Your search keyword '"Ahmad, Iftikhar"' showing total 9 results

1. Detailed DFT studies of the band profiles and optical properties of antiperovskites SbNCa3 and BiNCa3.

Author

Bilal, M., Ahmad, Iftikhar, Rahnamaye Aliabad, H.A., and Jalali Asadabadi, S.

Subjects

*ENERGY bands, *PEROVSKITE, *ANTIMONY compounds, *BISMUTH compounds, *DENSITY functional theory, *OPTICAL properties of metals

Abstract

Highlights: [•] The available theoretical studies on the antiperovskites SbNCa3 and BiNCa3 were not consistent with the experiments. [•] These compounds are theoretically revisited with LDA, GGA, EV-GGA and mBJ potentials. [•] Both of them are found direct bandgap semiconductors. [•] The bandgaps for both of them is about 1.1eV. [•] Realizing the importance of these compounds in optical devices, optical properties are also discussed. [ABSTRACT FROM AUTHOR]

Published

2014

2. Lead-free Dion–Jacobson halide perovskites CsMX2Y2 (M = Sb, Bi and X, Y = Cl, Br, I) used for optoelectronic applications via first principle calculations.

Author

Haq, Izaz Ul, Rehman, Gul, Ahmad, Iftikhar, Yakout, H.A., and Khan, Imad

Subjects

*BAND gaps, *PEROVSKITE, *CONDUCTION bands, *ELECTRON transitions, *CHARGE carrier mobility, *VALENCE fluctuations, *ANTIMONY

Abstract

In this study, all-inorganic two-dimensional Dion–Jacobson halide perovskites (DJ-HPs) CsMX 2 Y 2 (M = Sb, Bi; and X/Y= I/I, I/Br, Br/Br, I/Cl, Br/Cl, Cl/Cl) have been studied for photovoltaic, photoemission and other potential applications in optoelectronic devices using first principle calculations within the framework of density functional theory (DFT). The ground state crystal symmetry is tetragonal with a P 4/ mmm (No. 123) space group. In these compounds, Cs+ is a spacer cation, which separates the octahedral layers and balances the charge. The corner sharing M-centered (Sb, Bi) [MX 2 Y 4 ]3– unit constructs the 2D [MX 2 Y 2 ] n n– plane, where the X and Y (halogens) atoms occupy the out of plane apical and in-plane bridging sites, respectively. The DJ-HPs with P 4/ mmm crystal symmetry exhibit pseudo-direct band gap semiconducting nature and the spin orbit (SO) effect reduces the band gaps as well as splits the Sb/Bi-p orbital in the bottom of conduction band (CB) and X/Y-p orbital at the top of valence band (VB). Among these DJ-HPs, the band gap energies of CsSbI 2 Cl 2 (0.87 eV), CsSbBr 2 Cl 2 (1.00 eV), CsSbCl 4 (1.40 eV), CsBiI 4 (1.10 eV), CsBiI 2 Br 2 (1.40 eV) and CsBiBr 4 (1.60 eV) lie in a band gap energy range (0.9–1.6 eV) suitable for photovoltaic applications. The M-s (Sb-5s and Bi-6s) and X/Y-p (Cl-3p, Br-4p and I-5p) orbitals are responsible for the electron transition from the valence to conduction band, while the spacer cation (Cs+) has a limited effect on the charge carrier mobility. The effective masses of the charge carriers and exciton binding energies of these materials are suitable for solar cell and optoelectronic applications. From the optical coefficients it is clear that these DJ-HPs have excellent response to the incident photons in the visible and ultraviolet light region. • New Dion–Jacobson two dimensional halide are investigated for optoelectronic applications. • These compounds belongs to tetragonal symmetry having space group P 4/ mmm. • Band gap of these semiconductors are pseudo direct and spin orbit (SO) effect increases from Sb to Bi and Cl to I. • The effective masses of the carriers are increasing linearly with the increasing band gaps. [ABSTRACT FROM AUTHOR]

Published

2023

3. Structural and magnetic properties of TlTF3 (T=Fe, Co and Ni) by hybrid functional theory.

Author

Zeb, Raham, Ali, Zahid, Ahmad, Iftikhar, and Khan, Imad

Subjects

*IRON compounds, *MAGNETIC properties of metals, *MAGNETIC structure, *DENSITY functional theory, *MAGNETOELECTRONICS, *PEROVSKITE

