Graphene as a long-term metal oxidation barrier: worse than nothing.
about
Compact Shielding of Graphene Monolayer Leads to Extraordinary SERS-Active Substrate with Large-Area Uniformity and Long-Term Stability.Toxicity of graphene-family nanoparticles: a general review of the origins and mechanismsCatalyst Interface Engineering for Improved 2D Film Lift-Off and TransferConfined catalysis under two-dimensional materials.Graphene-protected copper and silver plasmonics.Superiority of Graphene over Polymer Coatings for Prevention of Microbially Induced Corrosion.Ultrahigh-mobility graphene devices from chemical vapor deposition on reusable copper.Long-Term Passivation of Strongly Interacting Metals with Single-Layer Graphene.Time Evolution of the Wettability of Supported Graphene under Ambient Air Exposure.Tailored CVD graphene coating as a transparent and flexible gas barrier.Roles of Oxygen and Hydrogen in Crystal Orientation Transition of Copper Foils for High-Quality Graphene Growth.Assessment and control of the impermeability of graphene for atomically thin membranes and barriers.Graphene: An Outstanding Multifunctional Coating for Conventional Materials.Surface chemistry and catalysis confined under two-dimensional materials.Real-time oxide evolution of copper protected by graphene and boron nitride barriersObserving graphene grow: catalyst-graphene interactions during scalable graphene growth on polycrystalline copper.Optical Relaxation Time Enhancement in Graphene-Passivated Metal Films.Durable Corrosion Resistance of Copper Due to Multi-Layer Graphene.Graphene-Based Materials for Biosensors: A Review.Reduced graphene oxide growth on 316L stainless steel for medical applications.Oxidation behavior of graphene-coated copper at intrinsic graphene defects of different origins.Evaluation of Graphene/WO3 and Graphene/CeO x Structures as Electrodes for Supercapacitor Applications.Greatly Enhanced Anticorrosion of Cu by Commensurate Graphene Coating.A cautionary note on graphene anti-corrosion coatings.Single Graphene Layer on Pt(111) Creates Confined Electrochemical Environment via Selective Ion Transport.Atomically Thin Hexagonal Boron Nitride Nanofilm for Cu Protection: The Importance of Film Perfection.Roll-to-Roll Green Transfer of CVD Graphene onto Plastic for a Transparent and Flexible Triboelectric Nanogenerator.Efficient anti-corrosive coating of cold-rolled steel in a seawater environment using an oil-based graphene oxide ink.The Structural Stability of Graphene Anticorrosion Coating Materials is Compromised at Low Potentials.The influence of intercalated oxygen on the properties of graphene on polycrystalline Cu under various environmental conditions.Quantitative optical mapping of two-dimensional materials.Atomically Thin Boron Nitride: Unique Properties and ApplicationsEvolution of the Raman spectrum of graphene grown on copper upon oxidation of the substrateSingle Graphene Layer on Pt(111) Creates Confined Electrochemical Environment via Selective Ion Transport
P2860
Q27305100-D2F672AC-6857-4B18-AD12-B7C47896B682Q28071613-12A50C0B-0EF4-47C6-965E-D59EEB4D7029Q28818640-9986F48F-B867-4949-BE8F-8E6D38075310Q33790819-E3B9941B-35EB-4A5F-B540-1D986F789F69Q33827233-834694C5-7DC0-458C-A34F-0C3284DB907CQ36039517-47D22D11-D3D5-4966-A702-2BF032206A33Q36284772-1F75F182-919F-406A-A585-A34036DE1D74Q36380999-8C4EB5AC-A1A5-47FC-AEEA-8AF89AC6E17FQ36581561-A46FC78C-EBD8-4912-8D78-AAA13E081880Q36785070-C435B73D-06EE-4D04-8362-651D76D93B5AQ37734526-B8EE80D7-8FE7-4F7C-ABCA-F741594F5947Q38671990-2D60270C-A2BD-4287-944F-E1F759AD1161Q38757184-BEC8E696-2DBA-4A53-854A-C57A8D1B04ADQ38976858-E57D7A68-248B-405B-8912-0610E3BF69DAQ40972512-53877EFD-8A7B-467C-BAC4-44BCC216F468Q41855186-B964F154-3BB8-4EDE-8C30-7246A9A667B2Q42401264-4AC04861-5034-401C-BCC2-21B7634291D8Q45341628-F73D5305-B7D2-4B93-9902-59DC9B0CA412Q46259316-FE297D57-C6E8-42E7-AE1F-A543966AB739Q46877052-8F412345-AEBF-4A2C-8DDE-57F1553A5FA9Q47155143-1141E182-9655-403B-AB1C-EC56DFB1FE7AQ47222935-22E986F5-2C7C-49EC-B463-7134D67DDFB5Q47228869-4D06AB06-0316-4F0D-A556-7DB18F84E4FBQ47711614-30A52EA2-3984-4E96-BFBA-5DD32336EF58Q48313376-17F0B5DD-729A-4C91-A20A-591F7D46BB90Q50214474-0D40DC0D-128B-4536-9E87-09C60A30EDA4Q50249716-FCC54B19-BFFA-493E-AFE9-1EA058C34527Q50448250-C7F23132-1853-42E6-B12B-0DE085ECDC7EQ50936242-6F35CE55-B8DE-45B7-A095-E2D56B1D7763Q52872805-E271A5D7-D7CA-4F1B-8E19-8676421ECB76Q55007864-CDC7DBA7-9484-4474-B63D-337B3954A192Q56038985-D2F1E416-0A99-4F03-8939-05E0270F439BQ57531173-459CD036-1E0A-48B5-B7A1-A7C4C9C866DCQ57737423-112BCEE9-436A-4401-B77C-0139B8B31D12
P2860
Graphene as a long-term metal oxidation barrier: worse than nothing.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
2013年论文
@zh
2013年论文
@zh-cn
name
Graphene as a long-term metal oxidation barrier: worse than nothing.
@en
Graphene as a long-term metal oxidation barrier: worse than nothing.
@nl
type
label
Graphene as a long-term metal oxidation barrier: worse than nothing.
@en
Graphene as a long-term metal oxidation barrier: worse than nothing.
@nl
prefLabel
Graphene as a long-term metal oxidation barrier: worse than nothing.
@en
Graphene as a long-term metal oxidation barrier: worse than nothing.
@nl
P2093
P356
P1433
P1476
Graphene as a long-term metal oxidation barrier: worse than nothing.
@en
P2093
Anna M Zaniewski
Maria Schriver
Will J Gannett
William Regan
P304
P356
10.1021/NN4014356
P407
P577
2013-06-11T00:00:00Z