HOMO-LUMO Gap Research Articles

Oxidations of (2,2'-Diphenyl)ethylidene-Bridged Porphyrin Dimers.

Oxidation reactions of (2,2'-diphenyl)ethylidene-bridged porphyrin dimers were examined for the synthesis of (2,2'-diphenyl)ethylidene-inserted porphyrin arch tape dimers. These reactions provided, in addition to the target arch tape dimers, unexpected products such as a bicyclo[3.3.0]octane-fused porphyrin dimer, a (2,2'-fluorenyl)ethylidene-inserted porphyrin arch tape dimer, and a meso- and ortho-phenyl-linked free base dimer, depending upon the substrate and reaction conditions, demonstrating the high promise of these porphyrin substrates. The target arch tape dimers, which were synthesized by the oxidation with DDQ and CF3SO3H, exhibit red-shifted and enhanced Q-bands and small electrochemical HOMO-LUMO gaps, indicating effective conjugation.

Emission-Tunable B←N Lewis Pair-Functionalized Naphthalenes.

Herein, we simultaneously synthesized three different double B←N Lewis pair-functionalized naphthalenes including the asymmetric BNNY and BNNO and the mirror-symmetric BNNR, via a one-pot method. The annulation modes of the B←N Lewis pairs and the substituents on the boron atoms efficiently tune the molecular frontier orbitals and emission colors. α-Position fusion leads to a significant enhancement of the HOMO energy level and a decrease in the HOMO-LUMO gap, while the electron-withdrawing groups attached to the boron atom make the LUMO energy level more stable. In particular, the LUMO energy level of BNNO is as low as -3.12 eV. BNNY, BNNO, and BNNR emit cyan, green, and red fluorescence at 509, 534, and 620 nm, respectively, with fluorescence quantum yields of 24%, 49%, and 30%, respectively.

Impact of Transition Metal Decoration on the Electronic and Optical Properties of Polycyclic Aromatic Hydrocarbon “Naphthalene”- A DFT investigation

The transition metal doping on polycyclic aromatic hydrocarbons (PAHs) like naphthalene (C10H8) significantly changes its electronic as well as optical properties reflecting their potential applications in the field of optoelectronic devices such as light emitting diode, solar cell etc. In this study, we investigated the structural, electronic, and optical properties of pure C10H8 and TM (Cr, Mn, Fe, Co, Ni, and Cu) C10H8 by employing the B3LYP functional using density functional theory (DFT). Our calculation revealing binding energies in between 0.76-3.84 eV across the TM series, showing TM interaction with aromatic π-electron cloud. Charge transfer between TM and naphthalene compound is confirmed by Mulliken charge analysis indicating TMs acting as charge donors. Decoration of TM reducing the HOMO-LUMO gap from 4.74 eV for pure C10H8 to 2.90 eV, 2.87 eV, 3.17 eV, 2.88 eV, and 3.52eV for Cr, Mn, Fe, Co, Ni, and Cu respectively. Metal dependent electronic interaction leading to splitting of electronic states has been analyzed using density of states. Vibrational properties also calculated by analyzing IR showing extra peaks due to altered electron density while Raman spectra shoed a red shift. These findings underscore the potential of TM-decorated C10H8 in tunable optoelectronic applications.

Deep-Ultraviolet Transparent Nonlinear Optical Phosphates: A New Alternative to Conventional Borates.

