacity and Excellent Stability of Lithium Ion Battery Anode Using Interface-Controlled Binder-Free Multiwall Carbon Nanotubes Grown on Copper | 15.3 | 196 | Citations (PDF) |
| 457 | Role of surface coating on cathode materials for lithium-ion batteries | 7.3 | 640 | Citations (PDF) |
| 458 | Effect of AlF<sub>3</sub>Coating on Thermal Behavior of Chemically Delithiated Li<sub>0.35</sub>[Ni<sub>1/3</sub>Co<sub>1/3</sub>Mn<sub>1/3</sub>]O<sub>2</sub> | 3.1 | 103 | Citations (PDF) |
| 459 | PVA assisted growth of hydrophobic honeycomb network of CdS thin films | 6.0 | 10 | Citations (PDF) |
| 460 | The effects of calcination temperature on the electrochemical performance of LiMnPO4 prepared by ultrasonic spray pyrolysis | 6.0 | 52 | Citations (PDF) |
| 461 | High Temperature Performance of Surface-Treated Li[sub 1.1](Ni[sub 0.15]Co[sub 0.1]Mn[sub 0.55])O[sub 1.95] Layered Oxide | 3.1 | 70 | Citations (PDF) |
| 462 | Synthesis of Li<sub>4</sub>Mn<sub>5</sub>O<sub>12</sub>and its application to the non-aqueous hybrid capacitor | 2.6 | 3 | Citations (PDF) |
| 463 | Synthesis of Li2Mn3O7and Application to Hybrid Capacitor | 2.9 | 5 | Citations (PDF) |
| 464 | Synthesis of Defective-Structure Li<sub>4</sub>Mn<sub>5</sub>O<sub>12</sub>by Combustion Method and Its Application to Hybrid Capacitor | 0.3 | 3 | Citations (PDF) |
| 465 | Role of AlF[sub 3] Coating on LiCoO[sub 2] Particles during Cycling to Cutoff Voltage above 4.5 V | 3.1 | 77 | Citations (PDF) |
| 466 | Effects of Co doping on Li[Ni0.5CoxMn1.5−x]O4 spinel materials for 5V lithium secondary batteries via Co-precipitation | 7.9 | 58 | Citations (PDF) |
| 467 | Effect of protecting metal oxide (Co3O4) layer on electrochemical properties of spinel Li1.1Mn1.9O4 as a cathode material for lithium battery applications | 7.9 | 33 | Citations (PDF) |
| 468 | Electrochemical behavior of current collectors for lithium batteries in non-aqueous alkyl carbonate solution and surface analysis by ToF-SIMS | 5.3 | 136 | Citations (PDF) |
| 469 | Mesoporous TiO2 nano networks: Anode for high power lithium battery applications | 3.9 | 98 | Citations (PDF) |
| 470 | Improvement of electrochemical and thermal properties of Li[Ni0.8Co0.1Mn0.1]O2 positive electrode materials by multiple metal (Al, Mg) substitution | 5.3 | 198 | Citations (PDF) |
| 471 | Passivation behavior of Type 304 stainless steel in a non-aqueous alkyl carbonate solution containing LiPF6 salt | 5.3 | 36 | Citations (PDF) |
| 472 | Electrochemical characterization of Li2MnO3–Li[Ni1/3Co1/3Mn1/3]O2–LiNiO2 cathode synthesized via co-precipitation for lithium secondary batteries | 7.9 | 180 | Citations (PDF) |
| 473 | Electrochemical behaviour of Heusler alloy Co2MnSi for secondary lithium batteries | 7.9 | 14 | Citations (PDF) |
| 474 | Effect of carbon coating on thermal stability of natural graphite spheres used as anode materials in lithium-ion batteries | 7.9 | 73 | Citations (PDF) |
| 475 | Improvement of high voltage cycling performance and thermal stability of lithium–ion cells by use of a thiophene additive | 3.9 | 89 | Citations (PDF) |
| 476 | Improvement of High Voltage Cycling Performances of Li[Ni[sub 1/3]Co[sub 1/3]Mn[sub 1/3]]O[sub 2] at 55°C by a (NH[sub 4])[sub 3]AlF[sub 6] Coating | 2.3 | 38 | Citations (PDF) |
| 477 | Mesoporous Anatase TiO<sub>2</sub> with High Surface Area and Controllable Pore Size by F<sup>−</sup>-Ion Doping: Applications for High-Power Li-Ion Battery Anode | 3.1 | 115 | Citations (PDF) |
| 478 | Electrochemical characterization of Ti–Si and Ti–Si–Al alloy anodes for Li-ion batteries produced by mechanical ball milling | 6.0 | 61 | Citations (PDF) |
| 479 | LixNi0.25Mn0.75Oy (0.5 ≤x≤ 2, 2 ≤y≤ 2.75) compounds for high-energy lithium-ion batteries | 7.3 | 118 | Citations (PDF) |
| 480 | Dual functioned BiOF-coated Li[Li0.1Al0.05Mn1.85]O4 for lithium batteries | 7.3 | 72 | Citations (PDF) |
