Your search keyword '"Iliashevsky O"' showing total 2 results

1. DOTP versus DOTA as Ligands for Lanthanide Cations: Novel Structurally Characterized Ce IV and Ce III Cyclen-Based Complexes and Clusters in Aqueous Solutions.

Author

Dovrat G, Pevzner S, Maimon E, Vainer R, Iliashevsky O, Ben-Eliyahu Y, Moisy P, Bettelheim A, and Zilbermann I

Abstract

The coordination and redox chemistry of aqueous Ce IV/III macrocyclic compounds were studied by using the ligands DOTA and DOTP (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetrayl)tetraacetic acid and 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetra(methylene phosphonic acid), respectively). The hydrolysis tendency of the tetravalent cation in the presence of DOTA is shown to result in the formation of a highly ordered, fluorite-like [Ce IV (O) 6 (O) 4 (OH) 4 O) 2 O) 8 (DOTAH) 4 ] oxo-hydroxo structure both in solution and in the solid state. The lifetime of the analogous species formed in the presence of DOTP was found to be much shorter. Spectroscopic measurements of the latter suggest its similarity to the former. Its gradual decomposition in solution leads to the accumulation of the in-cage complexes [Ce IV DOTP] and [Ce III O)], which were crystallographically characterized in this study. The redox energetics and spectroscopic characteristics for the transition between these two in-cage complexes in aqueous solutions were studied as well. Together with the crystallographic structures of the above-mentioned species, the in-cage [Ce 2 O)], which were crystallographically characterized in this study. The redox energetics and spectroscopic characteristics for the transition between these two in-cage complexes in aqueous solutions were studied as well. Together with the crystallographic structures of the above-mentioned species, the in-cage [Ce IV O)] complex structure is presented herein for the first time. An elaborative analysis of the X-ray crystallographic structural data obtained for the in-cage complexes studied herein and similar structures published previously suggests that hard-bonding cyclen-derived ligands are, counter-intuitively, better suited for encapsulating, and perhaps kinetically stabilize softer cations than harder ones with DOTP, marked as a possible adequate chelator for the study of the aqueous properties of Ln 2 O)] complex structure is presented herein for the first time. An elaborative analysis of the X-ray crystallographic structural data obtained for the in-cage complexes studied herein and similar structures published previously suggests that hard-bonding cyclen-derived ligands are, counter-intuitively, better suited for encapsulating, and perhaps kinetically stabilize softer cations than harder ones with DOTP, marked as a possible adequate chelator for the study of the aqueous properties of Ln II and Ac III cations., (© 2022 Wiley-VCH GmbH.)

Published

2022

2. Single-chain polybutadiene organometallic nanoparticles: an experimental and theoretical study.

Author

Berkovich I, Mavila S, Iliashevsky O, Kozuch S, and Lemcoff NG

Abstract

High molecular weight polybutadienes and rhodium complexes were used to produce single chain organometallic nanoparticles. Irradiation of high cis -polybutadiene in the presence of a photosensitizer isomerised the double bonds to produce differing cis / trans ratios within the polymer. Notably, a higher cis percentage of carbon-carbon double bonds within the polymer structure led to faster binding of metal ions, as well as their faster removal by competing phosphine ligands. The experimental results were supported and rationalized by DFT computations.

Published

2016