Igor Zhitomirsky

TL;DR: In this article, a review of recent developments in the electrodeposition of ceramics and organoceramic materials is presented, which includes mass transport, accumulation of particles near the electrode and their coagulation to form a cathodic deposit, and interparticle forces that govern colloidal stability in the absence and presence of processing additives.

TL;DR: How EPD has become an important tool in advanced biomaterials processing, as a convenient alternative to conventional methods, and the potential of the technique to manipulate and control the deposition of a range of nanomaterials of interest in the biomedical and biotechnology fields are presented.

TL;DR: Electrodeposition is gaining increasing interest as a ceramic processing technique for a variety of technical applications as discussed by the authors, and major advances in the areas of electrophoretic deposition (EPD) and electrolytic deposition (ELD) achieved in the last 24 months include the fabrication of: electrodes and films for solid oxide fuel cells, fibre-reinforced and graded ceramic composites, nanostructured materials as well as advanced films and coatings for electronic, biomedical, optical, catalytic and electrochemical applications.

TL;DR: It was established that experimental conditions of powder preparation, electric field and stirring have a significant influence on suspension stability and deposit morphology.

TL;DR: In situ incorporation of polypyrrole nanofibers, poly pyrrole-coated carbon nanotubes, and manganese dioxide nanoparticles in the aerogels gives flexible 3D supercapacitor devices with excellent capacitance retention, low internal resistance, and fast charge-discharge rates.