| Nome |
# |
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Current status and future perspectives of lithium metal batteries, file e309ade4-7479-3969-e053-3a05fe0a2c94
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535
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All solid-state lithium-sulfur battery using a glass-type P2S5-Li2S electrolyte: Benefits on anode kinetics, file e309ade4-1530-3969-e053-3a05fe0a2c94
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310
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Multiwalled Carbon Nanotubes Anode in Lithium-Ion Battery with LiCoO2, Li[Ni1/3Co1/3Mn1/3]O2, and LiFe1/4Mn1/2Co1/4PO4 Cathodes, file e309ade5-0cd9-3969-e053-3a05fe0a2c94
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254
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The lithium/air battery: Still an emerging system or a practical reality?, file e309ade3-afe2-3969-e053-3a05fe0a2c94
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219
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Glyme-based electrolytes for lithium metal batteries using insertion electrodes: An electrochemical study, file e309ade4-781b-3969-e053-3a05fe0a2c94
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194
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An Advanced Lithium-Ion Sulfur Battery for High Energy Storage, file e309ade3-cd48-3969-e053-3a05fe0a2c94
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142
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The role of synthesis pathway on the microstructural characteristics of sulfur-carbon composites: X-ray imaging and electrochemistry in lithium battery, file e309ade4-c83b-3969-e053-3a05fe0a2c94
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129
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A sodium-ion battery exploiting layered oxide cathode, graphite anode and glyme-based electrolyte, file e309ade3-d7b6-3969-e053-3a05fe0a2c94
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128
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Triglyme-based electrolyte for sodium-ion and sodium-sulfur batteries, file e309ade4-6adb-3969-e053-3a05fe0a2c94
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128
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Investigating high-performance sulfur-metal nanocomposites for lithium batteries, file e309ade4-c01f-3969-e053-3a05fe0a2c94
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128
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Lithium-Oxygen Battery Exploiting Highly Concentrated Glyme-Based Electrolytes, file e309ade4-4efe-3969-e053-3a05fe0a2c94
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109
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A long-life lithium ion sulfur battery exploiting high performance electrodes, file e309ade4-825d-3969-e053-3a05fe0a2c94
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106
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Lithium-ion batteries for sustainable energy storage: Recent advances towards new cell configurations, file e309ade3-f2b5-3969-e053-3a05fe0a2c94
|
94
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Polysulfide-containing Glyme-based Electrolytes for Lithium Sulfur Battery, file e309ade3-a382-3969-e053-3a05fe0a2c94
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92
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Alternative lithium-ion battery using biomass-derived carbons as environmentally sustainable anode, file 2fcfe6cf-ab65-4992-ac8b-33f9bb1a2372
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84
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A polymer lithium-oxygen battery, file e309ade4-a0c0-3969-e053-3a05fe0a2c94
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84
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A single layer of Fe3O4@TiO2 submicron spheres as a high-performance electrode for lithium-ion microbatteries, file e309ade4-781a-3969-e053-3a05fe0a2c94
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79
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Highly cyclable lithium-sulfur batteries with a dual-type sulfur cathode and a lithiated Si/SiOx nanosphere anode, file e309ade4-4ba8-3969-e053-3a05fe0a2c94
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74
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Toward high energy density cathode materials for sodium-ion batteries: investigating the beneficial effect of aluminum doping on the P2-type structure, file e309ade3-9f69-3969-e053-3a05fe0a2c94
|
70
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A lithium-ion sulfur battery using a polymer, polysulfide-added membrane, file e309ade4-ac7c-3969-e053-3a05fe0a2c94
|
48
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Towards a High-Performance Lithium-Metal Battery with Glyme Solution and an Olivine Cathode, file e309ade4-bc70-3969-e053-3a05fe0a2c94
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46