Deep ultraviolet (DUV) nonlinear optical (NLO) crystals with balanced performance are crucial for extending laser wavelengths into the DUV region, essential for various laser applications. However, developing ideal DUV crystals is challenging due to stringent requirements: strong second-harmonic generation (SHG) response, short cut-off wavelength, and effective phase-matching behavior. DUV NLO borates, which feature π-conjugated groups, have garnered attention for their higher SHG coefficients compared to phosphates. However, phosphates typically show short UV cut-off edges due to the large HOMO-LUMO gap (approximately 9.6 eV) of the [PO₄] units. To enhance the SHG effect while maintaining DUV transparency in phosphates, several strategies have been proposed: 1) using distorted polymerized P-O groups like isolated C₁-[P₃O₁₀]⁵⁻ and [P₂O₇]⁴⁻; 2) aligning isolated [PO₄]³⁻ tetrahedra along the polar screw axis; 3) introducing additional NLO-active units; and 4) exploring new units derived from [PO₄]³⁻, such as [PO₃F]²⁻ tetrahedra. These strategies have led to the successful development of various non-centrosymmetric phosphates, highlighting their potential as DUV NLO candidates. This review explores the relationship between their crystal structures and DUV NLO performance, and proposes future directions for developing ideal DUV NLO materials.

Enhancing the Pressure-Sensitive Electrical Conductance of Self-Assembled Monolayers.

The inherent large HOMO-LUMO gap of alkyl thiol (CnS) self-assembled monolayers (SAMs) has limited their application in molecular electronics. This work demonstrates significant enhancement of mechano-electrical sensitivity in CnS SAMs by external compression, achieving a gauge factor (GF) of approximately 10 for C10S SAMs. This GF surpasses values reported for conjugated wires and DNA strands, highlighting the potential of CnS SAMs in mechanosensitive devices. Conductive atomic force microscopy (cAFM) investigations reveal a strong dependence of GF on the alkyl chain length in probe/CnS/Au junctions. This dependence arises from the combined influence of molecular tilting and probe penetration, facilitated by the low Young's modulus of alkyl chains. Theoretical simulations corroborate these findings, demonstrating a shift in the electrode Fermi level toward the molecular resonance region with increasing chain length and compression. Introducing a rigid graphene interlayer prevents probe penetration, resulting in a GF that is largely independent of the alkyl chain length. This highlights the critical role of probe penetration in maximizing mechano-electrical sensitivity. These findings pave the way for incorporating CnS SAMs into mechanosensitive and mechanocontrollable molecular electronic devices, including touch-sensitive electronic skin and advanced sensor technologies. This work demonstrates the potential of tailoring mechanical and electrical properties of SAMs through molecular engineering and interface modifications for optimized performance in specific applications.

Potential MAO-B Inhibitors from Cissampelos Capensis L.f.: ADMET, Molecular Docking, Dynamics, and DFT Insights.

This study explores the therapeutic potential of three proaporphine alkaloids-cissamaline, cissamanine, and cissamdine, which were recently isolated from Cissampelos capensis L.f., against Parkinson's disease (PD). Using computational techniques, we investigated their efficacy as inhibitors of a key protein in PD. ADMET analysis demonstrated that these alkaloids conform to the Lipinski, Pfizer, Golden Triangle, and GSK rules, indicating favorable safety, oral bioavailability, and a high probability of passing the human intestinal and blood-brain barriers. They were neither substrates nor inhibitors of any CYP enzymes tested, indicating minimal metabolic interference and an enhanced safety profile. Molecular docking studies revealed binding energies of -9.05 kcal/mol (cissamaline), -9.95 kcal/mol (cissamanine), and -10.65 kcal/mol (cissamdine) against MAO-B, a critical PD target, surpassing the control (zonisamide, -6.96 kcal/mol). The molecular interaction analyses were also promising, with interactions comparable to the control. Molecular dynamics (MD) simulations confirmed stable protein-ligand interactions, with root-mean-square deviation (RMSD) values ranging from 1.03 Å to 3.92 Å, root-mean-square fluctuation (RMSF) values remaining below 1.14 Å, and radius of gyration (RGyr) values between 20.20 Å and 20.50 Å, indicating compact structures. Hydrogen bonding analysis revealed maximum hydrogen bond counts of 6 (cissamanine), 5 (cissamaline), and 4 (cissamdine), demonstrating robust interactions with MAO-B. Density Functional Theory (DFT) calculations revealed the highest electrophilicity (ω =0.151), highest electron affinity (EA =0.075), and smallest HOMO-LUMO gap (ΔE =0.130) for cissamanine, indicating enhanced reactivity. These results advocate for further in vitro and in vivo studies to evaluate the compounds' potential as PD therapeutics.

