Green Energy Harvesting
Materials for Hydrogen Generation and Carbon Dioxide Reduction
1st Edition
Published on 6. October 2022
304 pages
978-1-119-77607-9 (ISBN)
Description
Comprehensive resource summarizing current approaches to generating hydrogen from water and reducing CO2 into various hydrocarbons
Green Energy Harvesting: Materials for Hydrogen Generation and Carbon Dioxide Reduction provides an in-depth treatment of the subject by exploring the fundamentals required for the selection of the materials, their synthesis methods, and possible ways to modify them for higher efficiency and enhanced stability. The prospects of adopting these sustainable solutions at a commercial level are summarized. Special emphasis is given to the figure-of-merits for currently developed systems for hydrogen generation and CO2 reduction and to an assessment of available materials in terms of efficacy and efficiency.
Green Energy Harvesting also includes information on:
* Renewable energy in general, including the role of renewable hydrogen and hydrocarbon fuels, and possible renewable energy sources
* A fundamental understanding hydrogen generation and CO2 reduction
* Device development and deployment status for commercial usage and applications of H2 and hydrocarbon fuels in various sectors
* Electrocatalysts, 2D materials, and hybrid materials for CO2 reduction and H2 generation
Green Energy Harvesting is a highly useful guide for both novice and experienced researchers involved in renewable energy and carbon dioxide utilization that explains the current state of the field and discusses future perspectives.
Green Energy Harvesting: Materials for Hydrogen Generation and Carbon Dioxide Reduction provides an in-depth treatment of the subject by exploring the fundamentals required for the selection of the materials, their synthesis methods, and possible ways to modify them for higher efficiency and enhanced stability. The prospects of adopting these sustainable solutions at a commercial level are summarized. Special emphasis is given to the figure-of-merits for currently developed systems for hydrogen generation and CO2 reduction and to an assessment of available materials in terms of efficacy and efficiency.
Green Energy Harvesting also includes information on:
* Renewable energy in general, including the role of renewable hydrogen and hydrocarbon fuels, and possible renewable energy sources
* A fundamental understanding hydrogen generation and CO2 reduction
* Device development and deployment status for commercial usage and applications of H2 and hydrocarbon fuels in various sectors
* Electrocatalysts, 2D materials, and hybrid materials for CO2 reduction and H2 generation
Green Energy Harvesting is a highly useful guide for both novice and experienced researchers involved in renewable energy and carbon dioxide utilization that explains the current state of the field and discusses future perspectives.
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Green Energy Harvesting: Materials for Hydrogen Ge neration and Carbon Dioxide Reduction
Materials for Hydrogen Generation and Carbon Dioxide Reduction
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12/2022
1st Edition
Wiley-Blackwell
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10/2022
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Person
Pooja Devi is a senior scientist at CSIR-CSIO, Chandigarh. She has a Ph.D. in Engineering from the AcSIR, New Delhi, an M. Tech. in Nanotechnology from IIT Roorkee, and a B. Tech in Biotechnology from Kurukshetra University.