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A comparative study of layered transition metal oxide cathodes for application in sodium-ion battery, file e309ade3-d536-3969-e053-3a05fe0a2c94
|
45
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Porous Cr2O3@C composite derived from metal organic framework in efficient semi-liquid lithium-sulfur battery, file bcf03adb-2bcb-49b2-95df-467812202405
|
44
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Exceptional long-life performance of lithium-ion batteries using ionic liquid-based electrolytes, file e309ade3-f80d-3969-e053-3a05fe0a2c94
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43
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A simple approach for making a viable, safe, and high-performances lithium-sulfur battery, file e309ade4-b40a-3969-e053-3a05fe0a2c94
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33
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Electrochemical behavior of nanostructured NiO@C anode in a lithium-ion battery using LiNi⅓Co⅓Mn⅓O2 cathode, file e309ade4-8d09-3969-e053-3a05fe0a2c94
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31
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X-ray Nano-computed Tomography of Electrochemical Conversion in Lithium-ion Battery, file e309ade4-8cd1-3969-e053-3a05fe0a2c94
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30
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Investigation of Mn and Fe Substitution Effects on the Characteristics of High-Voltage LiCo1- xMxPO4 (x = 0.1, 0.4) Cathodes Prepared by Sol-gel Route, file e309ade4-a992-3969-e053-3a05fe0a2c94
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27
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Degradation of Layered Oxide Cathode in a Sodium Battery: A Detailed Investigation by X-Ray Tomography at the Nanoscale, file 06c6ee73-7d96-455b-b5d1-5f2e5ab0b1f9
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25
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Novel Lithium-Sulfur Polymer Battery Operating at Moderate Temperature, file cb8769a7-d0ff-4678-8fd0-eddb29be4860
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22
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A Lithium-Ion Battery using a 3 D-Array Nanostructured Graphene–Sulfur Cathode and a Silicon Oxide-Based Anode, file e309ade4-ca99-3969-e053-3a05fe0a2c94
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20
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The Role of Current Collector in Enabling the High Performance of Li/S Battery, file e309ade5-0346-3969-e053-3a05fe0a2c94
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19
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Lithium-Metal Batteries Using Sustainable Electrolyte Media and Various Cathode Chemistries, file 8fde1f41-451f-4563-bff8-325e9e1508ff
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14
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Insight on the Enhanced Reversibility of a Multimetal Layered Oxide for Sodium-Ion Battery, file e309ade4-e5dc-3969-e053-3a05fe0a2c94
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14
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Synthesis of a High-Capacity α-Fe2O3@C Conversion Anode and a High-Voltage LiNi0.5Mn1.5O4Spinel Cathode and Their Combination in a Li-Ion Battery, file 4dd94f8a-eabb-4bc2-9dd0-4d9ab6642fbe
|
9
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Towards a High-Performance Lithium-Metal Battery with Glyme Solution and an Olivine Cathode, file e309ade4-bc71-3969-e053-3a05fe0a2c94
|
8
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A Stable High-Capacity Lithium-Ion Battery Using a Biomass-Derived Sulfur-Carbon Cathode and Lithiated Silicon Anode, file 079cf940-412e-48f2-ab1e-d6e0d59aab69
|
7
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High capacity semi-liquid lithium sulfur cells with enhanced reversibility for application in new-generation energy storage systems, file e309ade4-b7d5-3969-e053-3a05fe0a2c94
|
6
|
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Glyme-based electrolytes: Suitable solutions for next-generation lithium batteries, file 70352e56-07d6-44d0-84cd-79e9defd4efd
|
4
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A Comparative Study of Layered Transition Metal Oxide Cathodes for Application in Sodium-Ion Battery, file e309ade4-2432-3969-e053-3a05fe0a2c94
|
3
|
|
A New CuO-Fe2 O3 -Mesocarbon Microbeads Conversion Anode in a High-Performance Lithium-Ion Battery with a Li1.35 Ni0.48 Fe0.1 Mn1.72 O4 Spinel Cathode, file e309ade2-b7c7-3969-e053-3a05fe0a2c94
|
2
|
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Toward high energy density cathode materials for sodium-ion batteries: investigating the beneficial effect of aluminum doping on the P2-type structure, file e309ade3-a949-3969-e053-3a05fe0a2c94
|
2
|
|
The lithium/air battery: Still an emerging system or a practical reality?, file e309ade3-c778-3969-e053-3a05fe0a2c94