| 481 | Nanoporous Structured LiFePO[sub 4] with Spherical Microscale Particles Having High Volumetric Capacity for Lithium Batteries | 2.3 | 86 | Citations (PDF) |
| 482 | Development of LiNi[sub 0.5]Mn[sub 1.5]O[sub 4]/Li[sub 4]Ti[sub 5]O[sub 12] System with Long Cycle Life | 3.1 | 96 | Citations (PDF) |
| 483 | Electrochemical and thermal characterization of AlF3-coated Li[Ni0.8Co0.15Al0.05]O2 cathode in lithium-ion cells | 7.9 | 120 | Citations (PDF) |
| 484 | Optimization of microwave synthesis of Li[Ni0.4Co0.2Mn0.4]O2 as a positive electrode material for lithium batteries | 5.3 | 39 | Citations (PDF) |
| 485 | Particle size effect of Li[Ni0.5Mn0.5]O2 prepared by co-precipitation | 5.3 | 69 | Citations (PDF) |
| 486 | Improvement of structural and electrochemical properties of AlF3-coated Li[Ni1/3Co1/3Mn1/3]O2 cathode materials on high voltage region | 7.9 | 149 | Citations (PDF) |
| 487 | Physical and electrochemical properties of spherical Li1+x(Ni1/3Co1/3Mn1/3)1−xO2 cathode materials | 7.9 | 153 | Citations (PDF) |
| 488 | Cycling performance of lithium metal polymer cells assembled with ionic liquid and poly(3-methyl thiophene)/carbon nanotube composite cathode | 7.9 | 29 | Citations (PDF) |
| 489 | Synthesis and electrochemical properties of Ni doped titanate nanotubes for lithium ion storage | 6.7 | 11 | Citations (PDF) |
| 490 | Nanosized TiN–SBR hybrid coating of stainless steel as bipolar plates for polymer electrolyte membrane fuel cells | 5.3 | 27 | Citations (PDF) |
| 491 | Investigation of anode-supported SOFC with cobalt-containing cathode and GDC interlayer | 3.1 | 62 | Citations (PDF) |
| 492 | Combustion synthesized LiMnSnO4 cathode for lithium batteries | 3.9 | 18 | Citations (PDF) |
| 493 | Nanoparticle TiN-coated type 310S stainless steel as bipolar plates for polymer electrolyte membrane fuel cell | 3.9 | 71 | Citations (PDF) |
| 494 | Enhanced electrochemical performance of silicon-based anode material by using current collector with modified surface morphology | 5.3 | 69 | Citations (PDF) |
| 495 | Comparative study of Li[Ni1/3Co1/3Mn1/3]O2 cathode material synthesized via different synthetic routes for asymmetric electrochemical capacitor applications | 4.5 | 35 | Citations (PDF) |
| 496 | The Effect of Morphological Properties on the Electrochemical Behavior of High Tap Density C–LiFePO[sub 4] Prepared via Coprecipitation | 3.1 | 37 | Citations (PDF) |
| 497 | Improvement of Electrochemical Performance of Li[Ni<sub>0.8</sub>Co<sub>0.15</sub>Al<sub>0.05</sub>]O<sub>2</sub> Cathode Materials by AlF<sub>3</sub> coating at Various Temperatures | 3.9 | 66 | Citations (PDF) |
| 498 | Effects of Metal Ions on the Structural and Thermal Stabilities of Li[Ni[sub 1−x−y]Co[sub x]Mn[sub y]]O[sub 2] (x+y≤0.5) Studied by In Situ High Temperature XRD | 3.1 | 27 | Citations (PDF) |
| 499 | Improvement of the Electrochemical Properties of Li[Ni[sub 0.5]Mn[sub 0.5]]O[sub 2] by AlF[sub 3] Coating | 3.1 | 44 | Citations (PDF) |
| 500 | In Situ XAFS Study of the Effect of Dopants in Li[sub 1+x]Ni[sub (1−3x)∕2]Mn[sub (3+x)∕2]O[sub 4] (0≤x≤1∕3), a Li-Ion Battery Cathode Material | 3.1 | 13 | Citations (PDF) |
| 501 | Structural, Electrochemical, and Thermal Aspects of Li[(Ni[sub 0.5]Mn[sub 0.5])[sub 1−x]Co[sub x]]O[sub 2] (0≤x≤0.2) for High-Voltage Application of Lithium-Ion Secondary Batteries | 3.1 | 32 | Citations (PDF) |
| 502 | Electrochemical evaluation of La1 − x Ca x CoO3 cathode material for zinc air batteries application | 2.0 | 22 | Citations (PDF) |
| 503 | Improvement of Electrochemical Performances of Li[Ni[sub 0.8]Co[sub 0.1]Mn[sub 0.1]]O[sub 2] Cathode Materials by Fluorine Substitution | 3.1 | 154 | Citations (PDF) |
| 504 | Significant Improvement of Electrochemical Performance of AlF[sub 3]-Coated Li[Ni[sub 0.8]Co[sub 0.1]Mn[sub 0.1]]O[sub 2] Cathode Materials | 3.1 | 212 | Citations (PDF) |
