Sergey Ershov

TL;DR: The goal of this review is to illustrate the increasing application of plasma-based technologies for tuning the surface properties of polymers, principally through free-radical chemistry.

TL;DR: The reported research findings reveal the potential of PCL matrices for application in tissue engineering, while the plasma modification with COOH groups and their subsequent covalent binding with proteins expand this potential even further.

TL;DR: In this paper, a magnetron sputtering on Al clad 2024 alloy was used to evaluate the corrosion protection potential of thin cerium oxide thin films, and the electrochemical characterization showed that specific self-healing mechanisms are suspected for the samples with the highest amount of oxygen.

TL;DR: Different evolutions of the surface free radical density for the benzene- and cyclohexane-based PPF, namely, a continuous increase versus stabilization to a plateau, are attributed to different plasma polymerization mechanisms and resulting structures as illustrated by PPF characterization findings.

TL;DR: The surface radical density of an isopropanol-based PPF was quantitatively determined by a combination of NO chemical derivatization and X-ray photoelectron spectroscopy (XPS), revealing that on the top surface, primary, and secondary radicals are dominating, whereas more tertiary radicals are present in the subsurface region.