Abstract

DFT studies are performed to investigate the structural, mechanical and magneto-electronic properties of the TlTF 3 (T=Fe, Co and Ni) perovskites for the first time using GGA, GGA+U and hybrid density functional theory (HF). Our calculations show that HF give better results than GGA and GGA+U and more consistent with the experiments. The comparison of the lattice constants calculated by HF with experiments shows a maximum underestimation less than 0.2%. The chemical bonding between different ions in these compounds is explained on the bases of electronic clouds, which reveals that in TlFeF 3 , Fe has more ionic character with F than the rest. The mechanical properties explain the hardness of these compounds and show that TlFeF 3 is more ductile. Spin-dependent electronic band profiles show that TlFeF 3 and TlCoF 3 are metallic, whereas TlNiF 3 is pseudo direct wide bandgap semiconductor. The stable magnetic phase optimizations and the calculated magnetic susceptibility confirm that TlFeF 3 and TlNiF 3 are ferromagnetic whereas TlCoF 3 is anti-ferromagnetic material. [ABSTRACT FROM AUTHOR]

Published

2015

4. Magneto-electronic studies of the inverse-perovskite (Eu3O)In.

Author

Ali, Zahid, Khan, Banaras, Ahmad, Iftikhar, Khan, Imad, and Asadabadi, S. Jalali

Subjects

*MAGNETOELECTRONICS, *PEROVSKITE, *FERROMAGNETIC materials, *DENSITY functional theory, *SPIN polarization, *CHARGE density waves

Abstract

Ferromagnetic metallic inverse-perovskite (Eu 3 O)In is studied using hybrid functional theory (HF) in the frame work DFT. The calculated structural parameters and geometries of the material are calculated by different exchange correlation potentials and found that HF results are closed to the experiments. Electronic charge density explains the bond nature and polarization. The spin polarized electronic band profiles and density of states reveal the metallic nature of the compound. The Eu f-state splitting show that the valance bands are dominated mainly by f-[a 2 ], f-[x(T 1 )], f-[y(T 1 )] and f-[z(T 1 )] states. The ground state magnetic phase of the compound is optimized. The optimum energy and magnetic susceptibility confirm the ferromagnetic nature of the compound. On the basis of different properties presented it is predicted that this compound is magnetoresistive material. [ABSTRACT FROM AUTHOR]

Published

2015

5. Comparison of the electronic band profiles and magneto-optic properties of cubic and orthorhombic SrTbO3.

Author

Ali, Zahid, Khan, Imad, Ahmad, Iftikhar, Naeem, S., Rahnamaye Aliabad, H.A., Jalali Asadabadi, S., and Zhang, D.

Subjects

*ELECTRONIC band structure, *MAGNETOOPTICS, *STRONTIUM compounds, *PLANE wavefronts, *PEROVSKITE, *GROUND state (Quantum mechanics)

Abstract

Abstract: The all electrons full potential linearized augmented plane waves (FP-LAPW) method with GGA+U is used to study SrTbO3 perovskite in cubic and orthorhombic phases. The structural parameters and ground state magnetic properties are found consistent with the experimental results. The electronic band structures and density of states demonstrate that SrTbO3 is a wide band gap semiconductor in both phases. The magnetic studies of the material show that the nature of the compound is G-type anti-ferromagnetic. The calculated magnetic moment of Tb+4 is found consistent with the experiments. Furthermore, the optical properties demonstrate that the optical gap of the material is 1.8eV, which lies in the visible region of the electromagnetic spectrum and hence the compound can be used in optoelectronic devices. [Copyright &y& Elsevier]

Published

2013

6. Structural and optoelectronic properties of the zinc titanate perovskite and spinel by modified Becke–Johnson potential.

Author

Ali, Zahid, Ali, Sajad, Ahmad, Iftikhar, Khan, Imad, and Rahnamaye Aliabad, H.A.