| 505 | On the Safety of the Li[sub 4]Ti[sub 5]O[sub 12]∕LiMn[sub 2]O[sub 4] Lithium-Ion Battery System | 3.1 | 184 | Citations (PDF) |
| 506 | Structural Transformation of Li[Ni[sub 0.5−x]Co[sub 2x]Mn[sub 0.5−x]]O[sub 2] (2x≤0.1) Charged in High-Voltage Range (4.5 V) | 3.1 | 19 | Citations (PDF) |
| 507 | Characterization of Core-Shell Type Cathode Material in Li-ion Cells | 0.5 | 1 | Citations (PDF) |
| 508 | Microwave Synthesis of Spherical Li[Ni0.4Co0.2Mn0.4]O2Powders as a Positive Electrode Material for Lithium Batteries | 6.7 | 37 | Citations (PDF) |
| 509 | AlF[sub 3]-Coating to Improve High Voltage Cycling Performance of Li[Ni[sub 1∕3]Co[sub 1∕3]Mn[sub 1∕3]]O[sub 2] Cathode Materials for Lithium Secondary Batteries | 3.1 | 167 | Citations (PDF) |
| 510 | Comparison of Structural Changes in Fully Delithiated Li[sub x][Ni[sub 1∕3]Co[sub 1∕3]Mn[sub 1∕3]]O[sub 2] and Li[sub x][Ni[sub 0.33]Co[sub 0.33]Mn[sub 0.30]Mg[sub 0.04]]O[sub 1.96]F[sub 0.04] Cathodes (x=0) upon Thermal Annealing | 3.1 | 8 | Citations (PDF) |
| 511 | Structural and Electrochemical Properties of Layered Li[Ni[sub 1−2x]Co[sub x]Mn[sub x]]O[sub 2] (x=0.1–0.3) Positive Electrode Materials for Li-Ion Batteries | 3.1 | 202 | Citations (PDF) |
| 512 | Functionality of Oxide Coating for Li[Li0.05Ni0.4Co0.15Mn0.4]O2as Positive Electrode Materials for Lithium-Ion Secondary Batteries | 3.1 | 167 | Citations (PDF) |
| 513 | Isothermal calorimetry investigation of Li1+xMn2−yAlzO4 spinel | 5.3 | 57 | Citations (PDF) |
| 514 | Effect of AlF3 coating amount on high voltage cycling performance of LiCoO2 | 5.3 | 116 | Citations (PDF) |
| 515 | Co-precipitation synthesis of spherical Li1.05M0.05Mn1.9O4 (M=Ni, Mg, Al) spinel and its application for lithium secondary battery cathode | 5.3 | 52 | Citations (PDF) |
| 516 | Comparative study of different crystallographic structure of LiNi0.5Mn1.5O4−δ cathodes with wide operation voltage (2.0–5.0V) | 5.3 | 127 | Citations (PDF) |
| 517 | Effect of calcination temperature on morphology, crystallinity and electrochemical properties of nano-crystalline metal oxides (Co3O4, CuO, and NiO) prepared via ultrasonic spray pyrolysis | 7.9 | 214 | Citations (PDF) |
| 518 | Synthesis and electrochemical properties of spherical spinel Li1.05M0.05Mn1.9O4 (M=Mg and Al) as a cathode material for lithium-ion batteries by co-precipitation method | 7.9 | 19 | Citations (PDF) |
| 519 | Electrochemical stability of core–shell structure electrode for high voltage cycling as positive electrode for lithium ion batteries | 7.9 | 24 | Citations (PDF) |
| 520 | Co-synthesis of nano-sized LSM–YSZ composites with enhanced electrochemical property | 2.3 | 31 | Citations (PDF) |
| 521 | Electrochemical performance of Li4/3Ti5/3O4/Li1+x(Ni1/3Co1/3Mn1/3)1−xO2 cell for high power applications | 7.9 | 37 | Citations (PDF) |
| 522 | Synthesis and electrochemical properties of Li[Ni0.45Co0.1Mn0.45−xZrx]O2 (x=0, 0.02) via co-precipitation method | 7.9 | 32 | Citations (PDF) |
| 523 | Life prediction and reliability assessment of lithium secondary batteries | 7.9 | 69 | Citations (PDF) |
| 524 | Synthesis of Spherical Nano- to Microscale Core−Shell Particles Li[(Ni0.8Co0.1Mn0.1)1-x(Ni0.5Mn0.5)x]O2and Their Applications to Lithium Batteries | 6.7 | 131 | Citations (PDF) |
| 525 | Synthesis of Li[(Ni0.5Mn0.5)1-xLix]O2by Emulsion Drying Method and Impact of Excess Li on Structural and Electrochemical Properties | 6.7 | 87 | Citations (PDF) |
| 526 | Novel Core−Shell-Structured Li[(Ni0.8Co0.2)0.8(Ni0.5Mn0.5)0.2]O2via Coprecipitation as Positive Electrode Material for Lithium Secondary Batteries | 2.7 | 106 | Citations (PDF) |
| 527 | Ultrasonic spray pyrolysis of nano crystalline spinel LiMn2O4 showing good cycling performance in the 3V range | 5.3 | 28 | Citations (PDF) |
| 528 | Rapidly solidified Ti–Si alloys/carbon composites as anode for Li-ion batteries | 5.3 | 43 | Citations (PDF) |
