Novel Nanomaterials for Energy Storage and Catalysis
Materialtyp:
ArtikelUtgivningsinformation: MDPI - Multidisciplinary Digital Publishing Institute 2024Beskrivning: 1 electronic resource (192 p.)Innehållstyp: - text
- computer
- online resource
- 9783725807659
- 9783725807666
- Technology, Engineering, Agriculture, Industrial processes
- Technology: general issues
- CO2-switchable
- CdS-C60
- Fe chelate
- Knoevenagel condensation
- POP-Ni catalyst
- Pickering emulsion
- TiO2
- TiO2 nanorods
- adsorption
- anion ionophore
- anode material
- anode materials
- bamboo charcoal
- carbon dioxide fixation
- carbon paste ion-selective electrode
- catalytic material
- ceramic separator
- co-modified
- degradation
- electrochemical impedance spectroscopy
- energy density
- fast charging
- graphite
- green chemistry
- heterogeneous catalysis
- hierarchically porous zirconium-based MOF
- high rate capability
- humic acid
- hybrid supercapacitor
- hydrogen evolution
- hydrothermal synthesis
- ion-selective electrode
- ionic liquid
- kinetics
- lithium ion batteries
- lithium-ion battery
- metal–organic compound
- methylene blue
- mini-reactor
- molybdenum disulfide
- nickel-chromium-sulfide (Ni-Cr-S)
- organic anode
- organic dye degradation
- photocatalytic activity
- photoelectrocatalysis
- polyethylene
- potentiometry
- solid contact
- specific surface area
- thermal stability
- tungsten oxide
- water splitting
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This reprint delves into the cutting-edge developments and applications of nanomaterials in energy storage and catalysis. The journey through this reprint begins with an exploration of advanced nanomaterials designed for energy storage applications, including batteries, supercapacitors and fuel cells. It delves into the fundamental principles governing their design, synthesis, characterization and performance optimization, highlighting key breakthroughs and emerging trends. Transitioning into catalysis, the reprint showcases the pivotal role of nanomaterials in catalytic processes for energy conversion, environmental remediation and sustainable chemical engineering. Readers gain valuable insights into design strategies, catalytic mechanisms and performance enhancements enabled by nanomaterial-based catalysts, showcasing their potential to revolutionize diverse sectors. Throughout this reprint, an emphasis is placed on the interdisciplinary nature of nanomaterial research, highlighting the synergistic integration of materials science, chemistry, physics, engineering and environmental science. Moreover, it underscores the importance of collaboration, knowledge exchange and continuous innovation in driving impactful solutions for global energy and environmental challenges.
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eng
Freely available e-book