5th Edition of
Chemistry World Conference
June 02-04, 2025 | Rome, Italy
Sonoelectrochemistry
Sonoelectrochemistry Is An Interdisciplinary Area Of Research Involving The Combination Of Ultrasound And Electrochemistry. The Technique Was First Proposed In 1972 And Has Since Been Widely Studied For Its Use In Enhanced Electrochemical Processes. With The Rapid Development Of Technology In Recent Years, Its Application Has Been Further Advanced And Now Has The Potential To Be Used In A Variety Of Fields, From Industry To Medical Research. The Main Benefit Of Sonoelectrochemistry Is Enhanced Reaction Kinetics. Ultrasound Waves Create Microbubbles Through Acoustic Cavitation, Which Increase Surface Area And Reactant Concentrations Near The Electrode. This Facilitates A Much Greater Rate Of Reaction, Allowing For Faster, More Efficient Measurements. Additionally, Sonoelectrochemistry Can Modulate And Control The Reaction Environment, Allowing For Greater Control Over Reaction Parameters. The Most Common Application Of Sonoelectrochemistry Is The Synthesis Of Nanomaterials. Acoustic Cavitation Produces Ultrasmall Droplets Containing Both Reactants And Products, Allowing For Much Greater Control Over The Size, Shape, And Structure Of Nanomaterial Synthesis. These Nanomaterials Have A Variety Of Applications, From Medical Devices To Catalytic Systems. Sonoelectrochemistry Has Also Been Increasingly Used In Biological Applications, Such As The Detection Of Pathogens, Toxic Pollutants, And Proteins. This Method Allows For Extremely Sensitive And Selective Detection, As The Acoustic Cavitation Produced Can Be Tailored To Selectively Detect Specific Molecules. The Use Of Sonoelectrochemistry Is Expected To Further Increase Due To Its Potential For Greater Control Over Reaction Parameters, Enhanced Reaction Kinetics, And Improved Nanomaterial Synthesis. Additionally, Its Application In Bioelectrochemical Sensors Is Expected To Expand Due To Its Ability To Selectively Detect Target Molecules. With Its Current Capabilities, Sonoelectrochemistry Has The Potential To Revolutionize The Way Industrial And Medical Processes Are Done.
Yong Xiao Wang
Albany Medical College, United States
Hossam A Gabbar
Ontario Tech University, Canada
Stanislaw Dzwigaj
Sorbonne Universite, France
Haibo Ge
Texas Tech University, United States
Thomas J Webster
Hebei University of Technology, China
Makarov Vladimir
Institute of Permafrost Science, Russian Federation
Silvia Elizabeth Asis
Universidad de Buenos Aires, ArgentinaSubmit your abstract Today
Title : Advances in plasma-based waste treatment for sustainable communities
Hossam A Gabbar, Ontario Tech University, Canada
Title : Nanostructured biodevices based on carbon nanotubes and glyconanoparticles for bioelectrocatalytic applications
Serge Cosnier, Silesian University of Technology, Poland
Title : Carbon capture and storage: The impact of impurities in CO2 streams
Andy Brown, Progressive Energy Ltd, United Kingdom
Title : Supramolecular nano chemistries: Fighting viruses, inhibiting bacteria and growing tissues
Thomas J Webster, Hebei University of Technology, China
Title : Chemical engineering of vanadium and tantalum zeolites for application in environmental catalysis
Stanislaw Dzwigaj, Sorbonne Universite, France
Title : Disrupting TNF-α and TNFR1 interaction: Computational insights into the potential of D-Pinitol as an anti-inflammatory therapeutic
Ferran Acuna Pares, Universidad Internacional de la Rioja (UNIR), Spain