| 529 | The roles and electrochemical characterizations of activated carbon in zinc air battery cathodes | 5.3 | 50 | Citations (PDF) |
| 530 | Significant improvement of high voltage cycling behavior AlF3-coated LiCoO2 cathode | 3.9 | 263 | Citations (PDF) |
| 531 | Synthesis of spherical Li[Ni(1/3−z)Co(1/3−z)Mn(1/3−z)Mgz]O2 as positive electrode material for lithium-ion battery | 5.3 | 94 | Citations (PDF) |
| 532 | Improvement of electrochemical properties of Li[Ni0.4Co0.2Mn(0.4−x)Mgx]O2−yFy cathode materials at high voltage region | 5.3 | 26 | Citations (PDF) |
| 533 | Relationship between glass network structure and conductivity of Li2O–B2O3–P2O5 solid electrolyte | 5.3 | 31 | Citations (PDF) |
| 534 | Improvement of cycling performance of Li1.1Mn1.9O4 at 60°C by NiO addition for Li-ion secondary batteries | 5.3 | 35 | Citations (PDF) |
| 535 | Improvement of electrochemical properties of LiNi0.5Mn1.5O4 spinel material by fluorine substitution | 7.9 | 110 | Citations (PDF) |
| 536 | Synthesis and electrochemical properties of Li[Ni0.8Co0.1Mn0.1]O2 and Li[Ni0.8Co0.2]O2 via co-precipitation | 7.9 | 265 | Citations (PDF) |
| 537 | Water activities of polymeric membrane/water systems in fuel cells | 7.9 | 7 | Citations (PDF) |
| 538 | Effect of sulfur and nickel doping on morphology and electrochemical performance of LiNi0.5Mn1.5O4−xSx spinel material in 3-V region | 7.9 | 80 | Citations (PDF) |
| 539 | Hydrothermal synthesis of nano-sized anatase TiO2 powders for lithium secondary anode materials | 7.9 | 57 | Citations (PDF) |
| 540 | Phase behaviors of solid polymer electrolytes/salt system in lithium secondary battery by group-contribution method: The pressure effect | 4.2 | 3 | Citations (PDF) |
| 541 | Synthesis and electrochemical properties of Li[Ni0.4Co0.2Mn(0.4−x)Mgx]O2−yFy via a carbonate co-precipitation | 2.7 | 5 | Citations (PDF) |
| 542 | Synthesis and characterization of spherical morphology [Ni0.4Co0.2Mn0.4]3O4 materials for lithium secondary batteries | 7.9 | 19 | Citations (PDF) |
| 543 | High capacity Li[Li0.2Ni0.2Mn0.6]O2 cathode materials via a carbonate co-precipitation method | 7.9 | 122 | Citations (PDF) |
| 544 | The effects of Na doping on performance of layered Li1.1−xNax[Ni0.2Co0.3Mn0.4]O2 materials for lithium secondary batteries | 4.5 | 44 | Citations (PDF) |
| 545 | Electrochemical Properties of Lithium-Rich Li[sub 1+x](Mn[sub 1∕3]Ni[sub 1∕3]Co[sub 1∕3])[sub 1−x]O[sub 2] at High Potential | 3.1 | 30 | Citations (PDF) |
| 546 | Improved Electrochemical Cycling Behavior of ZnO-Coated Li[sub 1.05]Al[sub 0.1]Mn[sub 1.85]O[sub 3.95]F[sub 0.05] Spinel at 55°C | 3.1 | 43 | Citations (PDF) |
| 547 | Microscale Core-Shell Structured Li[(Ni[sub 0.8]Co[sub 0.1]Mn[sub 0.1])[sub 0.8](Ni[sub 0.5]Mn[sub 0.5])[sub 0.2]]O[sub 2] as Positive Electrode Material for Lithium Batteries | 2.3 | 31 | Citations (PDF) |
| 548 | Ionic Conductivities of Solid Polymer Electrolyte/Salt Systems for Lithium Secondary Battery : Electrostatic Potential Contribution | 0.5 | 0 | Citations (PDF) |
| 549 | Improved electrochemical performance of Li-doped natural graphite anode for lithium secondary batteries | 7.9 | 27 | Citations (PDF) |
| 550 | Thermodynamic properties of direct methanol polymer electrolyte fuel cell | 7.9 | 5 | Citations (PDF) |
| 551 | Structural and electrochemical study of Li–Al–Mn–O–F spinel material for lithium secondary batteries | 7.9 | 44 | Citations (PDF) |
| 552 | Synthesis and structural characterization of layered Li[Ni1/3+xCo1/3Mn1/3−2xMox]O2 cathode materials by ultrasonic spray pyrolysis | 7.9 | 73 | Citations (PDF) |
| 553 | Effect of fluorine on the electrochemical properties of layered Li(Ni0.5Mn0.5)O2 cathode materials | 7.9 | 32 | Citations (PDF) |
| 554 | Ionic conductivities of solid polymer electrolyte/salt systems for lithium secondary battery | 4.2 | 16 | Citations (PDF) |
