Your search keyword '"Asif, Misbah"' showing total 6 results

1. Electrochemical sensing behavior of graphdiyne nanoflake towards uric acid: a quantum chemical approach

Author

Asif, Misbah, Sajid, Hasnain, Ayub, Khurshid, Gilani, Mazhar Amjad, Akhter, Mohammed Salim, and Mahmood, Tariq

Published

2021

2. Boron-rich triphenylene COF based electrides having excellent nonlinear optical activity.

Author

Asif, Misbah, Sajid, Hasnain, Qureshi, Sana, Gilani, Mazhar Amjad, Mahmood, Tariq, and Ayub, Khurshid

Subjects

*NONLINEAR optical spectroscopy, *FRONTIER orbitals, *NATURAL orbitals, *OPTICAL rotation, *ALKALI metals, *ELECTRONIC materials, *OPTOELECTRONIC devices

Abstract

The desirability of the high nonlinear response of two-dimensional (2D) materials for electronics and optoelectronic devices drove us to investigate the nonlinear optical (NLO) behavior of alkali metal atom (AA) doped lithiated boron-containing hexahydroxy-triphenylene (LiBHHTP). In this context, the geometric, electronic, optical, and NLO properties are investigated. The doped AA atoms including Li, Na, and K preferably interact via the oxygen atoms of the LiBHHTP surface. The stability of the doped complexes is revealed by the interaction energies (E int), which are −22.90, −16.10, and −16.52 kcal/mol for Li@LiBHHTP, Na@LiBHHTP, and K@LiBHHTP complexes, respectively. The alterations in the electronic behavior of LiBHHTP are observed upon doping with alkali atoms via Frontier Molecular Orbital (FMO), Natural Bond Orbital (NBO), and the Density of State (DOS) analyses. The FMO analysis reveals that these complexes are electride in nature with absorption transparency in the UV–Vis range. Finally, the NLO behavior of designed complexes is evaluated through static and dynamic hyperpolarizabilities. Among reported complexes, K@LiBHHTP exhibits significantly large static hyperpolarizability (βₒ), 2.24 × 105 au. The dynamic NLO response of doped LiBHHTP complexes is also high, where the values are ranged in between 3.67 × 105 and 6.04 × 108 au at 1064 nm. This article not only highlights the effects of alkali atom doping on the NLO behavior of materials but also presents the first Lithiated boron-containing triphenylene as a next-generation optoelectronic material. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

3. Superhalogen doping of aromatic heterocycles; effective approach for the enhancement of static and dynamic NLO response.

Author

Asif, Misbah, Sajid, Hasnain, Gilani, Mazhar Amjad, Ayub, Khurshid, and Mahmood, Tariq

Subjects

*NONLINEAR optical spectroscopy, *DENSITY functional theory, *BAND gaps, *HETEROCYCLIC compounds, *DENSITY of states

Abstract

In this study, for the first time, static and dynamic NLO responses of pure and superhalogen doped aromatic heterocyclic monomers have been investigated by using density functional theory (DFT) calculations. The thermal, electronic, linear, and nonlinear optical properties are computed at the ωB97XD/6-31+G(d,p) method. The thermodynamic stabilities of reported complexes are estimated based on interaction energies, which are in the range of −28.06 to −83.20 kcal/mol. The lowest interaction energies are observed for AlF 4 @X (X = C 4 H 4 NH, C 4 H 4 O, C 4 H 4 S, and C 5 H 5 N) complexes, which correspond to their higher stabilities. The appreciable decrease in the HOMO-LUMO energy gap (E gap) is an indicative of the increase in reactivity after doping with superhalogens. The decrease in E gap is further demonstrated with the help of density of state (DOS) analysis. The significant nonlinear optical responses of the superhalogen doped aromatic heterocyclic monomers are due to the strong electron-withdrawing nature of the fluorine atom. Overall, the results indicate the high NLO response for the AlF 4 @X complexes due to the presence of four electron-withdrawing fluorine atoms in AlF 4. The NLO results are further analyzed through the two-level model. • Superhalogen doping of aromatic heterocyclic monomers is investigated for enhancement of NLO response. • HOMO-LUMO gap significantly decreases upon complexation. • AlF 4 @X exhibit significant thermodynamic stability upto −83.20 kcal/mol. • AlF 4 @X showed excellent third order nonlinear response. [ABSTRACT FROM AUTHOR]

Published

2022

4. Electrochemical sensing of heptazine graphitic C3N4 quantum dot for chemical warfare agents; a quantum chemical approach.

