A5071537088- Electrocatalysts for Energy Conversion
- Crystallization and Solubility Studies
- X-ray Diffraction in Crystallography
- Advanced battery technologies research
- Electrochemical Analysis and Applications
- Advanced Photocatalysis Techniques
- Metal-Organic Frameworks: Synthesis and Applications
- Plant tissue culture and regeneration
- Crop Yield and Soil Fertility
- Fuel Cells and Related Materials
- Photosynthetic Processes and Mechanisms
- Plant Genetic and Mutation Studies
- Agronomic Practices and Intercropping Systems
- Agricultural Science and Fertilization
- Plant Physiology and Cultivation Studies
- Plant responses to elevated CO2
- Seed Germination and Physiology
- Agriculture, Plant Science, Crop Management
- Botanical Research and Chemistry
- Copper-based nanomaterials and applications
- Magnetic and Electromagnetic Effects
- Agricultural Economics and Practices
- Potato Plant Research
- Catalytic Processes in Materials Science
- Catalysis and Hydrodesulfurization Studies
Banaras Hindu University
1939-2025
Indian Institute of Technology BHU
2020-2025
Indian Institute of Technology Kanpur
2024-2025
Sardar Vallabhbhai Patel University of Agriculture & Technology
2015
Centre for Sustainable Energy
1995
The electrochemical transformation of a MOF precatalyst into metal hydroxide–(oxy)hydroxide active catalyst.
Journal Article Investigation of the Effect Age on Assimilation Leaves Get access B. N. SINGH, D.Sc., D.Sc. Kapurthala Professor Plant Physiology and Agricultural Botany, Director 1Institute Research Search for other works by this author on: Oxford Academic PubMed Google Scholar K. LAL, M.Sc. 2Contributions from Institute Research, Benares Hindu UniversityIndia Annals Volume os-49, Issue 2, April 1935, Pages 291–307, https://doi.org/10.1093/oxfordjournals.aob.a090507 Published: 01 1935
Abstract Herein, we have demonstrated the control over structure of precatalysts to tune properties active catalysts and their water oxidation activity. The reaction K 3 [Fe(CN) 6 ] Na 2 5 (NO)] with Co(OH) @CC produced PC‐1 PC‐2, respectively, distinct structural electronic features. replacement −CN group strong π‐acceptor −NO modulates atomic PC‐2. As a result, facile electrochemical transformation PC‐2 into catalyst Fe−Co(OH) ‐Co(O)OH (AC‐2) has been attained only in 15 CV cycles while...
Electrochemical seawater splitting is a potential approach to producing H2 and O2. As contains different cations anions, the direct electrochemical of suffers from various challenges like chlorine evolution, corrosion electrodes, poor stability for catalysts. Herein, we have demonstrated incorporation 4d-metal ion Ru3+ in Prussian blue analogue-derived Ru–NiFe(O)OH (at anode) Ru–NiFe(OH)2 cathode) nanosheets splitting. The introduction into active catalysts modulated electronic structure...
Prussian blue analog (PBA)-derived Fe–Co(O)OH showed improved anodic oxidation of a series organic and inorganic compounds without the interference from oxygen evolution reaction.
Herein, we demonstrate a template directed route for the synthesis of self-supported cobalt-iron based Prussian blue analogues (PBAs). The PBAs are electrochemically transformed into layered double hydroxides to produce excellent water oxidation and hydrogen evolution activity, while overall splitting is attained at cell voltage 1.58 V reach 20 mA cm-2 current density.
Electrochemical water oxidation requires a highly active electrocatalyst system with improved catalytic activity, high mechanical stability, and strong catalyst–support interactions. In this respect, unique facile method has been developed for the synthesis of ultrathin Fe–Co(OH)2–Co(O)x(OH)y nanosheets from self-supported Prussian blue analogues by chronoamperometric method. High electrochemical surface area, electronic conductivity, enhanced atomic level thickness (∼3 nm) provided boost...
Here, we demonstrate the enhanced water splitting activity of CoFe–LDH by vanadium substitution.
Electrochemical incorporation of high valent vanadium ions to obtain a V–Ni(OH) 2 –Ni(O)OH catalyst for water oxidation.
In this study, we developed a nitrate-coordinated iron–nickel hydroxide [N C –FeNi(OH) 2 ] catalyst for hydrazine oxidation-assisted seawater splitting.
The universality of the photosynthetic process and its fundamental nature importance have long been recognized, little is known regarding systems involved their exact working in consonance with both external internal factors. From time it came to be recognized that CO2 was absorbed by leaves during photosynthesis an increase concentration rate assimilation increased, attempts made determine optimum carbon dioxide, a percentage which may induce rapid photosynthesis, leading increased growth...
MOF-based materials for seawater electrolysis have been reviewed with a focus on structure–property–performance.