| 555 | Synthesis and improved electrochemical performance of Al (OH)3-coated Li[Ni1/3Mn1/3Co1/3]O2 cathode materials at elevated temperature | 5.3 | 86 | Citations (PDF) |
| 556 | The effect of Al(OH)3 coating on the Li[Li0.2Ni0.2Mn0.6]O2 cathode material for lithium secondary battery | 5.3 | 117 | Citations (PDF) |
| 557 | Hydrothermal synthesis of layered Li[Ni1/3Co1/3Mn1/3]O2 as positive electrode material for lithium secondary battery | 5.3 | 94 | Citations (PDF) |
| 558 | Effects of synthesis condition on LiNiMnO cathode material for prepared by ultrasonic spray pyrolysis method | 3.1 | 54 | Citations (PDF) |
| 559 | Synthesis of Li[NiCoMn]O cathode materials via a carbonate process | 3.1 | 32 | Citations (PDF) |
| 560 | Synthesis and electrochemical properties of layered LiNi1/2Mn1/2O2prepared by coprecipitation | 2.5 | 17 | Citations (PDF) |
| 561 | Electrochemical Properties for Solid Polymer Electrolyte/Salt Systems in Lithium Secondary Batteries | 3.1 | 6 | Citations (PDF) |
| 562 | LiNi[sub 0.5]Mn[sub 1.5]O[sub 4] Showing Reversible Phase Transition on 3 V Region | 2.3 | 44 | Citations (PDF) |
| 563 | Effect of Fluorine on the Electrochemical Properties of Layered Li[Ni[sub 0.43]Co[sub 0.22]Mn[sub 0.35]]O[sub 2] Cathode Materials via a Carbonate Process | 2.3 | 37 | Citations (PDF) |
| 564 | XAS Investigation of Inhomogeneous Metal-Oxygen Bond Covalency in Bulk and Surface for Charge Compensation in Li-Ion Battery Cathode Li[Ni[sub 1∕3]Co[sub 1∕3]Mn[sub 1∕3]]O[sub 2] Material | 3.1 | 116 | Citations (PDF) |
| 565 | In Situ Studies of Li[sub x]Mn[sub 2]O[sub 4] and Li[sub x]Al[sub 0.17]Mn[sub 1.83]O[sub 3.97]S[sub 0.03] Cathode by IMC | 3.1 | 49 | Citations (PDF) |
| 566 | Surface-Stabilized Amorphous Germanium Nanoparticles for Lithium-Storage Material | 2.7 | 118 | Citations (PDF) |
| 567 | Role of Alumina Coating on Li−Ni−Co−Mn−O Particles as Positive Electrode Material for Lithium-Ion Batteries | 6.7 | 529 | Citations (PDF) |
| 568 | Synthesis of Nanostructured Li[Ni1/3Co1/3Mn1/3]O2via a Modified Carbonate Process | 6.7 | 99 | Citations (PDF) |
| 569 | Synthesis and Characterization of Li[(Ni0.8Co0.1Mn0.1)0.8(Ni0.5Mn0.5)0.2]O2with the Microscale Core−Shell Structure as the Positive Electrode Material for Lithium Batteries | 15.0 | 466 | Citations (PDF) |
| 570 | Phase Transitions in Li[sub 1−δ]Ni[sub 0.5]Mn[sub 1.5]O[sub 4] during Cycling at 5 V | 2.3 | 119 | Citations (PDF) |
| 571 | Effect of Ti Substitution for Mn on the Structure of LiNi[sub 0.5]Mn[sub 1.5−x]Ti[sub x]O[sub 4] and Their Electrochemical Properties as Lithium Insertion Material | 3.1 | 114 | Citations (PDF) |
| 572 | Mo[sup 6+]-Doped Li[Ni[sub (0.5+x)]Mn[sub (1.5−2x)]Mo[sub x]]O[sub 4] Spinel Materials for 5 V Lithium Secondary Batteries Prepared by Ultrasonic Spray Pyrolysis | 2.3 | 28 | Citations (PDF) |
| 573 | Effect of Li-Doping on Electrochemical Performance of Natural Graphite Anode for Lithium Secondary Batteries | 3.1 | 8 | Citations (PDF) |
| 574 | Synthesis and electrochemical behavior of layered Li(Ni0.5−xCo2xMn0.5−x)O2 (x = 0 and 0.025) materials prepared by solid-state reaction method | 5.4 | 19 | Citations (PDF) |
| 575 | Molten salt synthesis of LiNi0.5Mn1.5O4 spinel for 5 V class cathode material of Li-ion secondary battery | 5.3 | 239 | Citations (PDF) |
| 576 | Synthesis and structural characterization of layered Li[Ni1/3Co1/3Mn1/3]O2 cathode materials by ultrasonic spray pyrolysis method | 5.3 | 215 | Citations (PDF) |
| 577 | Blended polymer electrolytes based on poly(lithium 4-styrene sulfonate) for the rechargeable lithium polymer batteries | 5.3 | 96 | Citations (PDF) |
| 578 | A novel layered Li [Li0.12NizMg0.32−zMn0.56]O2 cathode material for lithium-ion batteries | 5.3 | 26 | Citations (PDF) |
| 579 | Electrodeposition of nano-structured nickel–21% tungsten alloy and evaluation of oxygen reduction reaction in a 1% sodium hydroxide solution | 5.3 | 21 | Citations (PDF) |