Content
Renewable energy: Introduction, Current Status and Future Prospects
Hydrogen and Hydrocarbons as Fuel
Possible ways for H2 Generation
Fundamental Understanding and Figure of Merits for H2 Production and CO2 Reduction
Single Atom Catalysts for Hydrogen Production from Chemical Hydrogen Storage Materials
Metal-Organic Framework Based Electrocatalyst for Electrochemical Hydrogen Generation
2D-Materials for CO2 Reduction and H2 Generation
Hybrid Materials for CO2 Reduction and H2 Generation
Possible Ways for CO2 Reduction Into Hydrocarbons
Mxenes Hybrid for H2 Generation and CO2 Reduction
Transition Metal Oxides, Phosphides, Sulphides and Selenides for H2 Generation
Device Development and Deployment Status for H2 Production and CO2 Utilization
Abbreviations
- AB
- ammonia borane
- ABPE
- applied bias photon to current efficiency
- ac
- aberration-corrected
- AC
- activated carbon
- AEL
- alkaline electrolysis
- AEM
- alkaline exchange membrane
- AFC
- alkaline fuel cell
- Ag
- silver
- Al
- aluminum
- ALD
- atomic layer deposition
- APCE
- absorbed photon-to-current efficiency
- Au
- gold
- B
- boron
- BASF
- Baden Aniline and Soda Factory
- BC7N
- borocarbonitride
- BDC
- benzenedicarboxylic acid
- BHT
- benzene-1,2,3,4,5,6-hexathiol
- C3N4
- carbon nitride
- C
- carbon
- CA
- California
- CB
- conduction band
- CBE
- conduction band edge
- Cdl
- double layer capacitance
- CdS
- cadmium sulfide
- CH4
- methane
- CNT
- carbon nanotube
- Co
- cobalt
- CO
- carbon monoxide
- CO2
- carbon dioxide
- COD
- Chemical Oxygen Demand
- COOH
- carboxyl intermediate
- CoPC
- Co phthalocyanine
- CoPS
- Co-phosphosulphides
- CoP|S
- Co-phosphosulfate nanoparticles
- CO2RR
- CO2 reduction reaction
- COVID-19
- Coronavirus disease 2019
- CS
- catalytic selectivity
- Cs
- specific capacitance
- CTF
- covalent triazine framework
- Cuf
- copper foam
- CUMS
- coordinatively unsaturated metal sites
- CV
- cyclic voltammetry
- CVD
- chemical vapor deposition
- 1D
- one-dimensional
- 2D
- two-dimensional
- 3D
- three-dimensional
- DBD
- dielectric barrier discharge
- DFT
- density functional theory
- DMSO
- dimethyl sulfoxide
- DOE
- Department of Energy
- DOS
- density of states
- DRIFTS
- CO-diffuse reflectance infrared Fourier transform spectroscopy
- DTM
- double transition-metal
- EC
- electrocatalyst
- EC
- electrochemical
- ECSA
- electrochemical active surface area
- EELS
- electron energy-loss spectroscopy
- EF
- energy efficiency
- EG
- ethylene glycol
- EHvac
- H-vacancy energy
- EIA
- Energy Information Administration
- EIS
- electrochemical impedance spectroscopy
- ENE-FARM
- energy and farm
- EV
- electrovolts
- EXAFS
- extended X-ray absorption fine structure
- EY
- Ernst & Young Global Ltd
- FA
- formic acid
- fcc
- face-centred cubic
- FCH JU
- Fuel Cells and H2 Joint Undertaking
- FE
- faradic efficiency
- Fe
- iron
- FeOx
- iron oxide
- FTO
- conductive surface
- ?G
- Gibbs's free energy
- GCE
- glassy carbon electrode
- GDL
- gas diffusion layer
- GGNR
- graphene/graphene nanoribbon
- GO
- graphene oxide
- ?h
- enthalpy
- ?s
- entropy
- 2H
- hydrogen
- H2
- hydrogen
- Hads
- hydrogen adsorption
- HAADF
- high-angle annular dark-field
- h-BN
- hexagonal boron nitride
- HCN
- heptazine-based crystalline carbon nitride
- HCOOH
- formic acid
- hcp
- hexagonal close packing
- HDH
- hetero-dimensional hybrid architecture
- HDS
- hydrodesulfurization
- HEP
- H2 evolution photocatalyst
- HER
- hydrogen evolution reaction
- HES
- hydrogen energy storage
- HF
- hydrofluoric acid
- HRTEM
- high resolution transmission electron microscope
- HSSA
- high specific surface area
- IC
- ion chromatograph
- ICP-AES
- inductively coupled plasma atomic emission spectroscopy
- IL
- ionic liquid
- i-MAX
