Your search keyword '"M. Fadlallah"' showing total 6 results

1. Substitutional transition metal doping in MoSi

Author

Mohamed A, Abdelati, Ahmed A, Maarouf, and Mohamed M, Fadlallah

Abstract

Monolayer MoSi

Published

2022

2. Electronic, optical and thermoelectric properties of a novel two-dimensional SbXY (X = Se, Te; Y = Br, I) family

Author

A, Bafekry, M, Faraji, M M, Fadlallah, D M, Hoat, H R, Jappor, I Abdolhosseini, Sarsari, M, Ghergherehchi, and S A H, Feghhi

Abstract

Recent developments in the synthesis of highly crystalline ultrathin BiTeX (X = Br, Cl) structures [Debarati Hajra

Published

2021

3. Metal dichalcogenide nanomeshes: structural, electronic and magnetic properties

Author

H. M. El-Sayed, Mohamed A. Helal, Ahmed A. Maarouf, and Mohamed M. Fadlallah

Subjects

education.field_of_study, Materials science, Spintronics, Passivation, Spin states, Population, General Physics and Astronomy, chemistry.chemical_compound, Molecular dynamics, Nanomesh, chemistry, Transition metal, Chemical physics, Density functional theory, Physical and Theoretical Chemistry, education

Abstract

Motivated by the successful preparation of two-dimensional transition metal dichalcogenide (2D-TMD) nanomeshes in the last three years, we use density functional theory (DFT) to study the structural stability, mechanical, magnetic, and electronic properties of porous 2H-MoX2 (X = S, Se and Te) without and with pore passivation. We consider structures with multiple, systematically created pores. The molecular dynamics simulations and cohesive energy calculations showed the stability of the 2D-TMD nanomeshes, with larger stability for those with smaller pores. The lattice undergoes some deformations to accommodate the pore energetically, and as the pore size increases Young's modulus decreases. In most cases, the missing metal atoms disrupt the spin states’ even population, resulting in some nanomeshes becoming magnetic. The electronic gaps of the MoX2 nanomesh systems are diminished because of the emergence of pore-edge localized mid-gap metal 4d states in the spin-polarized spectrum, making some systems half-metallic. The oxygen passivation of the pore edges of 2D-TMD nanomeshes restores the even population of spin states, and makes those systems metallic. Our results can be used in different applications such as spintronics, ion chelation, and molecular sensing applications.

Published

2021

4. Surface modification of titanium carbide MXene monolayers (Ti

Author

M, Faraji, A, Bafekry, M M, Fadlallah, F, Molaei, N N, Hieu, P, Qian, M, Ghergherehchi, and D, Gogova

Abstract

Inspired by the recent successful growth of Ti2C and Ti3C2 monolayers, here, we investigate the structural, electronic, and mechanical properties of functionalized Ti2C and Ti3C2 monolayers by means of density functional theory calculations. The results reveal that monolayers of Ti2C and Ti3C2 are dynamically stable metals. Phonon band dispersion calculations demonstrate that two-surface functionalization of Ti2C and Ti3C2via chalcogenides (S, Se, and Te), halides (F, Cl, Br, and I), and oxygen atoms results in dynamically stable novel functionalized monolayer materials. Electronic band dispersions and density of states calculations reveal that all functionalized monolayer structures preserve the metallic nature of both Ti2C and Ti3C2 except Ti2C-O2, which possesses the behavior of an indirect semiconductor via full-surface oxygen passivation. In addition, it is shown that although halide passivated Ti3C2 structures are still metallic, there exist multiple Dirac-like cones around the Fermi energy level, which indicates that semi-metallic behavior can be obtained upon external effects by tuning the energy of the Dirac cones. In addition, the computed linear-elastic parameters prove that functionalization is a powerful tool in tuning the mechanical properties of stiff monolayers of bare Ti2C and Ti3C2. Our study discloses that the electronic and structural properties of Ti2C and Ti3C2 MXene monolayers are suitable for surface modification, which is highly desirable for material property engineering and device integration.

Published

2021

5. Electronic and optical properties of two-dimensional heterostructures and heterojunctions between doped-graphene and C- and N-containing materials

Author

Nguyen V. Chuong, Mohamad Oskoeian, Mohamed M. Fadlallah, Seyed Amir Hossein Feghhi, M. Faraji, Asadollah Bafekry, Mitra Ghergherehchi, and D. Gogova

Subjects

Materials science, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, symbols.namesake, law, Electric field, Monolayer, Physical and Theoretical Chemistry, Nanoscopic scale, business.industry, Graphene, Physics, Heterojunction, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemistry, Semiconductor, symbols, Optoelectronics, Density functional theory, van der Waals force, 0210 nano-technology, business

Abstract

The electronic and optical properties of vertical heterostructures (HTSs) and lateral heterojunctions (HTJs) between (B,N)-codoped graphene (dop@Gr) and graphene (Gr), C3N, BC3 and h-BN monolayers are investigated using van der Waals density functional theory calculations. We have found that all the considered HTSs are energetically and thermally feasible at room temperature, and therefore they can be synthesized experimentally. The dop@Gr/Gr, BC3/dop@Gr and BN/dop@Gr HTSs are semiconductors with direct bandgaps of 0.1 eV, 80 meV and 1.23 eV, respectively, while the C3N/dop@Gr is a metal because of the strong interaction between dop@Gr and C3N layers. On the other hand, the dop@Gr-Gr and BN-dop@Gr HTJs are semiconductors, whereas the C3N-dop@Gr and BC3-dop@Gr HTJs are metals. The proposed HTSs can enhance the absorption of light in the whole wavelength range as compared to Gr and BN monolayers. The applied electric field or pressure strain changes the bandgaps of the HTSs and HTJs, indicating that these HTSs are highly promising for application in nanoscale multifunctional devices.

Published

2021

6. Dopant site in indium-doped SrTiO

Author

Hanggara, Sudrajat, Mohamed M, Fadlallah, Shuxia, Tao, Mitsunori, Kitta, Nobuyuki, Ichikuni, and Hiroshi, Onishi

Abstract

Strontium titanate, SrTiO3, with the perovskite ABO3 structure is known as one of the most efficient photocatalyst materials for the overall water splitting reaction. Doping with appropriate metal cations at the A site or at the B site substantially increases the quantum yield to split water into H2 and O2. The site occupied by the guest dopant in the SrTiO3 host thus plays a key role in dictating the water splitting activity. However, little is known about the detailed structure of the dopant site in the host lattice. In this study, the local structure of In3+ cations, which were shown to improve the water splitting activity of SrTiO3, is investigated with X-ray absorption fine structure spectroscopy and density functional theory (DFT) calculations. The In3+ cations exclusively substitute for Ti4+ cations at the B site to form InO6 octahedra. Further optical experiments using UV-Vis diffuse reflectance spectroscopy and DFT calculations of the density of states indicate that the substitution of In3+ for Ti4+ does not alter the band structure and bandgap energy (remaining at 3.2 eV). The mechanism underlying the increased water splitting activity is discussed in relation to occupation of the B site by In3+ cations.

Published

2020