Author

Qureshi, Sana, Asif, Misbah, Sajid, Hasnain, Gilani, Mazhar Amjad, Ayub, Khurshid, Arshad, Muhammad, and Mahmood, Tariq

Subjects

*CHEMICAL warfare agents, *ATOMS in molecules theory, *CHEMICAL shift (Nuclear magnetic resonance), *NATURAL orbitals, *POISONS, *PERTURBATION theory, *QUANTUM dots

Abstract

Despite the numerous publications describing the photocatalytic and electronic properties of heptazine-based C 3 N 4 , the systematic study on the sensing behavior of pure heptazine-C 3 N 4 toward harmful chemical warfare agents (CWAs) is still lacking. Herein, we performed DFT calculations to investigate the adsorption behavior of C 3 N 4 toward various harmful and toxic CWAs including formaldehyde (OCH 2), thioformaldehyde (SCH 2), phosgene (OCCl 2), and thiophosgene (SCCl 2). ωB97XD functional of DFT along with 6–31G (d, p) basis set is used for all calculations for accurate estimation of noncovalent interactions. The CWAs are physiosorbed onto the C 3 N 4 having calculated interaction energy between −16.01 and −11.00 kcal/mol. Noncovalent interactions are further analyzed by symmetry-adapted perturbation theory (SAPT0), noncovalent interaction index (NCI), and quantum theory of atoms in molecules (QTAIM) analyses. The electronic behavior is characterized by the HOMO and LUMO energies, their energy gaps, and natural bond orbital (NBO) charge transfer. The charge transportation either donation or back donation is characterized by energy density difference (EDD) and charge decomposition analysis (CDA) analyses. The results demonstrate the trend of sensitivity of C 3 N 4 for toxic gases is OCH 2 @C 3 N 4 > SCH 2 @C 3 N 4 > OCCl 2 @C 3 N 4 > SCCl 2 @C 3 N 4. This theoretical work suggests that the C 3 N 4 can act as a good electrochemical sensor for a variety of toxic gaseous molecules. [Display omitted] • The sensing abilities of C 3 N 4 towards toxic molecules have been characterized by using ωB97XD/6-31G(d, p) level of DFT. • The sensing behavior of C 3 N 4 is studied through interaction geometries, energies, and electronic properties. • Among designed structures, OCH 2 @h-g-C 3 N 4 exhibits the strongest interaction due to electrostatic interactions. • C 3 N 4 exhibits significant sensitivity towards toxic molecules. [ABSTRACT FROM AUTHOR]

Published

2022

5. Nano-porous C4N as a toxic pesticide's scavenger: A quantum chemical approach.

Author

Asif, Misbah, Sajid, Hasnain, Ayub, Khurshid, Khan, Adnan Ali, Ahmad, Rashid, Ans, Muhammad, and Mahmood, Tariq

Subjects

*CHEMICAL scavengers, *DENSITY functional theory, *FENITROTHION, *BAND gaps, *CHARGE transfer, *ELECTRONIC structure, *POISONS