| 580 | Synthetic optimization of Li[Ni1/3Co1/3Mn1/3]O2 via co-precipitation | 5.3 | 583 | Citations (PDF) |
| 581 | Structural and electrochemical properties of layered Li6Ni0.5Mn0.591?xCoxO2 positive materials synthesized by ultrasonic spray pyrolysis method | 3.1 | 104 | Citations (PDF) |
| 582 | Synthesis and electrochemical characterization of spinel Li[Li(1−x)/3CrxTi(5−2x)/3]O4 anode materials | 7.9 | 75 | Citations (PDF) |
| 583 | Polymer–polymer miscibility: generalized double lattice model | 4.2 | 4 | Citations (PDF) |
| 584 | Synthesis and structural changes of LixFeyOz material prepared by a solid-state method | 7.9 | 36 | Citations (PDF) |
| 585 | Synthesis and electrochemical properties of 5V spinel LiNi0.5Mn1.5O4 cathode materials prepared by ultrasonic spray pyrolysis method | 5.3 | 42 | Citations (PDF) |
| 586 | Synthesis and Electrochemical Properties of Li[Ni[sub 1/3]Co[sub 1/3]Mn[sub (1/3−x)]Mg[sub x]]O[sub 2−y]F[sub y] via Coprecipitation | 2.3 | 94 | Citations (PDF) |
| 587 | Comparative Study of LiNi0.5Mn1.5O4-δ and LiNi0.5Mn1.5O4 Cathodes Having Two Crystallographic Structures: Fd3̄m and P4332 | 6.7 | 750 | Citations (PDF) |
| 588 | Hydrothermal Synthesis of Layered Li[Ni0.5Mn0.5]O2as Lithium Intercalation Material | 1.1 | 10 | Citations (PDF) |
| 589 | Synthesis of Li[Ni1/3Co1/3Mn1/3]O2−zFzvia Coprecipitation | 1.1 | 21 | Citations (PDF) |
| 590 | Effects of Molybdenum Doping on the Layered Li[Ni0.5+xMn0.5−2xMox]O2Cathode Materials for Lithium Secondary Batteries | 1.1 | 18 | Citations (PDF) |
| 591 | Electrochemical properties of layered Li[Ni1/2Mn1/2]O2cathode material synthesised by ultrasonic spray pyrolysis | 2.5 | 7 | Citations (PDF) |
| 592 | Surface structural change of ZnO-coated LiNi0.5Mn1.5O4 spinel as 5 V cathode materials at elevated temperatures | 5.3 | 124 | Citations (PDF) |
| 593 | Synthesis and electrochemical characterization of orthorhombic LiMnO2 material | 5.3 | 50 | Citations (PDF) |
| 594 | Electrochemical properties and structural characterization of layered Li[Ni0.5Mn0.5]O2 cathode materials | 5.3 | 22 | Citations (PDF) |
| 595 | Synthesis and electrochemical behavior of Li[Li0.1Ni0.35−x/2CoxMn0.55−x/2]O2 cathode materials | 3.1 | 104 | Citations (PDF) |
| 596 | Electrochemical stability and conductivity enhancement of composite polymer electrolytes | 3.1 | 197 | Citations (PDF) |
| 597 | Synthesis and electrochemical properties of layered Li[Li0.15Ni(0.275−x/2)AlxMn(0.575−x/2)]O2 materials prepared by sol–gel method | 7.9 | 70 | Citations (PDF) |
| 598 | Electrochemical performance of Li[LixNi(1−3x)/2Mn(1+x)/2]O2 cathode materials synthesized by a sol–gel method | 7.9 | 63 | Citations (PDF) |
| 599 | Li(Ni1/3Co1/3Mn1/3)O2 as a suitable cathode for high power applications | 7.9 | 333 | Citations (PDF) |
| 600 | Synthesis and electrochemical properties of sulfur doped-LixMnO2−ySy materials for lithium secondary batteries | 3.9 | 19 | Citations (PDF) |
| 601 | The Effect of ZnO Coating on Electrochemical Cycling Behavior of Spinel LiMn[sub 2]O[sub 4] Cathode Materials at Elevated Temperature | 3.1 | 117 | Citations (PDF) |
| 602 | Electrochemical performance of layered Li[Li0.15Ni0.275–xMgxMn0.575]O2 cathode materials for lithium secondary batteries | 7.3 | 65 | Citations (PDF) |
| 603 | Synthesis and Electrochemical Properties of ZnO-Coated LiNi[sub 0.5]Mn[sub 1.5]O[sub 4] Spinel as 5 V Cathode Material for Lithium Secondary Batteries [Electrochemical and Solid-State Letters, 5, A99 (2002)] | 3.1 | 10 | Citations (PDF) |
| 604 | Synthesis and Electrochemical Properties of ZnO-Coated LiNi[sub 0.5]Mn[sub 1.5]O[sub 4] Spinel as 5 V Cathode Material for Lithium Secondary Batteries [Electrochemical and Solid-State Letters, 5, A99 (2002)] | 2.3 | 4 | Citations (PDF) |
| 605 | Synthesis and Electrochemical Characteristics of Li[sub 0.7][Ni[sub 1/6]Mn[sub 5/6]]O[sub 2] Cathode Materials | 3.1 | 2 | Citations (PDF) |