Diarenofuran[b]-fused BODIPYs: One-Pot SNAr-Suzuki Synthesis and Properties.

We present a streamlined methodology that integrates regioselective tetrahalogen-BODIPY and o-hydroxyphenylboronic acid in a one-pot process, leveraging SNAr nucleophilic substitution in conjunction with Suzuki coupling to afford diarenofuran [b]-fused BODIPYs (DBFB1-9) with commendable yields (85-95%) and short reaction times (0.5-1.0 h). X-ray structure analyses of DBFB5,7-9 elucidate that these diarenofuran[b]-fused BODIPYs adopt a "butterfly" conformation, maintaining a highly rigid planarity. A comprehensive examination of the spectroscopic and electrochemical properties of these diarenofuran[b]-fused BODIPY derivatives, incorporating various substituents, reveals intriguing characteristics, including pronounced absorption and emission in the near-infrared region (NIR), elevated fluorescence quantum yields (ΦF = 75-89% in dichloromethane), and tunable HOMO-LUMO levels. Remarkably, compared to DBFB1-8, DBFB9 possesses a large extended π-conjugated system, resulting in significant red shifts in its absorption and emission maxima, reaching 623 and 635 nm, respectively, and a reduced HOMO-LUMO gap. Despite this substantial structural expansion, DBFB9 maintains a surprisingly high fluorescence quantum yield (ΦF = 80%), underscoring its exceptional photophysical performance and strong potential for applications requiring efficient NIR emission and robust fluorescence retention.

Understanding the Stability of Finite Double Walled Phenine and its Hybrid Structures using DFT Investigation

Abstract We have performed ab initio calculations based on density functional theory to investigate the structural and electronic properties
of finite double wall phenine nanotubes and their hybrid structures with armchair carbon nanotubes. The result shows that double wall
phenine nanotubes and the hybrid structures are quite stable. The stability of structure is strongly depends on inter-layer separation be-
tween the two tubes. The double walled phenine nanotubes are more stable than their corresponding pristine armchair tubes and exhibit
a semi-conducting nature with a HOMO-LUMO gap of 2.78eV and 2.80eV. The hybrid structures have a small electronic gap between
0.13eV-0.50eV similar to double wall armchair nanotubes. The results highlight the possibility of the synthesis of novel semi-conducting
double wall phenine structures.

The charge transport properties of dicyanomethylene-functionalised violanthrone derivatives.

The study of organic small molecule semiconductor materials as active components of organic electronic devices continues to attract considerable attention due to the range of advantages these molecules can offer. Here, we report the synthesis of three dicyanomethylene-functionalised violanthrone derivatives (3a, 3b and 3c) featuring different alkyl substituents. It is found that the introduction of the electron-deficient dicyanomethylene groups significantly improves the optical absorption compared to their previously reported precursors 2a-c. All compounds are p-type semiconductors with low HOMO-LUMO gaps (≈1.25 eV). The hole mobilities, measured from fabricated organic field-effect transistors, range from 3.6 × 10-6 to 1.0 × 10-2 cm2 V-1 s-1. We found that the compounds featuring linear alkyl chains (3b and 3c) displayed a higher mobility compared to the one with branched alkyl chains, 3a. This could be the result of the more highly disordered packing arrangement of this molecule in the solid state, induced by the branched side chains that hinder the formation of π-π stacking interactions. The influence of dicyanomethylene groups on the charge transport properties was most clearly observed in compound 3b which has a 60-fold improvement in mobility compared to 2b. This study demonstrates that the choice of the solubilising group has a profound effect on the hole mobility on these organic semiconductors.

DECOMPOSITION MECHANISM OF ALKYLIDENE BRIDGED TETRAZOLES WITH DIFFERENT CARBON CHAIN LENGTHS.

