Table 11 Quantum calculation parameters: highest occupied molecular orbital energy (EHOMO), lowest unoccupied molecular orbital energy (ELUMO), the energy gap (ΔE), global hardness (η), softness (σ), electronegativity (χ), global electrophilicity (ω), ΔN, and Δw
Code
|
H4
|
H5
|
H6
|
Program
|
MS-Dmol6
|
MS-Dmol6
|
MS-Dmol6
|
Method
|
DFT
|
DFT
|
DFT
|
Basis set
|
DNP (4.4)
|
DNP (4.4)
|
DNP (4.4)
|
Function
|
GGA-RPBE
|
GGA-RPBE
|
GGA-RPBE
|
EHOMO (eV)
|
−5.24731
|
−5.13616
|
−4.56568
|
ELUMO (eV)
|
−3.29443
|
−2.96602
|
−3.16616
|
ΔE = ELUMO − EHOMO
|
1.95288
|
2.17013
|
1.39953
|
η = ΔE/2
|
0.97644
|
1.08507
|
0.69976
|
σ(S) = 1/η
|
1.02413
|
0.92160
|
1.42905
|
Pi = (EHOMO + ELUMO)/2
|
−4.27087
|
−4.05109
|
−3.86592
|
X = −Pi
|
4.27087
|
4.05109
|
3.86592
|
ΔNmax
|
2.18695
|
1.86674
|
2.76230
|
ΔN (FET)
|
0.28119
|
0.35432
|
0.68172
|
ω
|
9.34019
|
7.56235
|
10.67884
|
ε
|
0.10706
|
0.13223
|
0.09364
|
ΔE back-donation
|
−0.24411
|
−0.27127
|
−0.17494
|
|
|
Fig. 15 Images of HOMO, LUMO electron density and optimized geometry configuration for inhibitor molecules resulted from computational chemical calculations.
|
|
Table 12 Orbital colors interpretation
Orbital type
|
Color
|
Refer to
|
Molecular orbital
|
Red/Blue
|
Filled orbitals
|
Yellow
|
Unfilled orbitals
|
Electrostatic potential
|
Red
|
Negative sites
|
Blue
|
Positive sites
|
Electrophilic (HOMO)
|
Blue
|
Site most susceptible to attack by a electrophile
|
Nucleophilic (LUMO)
|
Blue
|
Site most susceptible to attack by a nucleophile
|
3.8 Molecular simulation results
The computational Monte Carlo (MC) method was performed to study the adsorption behavior of (H4 & H5 & H6) on the carbon steel surface in the solution presence of H3O+, Cl− and H2O molecules. Side and top views of the adsorbed (H4 & H5 & H6) molecules on Fe surface are shown in Fig. 16. Computer simulations were achieved to understand how the inhibitors react with the carbon steel surface and how the geometrical structures of inhibitors molecules are arranged in Fe surface, the figure shows the protonated form of the inhibitor in solution. All inhibitor molecules arranged in superficial orientation on the Fe surface, which aids to form ideal coverage of the carbon steel surface. Adsorption could be understood as sending and receiving electrons at the HOMO and LUMO locations, which create coordination and back donation bonds, and electrostatic interaction can be represented as the other adsorbed sites on the Fe surface. The findings in Tables 13 and 14 give the calculated energies in vacuum and acid solution, respectively, such as total energy, adsorption energy, rigid absorption energy, and deformation energies. The (H4 & H5 & H6) inhibitor molecules are adsorbed in flat mode on the clean surface of Fe, allowing perfect interactions of N & O atoms and π-electrons with the surface of carbon steel. In addition, the inhibitor molecules detach H2O molecules from their adsorption sites and take their place, meaning that more inhibitors will displace H2O molecules by increasing the inhibitor molecules in the solution.49 The adsorption energy is, in fact, equal to the sum of the rigid energy of adsorption and the energy of deformation which is used to describe the adsorption of molecules on the metal surface. When the inhibitor molecules are adsorbed on the surface of Fe, the energy generated or adsorbed is called the rigid energy of adsorption. In all simulations, negative values of adsorption energy refer to a strong binding of (H4 & H5 & H6) on the Fe surface.50 This is because of the atoms (N and O), where the bonds of coordination can take place by granting the unoccupied iron orbital their unpaired electrons and a conjugated π-electron. The findings show that the negative adsorption energy values of inhibitors on the surface of carbon steel are in the following order: (H5 > H4 > H6), which means that the strong adsorption arrangement may be described as H6 > H4 > H5. This order is in line with the three inhibitors' practical % IE. The wet simulation (HCl) adsorption energy is greater than the medium of H3O and the medium of H2O. This indicates that the adsorption is enhanced by the involvement of water with the species Cl−.
|
|
Fig. 16 Top and side perspectives of the most stable structure of studied samples on the metal surface under acid solution conditions for MC simulations.
|
|
Table 13 Simulation results (total energy, adsorption energy, rigid absorption energy, and deformation energies) in vacuum
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