Your search keyword '"S. Haj Ibrahim"' showing total 2 results

1. Application of the plasma surface sintering conditions in the synthesis of ReBx–Ti targets employed for hard films deposition in magnetron sputtering technique

Author

M. Kubiś, Katarzyna Nowakowska-Langier, A. Lachowski, Rafal Chodun, E. Grzanka, S. Haj Ibrahim, Krzysztof Zdunek, Marek Trzcinski, B. Wicher, and J. Jaroszewicz

Subjects

Materials science, Analytical chemistry, Oxide, chemistry.chemical_element, Sintering, General Medicine, Sputter deposition, Rhenium, chemistry.chemical_compound, chemistry, Boride, Cavity magnetron, Stoichiometry, Titanium

Abstract

Preparation of a ternary ReBx–Ti compound within a single magnetron target, forming a plasma surface sintering (PSS) conditions, were investigated. An ionized‑neon pressure of 40 Pa induced sintering power pulses (Ei) with energies of up to 3.1 kJ, which resulted in a low-porosity rhenium boride (3.2%) structure within a solid titanium matrix (ReBx–Ti). The prepared targets showed promising resistance to high temperatures (5.45 mm2/s of thermal diffusivity), after the PSS process at a temperature above 2100 °C. These as-surface-sintered magnetron targets were further used in gas injection magnetron sputtering to obtain Re–B–Ti films characterized by an enhanced deposition rate (120 nm/min). Quantitative analysis of these films revealed that the B/Re ratio was in deficit in comparison to the stoichiometry of as-prepared cathode materials. A multiple-chemical-bond state showed the occurrence of Re B, Ti B, B B, Ti Ti, Ti O, and B O phases, of which TiB2 and ReB2 were dominant, forming therefore a glass-like structure. All gathered data indicated a maximum Vickers microhardness value (36.4 GPa), emphasizing the valuable mechanical response of the deposited Re–B–Ti films, as well as the retaining of their good self-passivation effect, attributed by the oxide phases.

Published

2022

2. Role of Surface Topography in the Superhydrophobic Effect-Experimental and Numerical Studies.

Author

Haj Ibrahim S, Wejrzanowski T, Przybyszewski B, Kozera R, García-Casas X, and Barranco A

Abstract

Within these studies, the effect of surface topography for hydrophobic coatings was studied both numerically and experimentally. Chemically modified polyurethane coating was patterned by application of a laser beam. A set of patterns with variously distant linear peaks and grooves was obtained. The cross section of the pattern showed that the edges of the peaks and grooves were not sharp, instead forming a rounded, rectangle-like shape. For such surfaces, experimental studies were performed, and in particular the static contact angle (SCA), contact angle hysteresis (CAH), and roll-off angle (ROA) were measured. Profilometry was used to create a numerical representation of the surface. Finite volume method was then applied to simulate the behavior of the water droplets. The model developed herewith enabled us to reproduce the experimental results with good accuracy. Based on the verified model, the calculation was extended to study the behavior of the water droplet on the simulated patterns, both spiked and rectangular. These two cases, despite a similar SCA of the water droplet, have shown extremely different ROA. Thus, more detailed studies were dedicated to other geometrical features of such topography, such as the size and distance of the surface elements. Based on the results obtained herewith, the future design of superhydrophobic and/or icephobic topography is discussed.

Published

2022