Subjects

*OPTOELECTRONICS, *ZINC compounds, *PEROVSKITE, *CRYSTAL structure, *DENSITY functional theory, *BAND gaps, *SEMICONDUCTORS

Abstract

Abstract: Structural and electronic properties of the cubic perovskite ZnTiO3 and spinel Zn2TiO4 are theoretically studied by the modified Becke–Johnson (mBJ) potential within the framework of density functional theory (DFT). The calculated lattice constants are found to be consistent with the experimental results. The electronic band structures of both the materials reveal that ZnTiO3 is an indirect band gap while Zn2TiO4 is a direct band gap semiconductor. The calculated fundamental band gaps of these compounds are 2.7eV and 3.18eV, which are consistent with the experimental band gaps of 2.9eV and 3.1eV, respectively. Zn2TiO4 is a wide and direct band gap compound and hence is an attractive material for optoelectronic applications, especially in near ultraviolet (UV) optoelectronics. Keeping in view the importance of Zn2TiO4 in low frequency UV devices its optical properties like dielectric functions, refractive index, reflectivity and energy loss function are also evaluated and discussed in detail. [Copyright &y& Elsevier]

Published

2013

7. Theoretical studies of the osmium based perovskites AOsO3 (A=Ca, Sr and Ba).

Author

Ali, Zahid, Sattar, Abdul, Asadabadi, S. Jalali, and Ahmad, Iftikhar

Subjects

*OSMIUM compounds, *PEROVSKITE, *DENSITY functional theory, *ELECTRONIC band structure, *MAGNETIZATION, *SCIENTIFIC observation

Abstract

Osmium based perovskites AOsO 3 (A=Ca, Sr and Ba) have been studied theoretically using density functional theory approach. These studies show that CaOsO 3 and SrOsO 3 are orthorhombic and BaOsO 3 is cubic and are consistent with the experiments. The electronic band structures demonstrate that these compounds are metals. The magnetic studies verify the experimental observations at low temperature, where the spin effects are canceled by the orbitals. The stable magnetic phase optimizations and magnetic susceptibilities calculations by the post-DFT treatment confirm that CaOsO 3 and SrOsO 3 are weak ferromagnetic whereas BaOsO 3 is a paramagnetic material. The directional magnetic study shows that these compounds are magnetically anisotropic, and reveals that the easy magnetization axis is [001] direction. [ABSTRACT FROM AUTHOR]

Published

2015

8. Magneto-electronic studies of anti-perovskites NiNMn3 and ZnNMn3.

Author

Ali, Zahid, Shafiq, M., Jalali Asadabadi, S., Rahnamaye Aliabad, H.A., Khan, Imad, and Ahmad, Iftikhar

Subjects

*MAGNETOELECTRONICS, *PEROVSKITE, *NICKEL compounds, *ZINC compounds, *ELECTRONIC band structure, *MAGNETIC transitions

Abstract

Highlights: [•] Anti-perovskites NiNMn3 and ZnNMn3 are theoretically investigated. [•] The electronic band structure reveals that both compounds are metals. [•] The optimized ground state magnetic phases of both compounds are anti-ferromagnetic. [•] The magnetic properties show that they can be used in spin based devices. [Copyright &y& Elsevier]

Published

2014

9. Electronic and optical properties of group IIA-IVB cubic perovskite oxides: Improved TB-mBJ study.

Author

Ullah, Saif, Iqbal, Tausif, Rehman, Gul, and Ahmad, Iftikhar

Subjects

*OPTICAL properties, *BAND gaps, *CHEMICAL bonds, *LIGHT absorption, *PEROVSKITE, *ELECTRONIC band structure, *ALKALINE earth metals, *BARIUM zirconate

Abstract

• Electronic and optical properties. • Effects of chemical bond strength and electronegativity difference on electronic properties. • Accuracy of improved TB-mBJ exchange potential. • Improved TB-mBJ approach results compared with experimental. The recently developed improved Tran and Blaha modified Becke-Johnson exchange potential (TB-mBJ) approach within the framework of DFT is used to calculate band gaps and optical properties of cubic perovskites ABO 3 (A = Ca, Sr, Ba and B = Ti, Zr, Hf). The bonding nature and electronegativity difference between B-cation and O atoms are considerably influencing the electronic band gaps of these compounds. Improved TB-mBJ treats the electronic density appropriately between them, producing accurate band gaps. The optical response shows wide range of light absorption, from visible to ultraviolet, in these compounds expecting their possible applications in various optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2020