|
2
|
|
Highly cyclable lithium-sulfur batteries with a dual-type sulfur cathode and a lithiated Si/SiOx nanosphere anode, file e309ade4-1532-3969-e053-3a05fe0a2c94
|
2
|
|
null, file e309ade4-a33a-3969-e053-3a05fe0a2c94
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2
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Lithium sulfur battery exploiting material design and electrolyte chemistry: 3D graphene framework and diglyme solution, file e309ade4-cafc-3969-e053-3a05fe0a2c94
|
2
|
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Transition metal oxide-carbon composites as conversion anodes for sodium-ion battery, file e309ade4-d453-3969-e053-3a05fe0a2c94
|
2
|
|
Synthesis and Characterization of a LiFe0.6Mn0.4PO4 Olivine Cathode for Application in a New Lithium Polymer Battery, file a46b086c-3a7d-4bcc-b967-7efde8d02258
|
1
|
|
Lithium-ion batteries for sustainable energy storage: Recent advances towards new cell configurations, file e309ade3-bd8b-3969-e053-3a05fe0a2c94
|
1
|
|
A comparative study of layered transition metal oxide cathodes for application in sodium-ion battery, file e309ade3-d535-3969-e053-3a05fe0a2c94
|
1
|
|
Lithium-ion batteries for sustainable energy storage: Recent advances towards new cell configurations, file e309ade3-f2b4-3969-e053-3a05fe0a2c94
|
1
|
|
An Advanced Lithium-Ion Sulfur Battery for High Energy Storage, file e309ade3-fcaf-3969-e053-3a05fe0a2c94
|
1
|
|
Polysulfide-containing Glyme-based Electrolytes for Lithium Sulfur Battery, file e309ade3-fcb1-3969-e053-3a05fe0a2c94
|
1
|
|
null, file e309ade4-0614-3969-e053-3a05fe0a2c94
|
1
|
|
High capacity semi-liquid lithium sulfur cells with enhanced reversibility for application in new-generation energy storage systems, file e309ade4-6d95-3969-e053-3a05fe0a2c94
|
1
|
|
A Long-Life Lithium Ion Battery with Enhanced Electrode/Electrolyte Interface by Using an Ionic Liquid Solution, file e309ade4-7314-3969-e053-3a05fe0a2c94
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1
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Enhanced Lithium Oxygen Battery Using a Glyme Electrolyte and Carbon Nanotubes, file e309ade4-744c-3969-e053-3a05fe0a2c94
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1
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A new Sn-C/LiFe0.1Co0.9PO4 full lithium-ion cell with ionic liquid-based electrolyte, file e309ade4-8c90-3969-e053-3a05fe0a2c94
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1
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Lithium Transport Properties in LiMn1-alpha Fe alpha PO4 Olivine Cathodes, file e309ade4-a4d6-3969-e053-3a05fe0a2c94
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1
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Porous Cr2O3@C composite derived from metal organic framework in efficient semi-liquid lithium-sulfur battery, file e309ade4-a4e7-3969-e053-3a05fe0a2c94
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1
|
|
A Lithium-Ion Battery using a 3 D-Array Nanostructured Graphene–Sulfur Cathode and a Silicon Oxide-Based Anode, file e309ade4-a682-3969-e053-3a05fe0a2c94
|
1
|
|
Novel configuration of poly(vinylidenedifluoride)-based gel polymer electrolyte for application in lithium-ion batteries, file e309ade4-ac79-3969-e053-3a05fe0a2c94
|
1
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Characteristics of an ionic liquid electrolyte for sodium-ion batteries, file e309ade4-ace4-3969-e053-3a05fe0a2c94
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1
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Electrochemical features of LiMnPO4 olivine prepared by sol-gel pathway, file e309ade4-bd8e-3969-e053-3a05fe0a2c94
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1
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|
Investigation of Mn and Fe Substitution Effects on the Characteristics of High-Voltage LiCo1- xMxPO4 (x = 0.1, 0.4) Cathodes Prepared by Sol-gel Route, file e309ade4-c1d0-3969-e053-3a05fe0a2c94
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1
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A QuaternaryPoly(ethylene carbonate)-Lithium Bis(trifluoromethanesulfonyl)imide-Ionic Liquid-Silica Fiber Composite Polymer Electrolyte for Lithium Batteries, file e309ade4-d455-3969-e053-3a05fe0a2c94
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1
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Rechargeable lithium battery using non-flammable electrolyte based on tetraethylene glycol dimethyl ether and olivine cathodes, file e309ade4-d458-3969-e053-3a05fe0a2c94
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1
|
|
A simple approach for making a viable, safe, and high-performances lithium-sulfur battery, file e309ade4-d532-3969-e053-3a05fe0a2c94
|
1
|
|
Multiwalled Carbon Nanotubes Anode in Lithium-Ion Battery with LiCoO2, Li[Ni1/3Co1/3Mn1/3]O2, and LiFe1/4Mn1/2Co1/4PO4 Cathodes, file e309ade5-0cda-3969-e053-3a05fe0a2c94
|
1
|
| Totale |
3.493 |