Suzan K. Alghamdi scite author profile

Light diffusing polycarbonate samples were exposed to protons fluences at levels between 10 11 and 10 16 p/cm 2 .T he variation of the refractive index and color intensity with the proton fluence has been studied. The results show that the polycarbonate samples acquire color changes under proton irradiation. Furthermore, thermogravimetric analysis has been performed. It was found that both the onset temperature and activation energy of thermal decomposition are affected by the proton fluencies owing to the degradation and crosslinking processes. Moreover, structural property studies using X-ray diffraction, intrinsic viscosity and Fourier transform infrared spectroscopy were performed.

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Interaction of Bromine with Cu(100) surface: adsorption and thermodynamics stability study

Marashdeh

Saraireh

Elrashidi

et al. 2023

Preprint

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Ab initio atomistic thermodynamics adapted using density functional theory and to study the effect of Bromine (Br) chemisorption on the Cu(001) surface is with coverage (0.11, 0.25, 0.5, 0.75 and 1) ML. H site with coverage of 0.25ML is the most preferred site followed by B site with the order of stability of (H > B > T). The majority of Br atoms stable at B site. Significant structural changes are observed for the first layer’s Cu atoms. For instance, for the bridge (B) site with coverage \(\ge 0.5\)ML, one of the Cu atoms moves from first to second layer, For the hollow H(0.75 and 1) ML and H(0.75 and 1) ML configurations; two Br’s layers thin film are produced on the top of the slab. The substitutional adsorption modes are stable for coverages from 0.25ML up to 2ML. Under ultrahigh-vacuum conditions, the free energies of different Br/Cu(110) structures as a function of Bromine chemical potential are calculated, these calculated energies showed that the bridge site is the most stable for coverages of 1/9ML, whereas the bridge and hollow configurations are the most stable at 1/4ML coverage. Thermodynamics insights provided herein shall be instrumental to underpin bromine interaction with Cu surfaces in applications related to environmental chemistry as in the thermal recycling of e-waste.

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Spectroscopic, electronic properties analysis for 2, 6-Bis (phenylamino)-4-(iminophenyl) benzoquinone molecule and molecular docking clarification for its anticancer activity detected by strong inhibition of NQO1 enzyme

Abbas

Attia

Alghamdi

et al. 2023

Journal of Molecular Structure

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Suzan K. Alghamdi

Spectroscopic characterization (IR, UV-Vis), and HOMO-LUMO, MEP, NLO, NBO Analysis and the Antifungal Activity for 4-Bromo-N-(2-nitrophenyl) benzamide; Using DFT Modeling and In silico Molecular Docking

Spectroscopic, Electronic Properties Analysis for 2, 6-Bis (Phenylamino)-4-(Iminophenyl) Benzoquinone Molecule and Molecular Docking Clarification for its Anticancer Activity Detected by Strong Inhibition of Nqo1 Enzyme

Modification Induced in Light Diffusing Polycarbonate due to Proton Irradiation

Interaction of Bromine with Cu(100) surface: adsorption and thermodynamics stability study

Spectroscopic, electronic properties analysis for 2, 6-Bis (phenylamino)-4-(iminophenyl) benzoquinone molecule and molecular docking clarification for its anticancer activity detected by strong inhibition of NQO1 enzyme

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