| 606 | Porous Polyacrylonitrile Membrane for Lithium-Ion Cells | 2.3 | 16 | Citations (PDF) |
| 607 | Preparation of Nano-Crystalline LiFe0.97Co0.03O1.95Cl0.05by Solid-State Method | 1.1 | 10 | Citations (PDF) |
| 608 | Structural and electrochemical characteristics of nano-structured Li0.53Na0.03MnO2manganese oxide prepared by the sol–gel method | 7.3 | 8 | Citations (PDF) |
| 609 | Synthesis and Electrochemical Properties of ZnO-Coated LiNi[sub 0.5]Mn[sub 1.5]O[sub 4] Spinel as 5 V Cathode Material for Lithium Secondary Batteries | 2.3 | 240 | Citations (PDF) |
| 610 | Cycling behavior of the oxysulfide LiAl0.18Mn1.82O3.97S0.03 cathode materials at elevated temperature | 2.5 | 7 | Citations (PDF) |
| 611 | Electrochemical properties of the oxysulfide lial0.18mn1.82o3.97s0.03 cathode materials at elevated temperature | 3.0 | 4 | Citations (PDF) |
| 612 | Electrochemical performance of nano-sized ZnO-coated LiNi0.5Mn1.5O4 spinel as 5 V materials at elevated temperatures | 3.9 | 265 | Citations (PDF) |
| 613 | Synthesis of nano-crystalline LiFeO2 material with advanced battery performance | 3.9 | 35 | Citations (PDF) |
| 614 | Preparation and characterization of nano-crystalline LiNi0.5Mn1.5O4 for 5 V cathode material by composite carbonate process | 3.9 | 152 | Citations (PDF) |
| 615 | Microstructure and cycling behavior of LiAl0.1Mn1.9O4 cathode for lithium secondary batteries at 3 V | 7.9 | 11 | Citations (PDF) |
| 616 | Cycling behavior of selenium-doped LiMn2O4 spinel cathode material at 3 V for lithium secondary batteries | 7.9 | 14 | Citations (PDF) |
| 617 | Layered Li(Ni0.5−xMn0.5−xM2x′)O2 (M′=Co, Al, Ti; x=0, 0.025) cathode materials for Li-ion rechargeable batteries | 7.9 | 216 | Citations (PDF) |
| 618 | Synthesis and electrochemical properties of Li[Li(1−2x)/3NixMn(2−x)/3]O2 as cathode materials for lithium secondary batteries | 7.9 | 98 | Citations (PDF) |
| 619 | Synthesis and electrochemical properties of lithium nickel oxysulfide (LiNiSyO2−y) material for lithium secondary batteries | 5.3 | 107 | Citations (PDF) |
| 620 | Synthesis and electrochemical characteristics of LiCrxNi0.5−xMn1.5O4 spinel as 5 V cathode materials for lithium secondary batteries | 7.9 | 57 | Citations (PDF) |
| 621 | Title is missing! | 2.5 | 0 | Citations (PDF) |
| 622 | Title is missing! | 2.0 | 12 | Citations (PDF) |
| 623 | Degradation mechanism of spinel LiAl0.2Mn1.8O4 cathode materials on high temperature cycling | 7.3 | 66 | Citations (PDF) |
| 624 | Structural Changes (Degradation) of Oxysulfide LiAl[sub 0.24]Mn[sub 1.76]O[sub 3.98]S[sub 0.02] Spinel on High-Temperature Cycling | 3.1 | 38 | Citations (PDF) |
| 625 | Peculiar Cycle Behavior of LiAl0.1Mn1.9O4Material in the 3 V Region | 1.1 | 1 | Citations (PDF) |
| 626 | Synthesis of Orthorhombic LiMnO2Material and Its Optimization | 1.1 | 4 | Citations (PDF) |
| 627 | Cycling behavior of oxysulfide spinel LiCr0.19Mn1.81O3.98S0.02 cathode material which shows no capacity loss in the 3-V region | 7.9 | 12 | Citations (PDF) |
| 628 | Electrochemical characterization of gel polymer electrolytes prepared with porous membranes | 7.9 | 71 | Citations (PDF) |
| 629 | Structural degradation mechanism of oxysulfide spinel LiAl 0.24Mn1.76O3.98S0.02 cathode materials on high temperature cycling | 3.9 | 25 | Citations (PDF) |
| 630 | Title is missing! 2001, 31, 1149-1153 | | 44 | Citations (PDF) |
| 631 | Synthesis and electrochemical characterization of oxysulfide spinel LiAl0.15Mn1.85O3.97S0.03 cathode materials for rechargeable batteries | 5.3 | 19 | Citations (PDF) |
| 632 | Electrochemical cyclability of oxysulfide spinel Li1.03Al0.2Mn1.8O3.96S0.04 material for lithium secondary batteries | 3.9 | 36 | Citations (PDF) |
| 633 | Degradation mechanisms in doped spinels of LiM0.05Mn1.95O4 (M=Li, B, Al, Co, and Ni) for Li secondary batteries | 7.9 | 159 | Citations (PDF) |