- in-plane MAX
- IPCC
- Intergovernmental Panel on Climate Change
- IPCE
- Incident Photon-to-Current Efficiency
- IPHE
- International Partnership for H2 and Fuel Cells in the Economy
- i-PrA
- isopropylamine
- IQE
- internal quantum efficiency
- iR drop
- ohmic potential drop
- IrO2
- iridium oxide
- jo
- exchange current density
- KOH
- potassium hydroxide
- LB
- Langmuir Blodgett
- LBL
- layer by layer
- LDH
- layered double hydroxide
- LM Wind
- Lunderskov Møbelfabrik
- LOHC
- liquid organic hydrogen carrier
- LSV
- linear sweep voltammetry
- M
- metal
- MCFC
- molten carbonate fuel cell
- MD
- molecular dynamic
- MEA
- membrane electrode assembly
- MILD
- minimally intensive layer delamination
- Mo
- molybdenum
- Mo2C
- molybdenum carbide
- MOF
- metal-organic framework
- MoP
- molybdenum phosphide
- MoS2
- molybdenum disulfide
- MoSe2
- molybdenum diselenide
- MWCNT
- multi-walled carbon nanotubes
- MX
- metal complex
- N
- nitrogen
- N2O
- nitrous oxide
- NASA
- National Aeronautics and Space Administration
- Nb
- niobium
- ND
- nanodisc
- ND
- nano-dots
- NEXAFS
- near edge X-ray absorption fine structure
- NF
- nanoflake
- NG
- N-doped graphene
- NGO
- N-doped graphene oxide
- NH4HF2
- ammonium bifluoride
- NHE
- normal hydrogen electrode
- Ni
- nickel
- NiCo-UMOFN
- Ni-Co MOF nanosheet
- Ni-G
- Ni-graphene
- NP
- nanoparticle
- O2
- oxygen
- OEP
- O2 evolution photocatalyst
- OER
- oxygen evolution reaction
- OH
- hydroxyl
- o-MAX
- out-of-plane MAX
- OPEC
- organic photoelectrochemical
- ORR
- oxygen reduction reaction
- Os
- osmium
- Ov
- oxygen vacancy
- QD
- quantum dots
- P
- phosphorus
- PAFC
- phosphoric acid fuel cell
- PC
- photocatalytic
- PCE
- photo-chemical-efficiency
- PCG
- porous conductive graphene
- Pd
- palladium
- PDMS
- polypyrrole, polydimethyl siloxane
- PEC
- photoelectrocatalyst
- PEC
- photoelectrochemical
- PEC-HER
- photoelectrochemical-hydrogen evolution reaction
- PEM
- (polymer) electrolyte membrane
- PEM
- proton exchange membrane
- PEMEL
- Proton Exchange Membrane Electrolysis
- PEMFC
- proton exchange fuel cell
- PH3
- phosphine gas
- PL
- photoluminescence
- PLD
- pulsed laser deposition
- POM
- polyoxometalate
- POMOF
- polyoxometalate-based metal-organic framework
- Pt
- platinum
- PV
- photovoltaic
- PVEC
- photovoltaic electrocatalyst
- PXRD
- powder X-ray diffraction
- QE
- quantum efficiency
- Rct
- charge transfer
- R&D
- Research and Development
- RDS
- rate determining step
- RECAI
- Renewable Energy Country Attractiveness Index
- RES
- renewable energy resources
- rGO
- reduced graphene oxide
- RHE
- reversible hydrogen electrode
- Ru
- ruthenium
- S
- sulfur
- SA
- surface area
- SAA
- single-atom alloy
- SAC
- single-atom catalyst
- SCE
- saturated calomel electrode
- SCWG
- supercritical water gasification
- Se
- selenium
- SEM
- scanning electron microscope
- SFE
- Solar-to-Fuel efficiency
- SMR
- steam methane reforming
- SOEL
- high-temperature solid oxide water electroysis
- SOFC
- solid oxide fuel cell
- SPR
- van der Waals
- SSA
- specific surface area
- STEM
- scanning transmission electron microscopy
- STH
- solar-to-hydrogen
- Ta
- tantalum
- TA
- terminal alkyne
- TaS2
- tantalum disulfide
- TBA
- tetrabutylammonium
- TEOA
- triethanolamine
- TNAOH
- tetrabutylammonium hydroxide
- TDOS
- total density of states
- TEM
- transmission electron microscope
- THT
- triphenylene-2,3,6,7,10,11-hexathiolate (THT)
- TM
- transition metal
- TMAOH
- tetramethylammonium hydroxide
- TMC
- transition metal carbide
- TMD
- transition metal dichalcogenide
- TMN
- transition metal nitrides
- TMO
- transition metal oxide
- TMP
- transition metal phosphide
- TMPS
- TM-phosphosulphides
- TOF
- turnover frequency
- TON
- turnover...
