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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
https://orcid.org/0000-0002-5531-1135
Email
Di.Hu
nottingham.edu
cn
h-index
1719
Scopus Citations
20
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
(54)
Supervised Work
(7)
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
Alloying
18%
Anode
36%
Anodic Dissolution
18%
Battery (Electrochemical Energy Engineering)
31%
Capacitance
48%
Carbon Dioxide
85%
Carbon Nanotube
77%
Carbon Steel
53%
Carburization
37%
Cathode
28%
Cerium Oxide
18%
Conducting Polymer
33%
Corrosion
21%
Corrosion Inhibitor
21%
Direct Ink Writing
23%
Electrochemical Reaction
51%
Electrodeposition
24%
Electrometallurgy
18%
Electron Transfer
26%
Film
25%
Flame Retardant
18%
Graphene
30%
Halide
18%
Ionic Liquid
18%
Lithium
21%
Lithium Ion
23%
Lithium Ion Battery
32%
Manganese Oxide
18%
Mechanical Stability
18%
Metal Oxide
46%
Metal Surface
18%
Morphology
18%
Nanoparticle
20%
Optical Property
18%
Oxidation Reaction
40%
Oxide Compound
46%
Photovoltaics
26%
Plating
18%
Polyaniline
37%
Polymer Composite
18%
Potassium
28%
Scanning Electron Microscopy
33%
Secondary Battery
29%
Supercapacitors
89%
Superhydrophobic
28%
Ti-6Al-4V
25%
Titanium
59%
Titanium Alloys
28%
Titanium Dioxide
46%
Transition Metal Oxide
28%
Keyphrases
Activated Carbon Electrode
18%
Amphiphilic Oligomers
18%
Cambridge
62%
Carbon Nanotubes
60%
Carbonate
24%
Carburisation
37%
Conducting Polymer
25%
Cu2ZnSnS4
28%
Direct Ink Writing
23%
Electrochemical Energy Storage
37%
Electrochemical Energy Storage Devices
23%
Electrochemical Metallization
22%
Electrochemical Reduction
29%
Electrodeposition
42%
Electrolysis
40%
Electrolyte
65%
FFC-Cambridge Process
37%
Graphene
22%
Hollow
24%
Hollow Spheres
28%
Interfacial Synthesis
18%
Lithium-ion Battery
28%
Mesoporous Manganese Dioxide
18%
Metal Oxide
26%
Metallization Process
22%
Mild Steel
43%
MnOx Nanoparticles
18%
Molten Carbonate Salt
24%
Molten Salt
100%
Myristoyl
18%
Near-net-shape
61%
Oxide Precursor
34%
Photovoltaic Devices
28%
Poly(2-oxazoline)
18%
Poly(3-hexylthiophene) (P3HT)
28%
Polyaniline (PANi)
28%
Pre-oxidation
20%
Rutile
71%
S235JR Steel
18%
Salt-assisted
24%
Spent Fuel
37%
Spray Coating
46%
Supercapacitor
33%
Supercapatteries
24%
Supercapattery
27%
Superhydrophobic
23%
Titanium Alloy
18%
Trimethylammonium Bromide
18%
Writing Process
23%
Zinc
19%
Engineering
Adsorption
9%
Alloy
18%
Carbon Dioxide Electroreduction
9%
Carbon Nanotube
12%
Carbon Paper
9%
Carburisation
18%
Closed Loop
18%
Current Collector
10%
Current Efficiency
20%
Cycling Stability
15%
Direct Reduction
18%
Electrochemical Capacitor
10%
Electrolysis Cell
9%
Electrolytic Cell
9%
Electrometallurgy
18%
Electron Beam Melting
18%
Energy Engineering
50%
Energy Storage
9%
Engineering Component
18%
Environmental Assessment
18%
Extraction Process
18%
Ffc Cambridge Process
18%
Heat Treatment
9%
Kroll Process
13%
Li-Metal Battery
12%
Lithium Metal Battery
12%
Max
18%
Melting Process
18%
Metal Extraction
18%
Metallic Component
18%
Metallizations
18%
Mild Steel
18%
Mixture Composition
9%
Molar Ratio
12%
Near Net Shape
65%
Nuclear Energy
18%
Photovoltaics
18%
Porosity
18%
Positive Electrode
12%
Processing Condition
9%
Rate Constant
9%
Reduction Process
18%
Single Source
9%
Situ Reduction
18%
Specific Surface Area
17%
Spent Fuels
37%
Structure Surface
9%
Supercapacitor
28%
Sustainable Production
18%
Ti-6al-4v
15%
