about
Ternary metal fluorides as high-energy cathodes with low cycling hysteresisTailoring a fluorophosphate as a novel 4 V cathode for lithium-ion batteries.The structural and chemical origin of the oxygen redox activity in layered and cation-disordered Li-excess cathode materials.Galvanic replacement reactions in metal oxide nanocrystals.The Reaction Mechanism and Capacity Degradation Model in Lithium Insertion Organic Cathodes, Li2C6O6, Using Combined Experimental and First Principle Studies.Biologically inspired pteridine redox centres for rechargeable batteries.A comparative study on Na2MnPO4F and Li2MnPO4F for rechargeable battery cathodes.First-Principles Design of Hydrogen Dissociation Catalysts Based on Isoelectronic Metal Solid Solutions.Redox Cofactor from Biological Energy Transduction as Molecularly Tunable Energy-Storage CompoundToward a lithium-"air" battery: the effect of CO2 on the chemistry of a lithium-oxygen cellAb Initio Study of the Sodium Intercalation and Intermediate Phases in Na0.44MnO2 for Sodium-Ion BatteryElectrochemical performance and ex situ analysis of ZnMn2O4 nanowires as anode materials for lithium rechargeable batteriesEnergy storage in composites of a redox couple host and a lithium ion hostTailored Oxygen Framework of Li4Ti5O12 Nanorods for High-Power Li Ion BatteryUnderstanding the Degradation Mechanisms of LiNi0.5 Co0.2 Mn0.3 O2 Cathode Material in Lithium Ion BatteriesA New High-Energy Cathode for a Na-Ion Battery with Ultrahigh StabilityFlexible energy storage devices based on graphene paperSimple Preparation of High-Quality Graphene Flakes without Oxidation Using Potassium SaltsFabrication of FeF3 Nanoflowers on CNT Branches and Their Application to High Power Lithium Rechargeable BatteriesMn based olivine electrode material with high power and energyA disordered rock-salt Li-excess cathode material with high capacity and substantial oxygen redox activity: Li 1.25 Nb 0.25 Mn 0.5 O 2Molecular dynamics simulations of the diffusion and rotation of Pt nanoclusters supported on graphiteKinetic pathways of ionic transport in fast-charging lithium titanateMetal-oxygen decoordination stabilizes anion redox in Li-rich oxides
P50
Q35311801-2B055731-19EC-4032-B0BB-801816FA0073Q36296170-BC50C537-B683-45DA-B2D5-F9B86EF1446FQ40383609-05E24ABE-549F-43B2-903D-10880A29C50AQ45061177-DFC4DF47-60AD-404E-B0E8-EF3D873F4DE5Q46886013-283E85CB-56DD-418C-82C6-0FBF80C02671Q51038690-A2279373-A501-426D-98F1-126677C0355EQ53388863-18775950-38CD-4623-B184-8980C748033CQ53534811-5C7621DD-79CA-4A3F-B16B-4780DCD41DE3Q55034279-5AFD17E5-8F07-4BB5-B5D7-2B1A9B63D174Q57125511-8E994D19-C2D8-4B44-A5AE-3E9AFAC30331Q57611178-3451DC9F-34E4-4478-8A43-A39C063224F3Q57611209-783D7BB7-02FD-487A-B058-D104B860DDD4Q57957010-10B780F3-8D82-4876-B3BC-7AA76E25875BQ58023256-FFFE1E0B-956A-40A6-B838-AB3D84CEE932Q58023260-4482D8C0-5E2A-4D19-B809-D179652668D2Q58023262-009B87CF-C7F6-46D5-B44E-BB6E52B16CA7Q58023329-7B6F586F-8BC0-406A-AB6F-4E437175F79AQ58023349-07020337-1E37-4643-BC14-8B7A66E1B816Q58023357-674C0481-259F-4A52-B10B-521CC3B36FA2Q58023358-F1F67277-18D1-48C9-9ADF-C064E5F8DBC8Q59897377-31060488-168E-4DC8-95EA-7854832DE546Q83470146-BD81C060-2DC0-4320-988F-A7B9235825DCQ89930333-659C000E-F571-4B3B-81AC-4B5C89EF921EQ91341383-B1D536EF-7C68-4B78-B257-14D7FBE63579
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Dong-Hwa Seo
@ast
Dong-Hwa Seo
@en
Dong-Hwa Seo
@es
Dong-Hwa Seo
@nl
type
label
Dong-Hwa Seo
@ast
Dong-Hwa Seo
@en
Dong-Hwa Seo
@es
Dong-Hwa Seo
@nl
prefLabel
Dong-Hwa Seo
@ast
Dong-Hwa Seo
@en
Dong-Hwa Seo
@es
Dong-Hwa Seo
@nl
P108
P106
P108
P1153
25931852700
P31
P496
0000-0002-7200-7186