| 634 | Gel-coated membranes for lithium-ion polymer batteries | 3.1 | 66 | Citations (PDF) |
| 635 | Synthesis and electro-optical properties of electroluminescent polymers containing carbazole unit | 5.9 | 29 | Citations (PDF) |
| 636 | Synthesis and electrochemical characteristics of oxysulfide spinel material for lithium secondary batteries | 3.9 | 15 | Citations (PDF) |
| 637 | Synthesis and characterization of spinel LiMn2−xNixO4 for lithium/polymer battery applications | 7.9 | 82 | Citations (PDF) |
| 638 | Cycling behaviour of LiCoO2 cathode materials prepared by PAA-assisted sol–gel method for rechargeable lithium batteries | 7.9 | 29 | Citations (PDF) |
| 639 | Synthesis and characterization of LiNiO2 cathode material prepared by an adiphic acid-assisted solâgel method for lithium secondary batteries | 3.1 | 56 | Citations (PDF) |
| 640 | Synthesis and characterization of side chain liquid crystalline polymer with a polythiophene backbone | 5.9 | 13 | Citations (PDF) |
| 641 | Synthesis and electrochemical characterization of LiMn2O4 cathode materials for lithium polymer batteries | 3.0 | 5 | Citations (PDF) |
| 642 | Overcoming Jahn-Teller Distortion for Spinel Mn Phase | 2.3 | 100 | Citations (PDF) |
| 643 | Overcoming Jahn–Teller distortion of oxysulfide spinel materials for lithium secondary batteries | 7.3 | 28 | Citations (PDF) |
| 644 | Synthesis and cycling behavior of LiMn2O4 cathode materials prepared by glycine-assisted sol-gel method for lithium secondary batteries | 3.0 | 10 | Citations (PDF) |
| 645 | Synthesis of spinel LiMn2O4 cathode material prepared by an adipic acid-assisted solâgel method for lithium secondary batteries | 3.1 | 106 | Citations (PDF) |
| 646 | Effect of mixed solvent electrolytes on cycling performance of rechargeable Li/LiNi0.5Co0.5O2 cells with gel polymer electrolytes | 3.1 | 9 | Citations (PDF) |
| 647 | Effect of crystallinity on the electrochemical behaviour of spinel Li1.03Mn2O4 cathode materials | 3.1 | 33 | Citations (PDF) |
| 648 | Polymer Electrolytes Based on Acrylonitrile‐Methyl Methacrylate‐Styrene Terpolymers for Rechargeable Lithium‐Polymer Batteries | 3.1 | 31 | Citations (PDF) |
| 649 | Synthesis and electrochemical characteristics of spinel phase LiMn2O4-based cathode materials for lithium polymer batteries | 7.3 | 46 | Citations (PDF) |
| 650 | Synthesis of LiCo0.5Ni>0.5O2 powders by a sol–gel method | 7.3 | 27 | Citations (PDF) |
| 651 | Synthesis of Spinel LiMn2O4 by the Sol−Gel Method for a Cathode-Active Material in Lithium Secondary Batteries | 3.9 | 88 | Citations (PDF) |
| 652 | Synthesis of LiNiO<sub>2</sub>powders by a sol–gel method | 1.0 | 36 | Citations (PDF) |
| 653 | Title is missing! | 3.5 | 57 | Citations (PDF) |
| 654 | Synthesis of high purity 110 K phase in the Bi(Pb)-Sr-Ca-Cu-O superconductor by the sol-gel method | 3.0 | 2 | Citations (PDF) |
| 655 | Synthesis and electrochemical studies of spinel Li1.03Mn2O4 cathode materials prepared by a sol-gel method for lithium secondary batteries | 3.1 | 79 | Citations (PDF) |
| 656 | Preparation of Ultrafine YBa2Cu3O7-xSuperconductor Powders by the Poly(vinyl alcohol)-Assisted Sol−Gel Method | 3.9 | 22 | Citations (PDF) |
| 657 | Synthesis of ultrafine LiCoO2 powders by the sol-gel method | 3.5 | 102 | Citations (PDF) |
| 658 | Catalytic behavior of YBa2Cu3O7-x in the partial oxidation of methanol to formaldehyde | 3.0 | 5 | Citations (PDF) |
| 659 | Preparation of high purity 110 K phase in the Bi(Pb)-Sr-Ca-Cu-O superconductor using the modified citrate process | 0.9 | 32 | Citations (PDF) |
| 660 | Catalytic behavior of YBa2Cu3O7-x in the partial oxidation of ethanol to acetaldehyde | 2.1 | 8 | Citations (PDF) |
| 661 | Nano/Microstructured Silicon–Graphite Composite Anode for High-Energy-Density Li-Ion Battery | 15.3 | 260 | Citations (PDF) |
