Enhancing the Energy Storage Capabilities of Ti₃C₂T_x MXene Electrodes by Atomic Surface Reduction

Keyphrases

• Atomic Surface Reduction 100%
• Surface Functionalization 100%
• Ti3C2Tx MXene 100%
• Energy Storage Capability 100%
• MXene Electrode 100%
• Reduction Method 66%
• Modified Surface 66%
• MXene-based Composites 66%
• Electronic Properties 33%
• Li-ion 33%
• Electrochemical Performance 33%
• Electrolyte Solution 33%
• Reactor 33%
• Cycling Stability 33%
• Na-ion 33%
• Electrochemical Properties 33%
• X-ray Photoelectron Spectroscopy 33%
• Solution Phase 33%
• Aqueous Electrolyte 33%
• Superior Rate Capability 33%
• Trimethylaluminum 33%
• 2D Materials 33%
• Atomic Layer Deposition 33%
• Structural Degradation 33%
• Large Classes 33%
• Improved Electrochemical Performance 33%
• Organic Electrolyte 33%
• Physical-chemical Properties 33%
• Interlayer Spacing 33%
• Thick Layer 33%
• Chemical Nature 33%
• Nitrides 33%
• Nuclear Magnetic Resonance Technique 33%
• Surface Termination 33%
• Transition Metal Carbides 33%
• MXene Film 33%
• Neutral Aqueous Electrolyte 33%
• Modified MXene 33%
• Acidic Aqueous Electrolytes 33%
• MXene Ti3C2Tx 33%
• Carbonitride 33%
• Physical Electronics 33%

Engineering

• MXene 100%
• Energy Storage 100%
• Modified Surface 60%
• Surface Functionalisation 60%
• Reduction Process 20%
• Rate Capability 20%
• Ray Photoelectron Spectroscopy 20%
• Thick Layer 20%
• Cycling Stability 20%
• 2D Material 20%
• Carbonitrides 20%
• Atomic Layer Deposition 20%
• Nitride 20%
• Nuclear Magnetic Resonance 20%
• Interlayer 20%
• Surface Termination 20%

Material Science

• MXene 100%
• Titanium Carbide 100%
• Surface Functionalization 60%
• Film 20%
• Electronic Property 20%
• Nuclear Magnetic Resonance 20%
• Electrochemical Property 20%
• X-Ray Photoelectron Spectroscopy 20%
• Physical Property 20%
• Lithium Ion 20%
• Sodium Ion 20%
• Chemical Property 20%
• Nitride Compound 20%
• Aluminum 20%
• Two-Dimensional Material 20%
• Carbon Nitride 20%
• Transition Metal Carbide 20%