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Dr Di Hu
Associate Professor in Environmental Engineering
Department of Chemical and Environmental Engineering
Zhejiang Aviation Electrification Technology Engineering Research Center
Advanced Energy and Environmental Materials & Technologies Research Group
Email
Di.Hu
nottingham.edu
cn
h-index
1638
Citations
19
h-index
Calculated based on number of publications stored in Pure and citations from Scopus
2007
2025
Research activity per year
Overview
Fingerprint
Network
Projects
(5)
Research output
(50)
Supervised Work
(6)
Fingerprint
Dive into the research topics where Di Hu is active. These topic labels come from the works of this person. Together they form a unique fingerprint.
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Weight
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Material Science
Supercapacitors
97%
Carbon Nanotube
90%
Carbon Dioxide
69%
Titanium
69%
Electrochemical Reaction
61%
Capacitance
56%
Titanium Dioxide
56%
Carbon Steel
52%
Metal Oxide
50%
Oxidation Reaction
49%
Carburization
45%
Potassium
45%
Conducting Polymer
40%
Battery (Electrochemical Energy Engineering)
38%
Oxide Compound
38%
Electron Transfer
36%
Titanium Alloys
33%
Graphene
33%
Scanning Electron Microscopy
33%
Photovoltaics
31%
Film
30%
Cathode
30%
Ti-6Al-4V
30%
Electrodeposition
30%
Polyaniline
28%
Superhydrophobic
28%
Lithium Ion Battery
28%
Lithium
25%
Nanoparticle
24%
Secondary Battery
24%
Anode
22%
Morphology
22%
Transition Metal Oxide
22%
Optical Property
22%
Electrometallurgy
22%
Sodium Ion Battery
22%
Redox Flow Battery
22%
Corrosion Inhibitor
22%
Flame Retardant
22%
Manganese Oxide
22%
Polymer Composite
22%
Cerium Oxide
22%
Mechanical Stability
22%
Alloying
22%
Metal Surface
22%
Anodic Dissolution
22%
Halide
22%
Plating
22%
Porous Carbon
22%
Electrochemical Double Layer
22%
Keyphrases
Molten Salt
100%
Rutile
82%
Cambridge
75%
Near-net-shape
60%
Carbon Nanotubes
52%
Electrodeposition
50%
Electrolyte
47%
Spray Coating
45%
Spent Fuel
45%
Supercapacitor
43%
FFC-Cambridge Process
42%
Electrolysis
39%
Oxide Precursor
38%
Electrochemical Reduction
35%
Electrochemical Energy Storage
33%
Carburisation
33%
Poly(3-hexylthiophene) (P3HT)
33%
Supercapattery
32%
Metal Oxide
32%
Mild Steel
30%
Salt-assisted
30%
Superhydrophobic
28%
Titanium Alloy
28%
Conducting Polymer
26%
Carbonate
26%
Molten Carbonate Salt
26%
Hollow
26%
Supercapatteries
26%
Pre-oxidation
24%
Graphene
24%
Zinc
24%
Non-conducting Polymer
22%
3D Electrodes
22%
Electrode Structure
22%
Three-dimensional Electrode
22%
Optical Properties
22%
Ethyl Xanthate
22%
Graded Interface
22%
Electrometallurgy
22%
Energy Cycle
22%
Nuclear Energy
22%
Sustainable Reduction
22%
Lithium-ion Battery
22%
Electron Beam Melting Process
22%
Rapid Manufacturing
22%
Rambutan-like
22%
Capacitance
22%
Electrochemical Properties
22%
Functionalized Carbon Nanotubes
22%
Carbon Dioxide Utilization
22%
Engineering
Near Net Shape
67%
Energy Engineering
49%
Spent Fuels
45%
Li-Metal Battery
26%
Reduction Process
22%
Metallic Component
22%
Electrometallurgy
22%
Metal Extraction
22%
Situ Reduction
22%
Nuclear Energy
22%
Closed Loop
22%
Metallizations
22%
Melting Process
22%
Supercapacitor
22%
Carburisation
22%
Mild Steel
22%
Alloy
22%
Engineering Component
22%
Ffc Cambridge Process
22%
Max
22%
Extraction Process
22%
Sustainable Production
22%
Direct Reduction
22%
Electrochemical Double Layer Capacitor
22%
Carbonization
22%
Porosity
22%
Ti-6al-4v
18%
Specific Surface Area
18%
Carbon Nanotube
18%
Lithium Metal Battery
18%
Electrochemical Capacitor
15%
Porous Structure
15%
Current Efficiency
15%
Kroll Process
13%
Current Collector
12%
Energy Storage
11%
Mixture Composition
11%
Electron Beam Melting
11%
Adsorption
11%
Photovoltaics
11%
Graphene
11%
Environmental Assessment
11%
Batch Process
11%
Situ Formation
11%
Reduction Mechanism
11%
Electroreduction
11%
Composite Coating
11%
Carbon Dioxide Electroreduction
11%
Carbon Paper
11%
Single Source
11%