Abstract

The sensing affinity of C 4 N is the most fascinating topic of research due to its excellent chemical and electronic properties. Moreover, owing to the highly active porous cavity, C 4 N can easily accommodate foreign molecules. Herein, we studied the adsorption properties of carbamate insecticides (CMs) namely, Dimetalin (DMT), Carbanolate (CBT), Isolan (ISO) and Propoxur (PRO) using density functional theory calculations. All the results are calculated at widely accepted ωB97XD functional along with 6-31G(d, p) basis set. The calculated counterpoise corrected interaction energy of the reported complexes ranges between −20.05 and −27.04 kcal/mol, however, the interaction distances are found to be higher than 2.00 Å. The values of interacting parameters depict that the carbamate molecules are physisorbed via noncovalent interactions that can easily be reversible. Moreover, the binding of selected insecticides notably changes the electronic structure of C 4 N. The electronic changes are characterized by the energies of HOMO & LUMO, their energy gaps and CHELPG charge transfer. The charge density difference between C 4 N surface and carbamate pesticides are characterized by EDD and CDA analysis. Moreover, the ab initio molecular dynamic study reveals that the complexes are stable even at 500 K. The photochemical sensing properties of C 4 N are estimated by time dependent UV–Vis calculations. The high sensitivity of C 4 N towards considered analytes enable it to act as a promising sensor for toxic pesticides. [Display omitted] • The sensing of C 4 N towards carbamate insecticides is investigated within the framework of DFT. • The results are characterized by the geometric, energetic, electronic, and optical analyses. • All the results are computed at ωB97XD/6-31G (d,p) level of DFT. • The trend of thermodynamic stability of complexes is as follow; DMT@C4N > CBT@C4N > ISO@C4N > PRO@C4N. [ABSTRACT FROM AUTHOR]

Published

2022

6. A first principles study on electrochemical sensing of highly toxic pesticides by using porous C4N nanoflake.

Author

Asif, Misbah, Sajid, Hasnain, Ayub, Khurshid, Ans, Muhammad, and Mahmood, Tariq

Subjects

*FENITROTHION, *DDT (Insecticide), *ATOMS in molecules theory, *PESTICIDES, *ORGANOPHOSPHORUS pesticides, *POISONS, *MOLECULAR orbitals, *DENSITY functional theory

Abstract

C 4 N is a novel porous two-dimensional material with fascinating electronic and chemical properties. Thereby, the sensing ability of C 4 N is the most aspect topic of research nowadays. In this study, potential application of C 4 N nanoflake as a chemical sensor for the toxic pesticides has been investigated using density functional theory calculations. The sensing ability of C 4 N for pesticides is evaluated through the interaction energy, noncovalent interaction index (NCI), quantum theory of atoms in molecule (QTAIM), molecular orbitals and CHELPG charge transfer analyses. The first principle calculations on ωB97XD/6-31G(d, p) level of DFT show that the C 4 N is selectively sensitive to Dichlorodiphenyltrichloroethane (DDT), Fenitrothion (FNT), Dimethoxy (DMDT), Ronnel (RN) and Fenthion (FT). The interaction of pesticides leads to the significant changes in the electronic structure of C 4 N. The observed sequence of interaction energy of our reported complexes is DDT@C 4 N > FNT@C 4 N > DMDT@C 4 N > RN@C 4 N > FT@C 4 N. The electronic structure changes can be demonstrated from two aspects: the strong interaction between pesticide molecule and C 4 N, the variation in HOMO-LUMO orbital energies and charge transfer from C 4 N to pesticide. The charges distribution between analytes and C 4 N nanoflake on interaction is analyzed by the electron density differences (EDD) and charge decomposition analysis (CDA). Our results reveal the potential application of C 4 N in electronic and sensor devices especially for the detection of toxic chemicals. [Display omitted] • The sensing of C 4 N nanoflake toward pesticides is investigated theoretically. • The results are based on the geometric, energetic, and electronic analyses. • ωB97XD and M052X-D3/6-31G (d,p) levels of DFT are implemented to measure the sensing affinity of C 4 N. • The thermodynamic stability is in the order of DDT@C 4 N > FNT@C 4 N > DMDT@C 4 N > RN@C 4 N > FT@C 4 N. [ABSTRACT FROM AUTHOR]

Published

2022