Nitrogen-rich heterocycles, particularly tetrazole-based high-energy density materials (HEDMs) offer high performance, low sensitivity, and are eco-friendly. Despite the diversity of nitrogen-rich energetic heterocycles, many are sensitive to external stimuli, and the introduction of a methylene, ethylene, or C-C linkage between nitrogen-rich heterocycles is a successful strategy to improve mechanical sensitivity and thermal stability. Understanding the potential anomalous thermal or kinetic behavior of such molecules is crucial for the design of new HEDMs and practical applications of these molecules. We have investigated the influence of introducing an alkylidene bridge between the energetic nitrogen heterocycles on the decomposition mechanism and pathway of different bridged tetrazoles, namely 5,5'-Bis-1H-tetrazole, 1,2-Bis(5-tetrazolo)methane, and 1,2-Bis(5-tetrazolo)ethane, using thermal experiments, mass spectrometry, and computational analysis. Kinetic parameters were evaluated using a non-linear integral method, and decomposition pathways were proposed based on mass fragmentation data. Stability comparisons were made using HOMO-LUMO gap and electrostatic potential (ESP) values from computational calculations.

Coupled Polymethine Dyes: Six Decades of Discoveries.

This review provides a comprehensive examination of the applications of the seminal coupling principle introduced by Siegfried Dähne and Dieter Leupold in 1966. Their heuristic and groundbreaking work proposed that combining multiple polymethine subunits within a single chromophore enables orbital coupling, consequently narrowing the HOMO-LUMO gap, and yielding redshifted optical properties. These outcomes are particularly valuable for developing organic dyes tailored for visible-to-near-infrared applications. Despite their potential, coupled polymethines remain relatively underexplored, with most reported instances being serendipitous discoveries over the last six decades. In light of this, our review compiles and discusses the reported coupled polymethine structures, covering synthetic, spectroscopic, theoretical and applicative aspects, offering insights into the structure-property relationships of this unique class of dyes and perspectives for their future applications.

Tailoring of electrocatalytic oxygen evolution reaction performance of 2D conductive Co-catecholate metal-organic frameworks

Herein, we report the microwave hydrothermal synthesis of highly porous and conductive 2D Co-catecholate MOFs (Co-CATs) in the absence (Co-CAT-WO) and presence (Co-CAT-W) of N-methyl-2-pyrrolidone (NMP) polar solvent, and the study of these Co-CATs as electrocatalysts for oxygen evolution reaction (OER). The OER performance of Co-CAT-WO and Co-CAT-W is compared. The as-synthesized Co-CATs exhibit a 2D layered hexagonal structure. The electrical conductivity of Co-CAT-WO and Co-CAT-W is 6.9 and 5.8 S/m, respectively. The good conductivity and porous structure can initiate charge transport to achieve better OER performance under the 4e--transfer process. The as-prepared Co-CAT-WO and Co-CAT-W, respectively, show an overpotential of 455 and 424 mV at 10 mA/cm2 after performing the durability and chronoamperometry experiments for 13 h in 1 M KOH. From the electrochemical studies, it is apparent that the Co-CAT-W exhibits better OER performance with low overpotential, high current density, and excellent stability over extended cycling. Moreover, the lower HOMO-LUMO gap for Co-CAT-W than that of the Co-CAT-WO endorses its better electrocatalytic activity. The post-OER results show that the Co-CAT-W electrocatalyst acts as a "precatalyst" rather than the original catalyst, and it undergoes electrochemical transformation to metal hydroxide and metal oxyhydroxide after the OER studies, promoting the OER kinetics. The findings of this work offer valuable insights into the synthetic strategies for developing 2D conducting metal-catecholate MOF catalysts for efficient and sustainable OER processes, which is crucial in water splitting for sustainable energy production.

Encapsulating Proton Inside C60 Fullerene: A Density Functional Theory Study on the Electronic Properties of Cationic X+@C60 (X+ = H+, H3O+ and NH4+).

Confining protons into an enclosed carbon cage is expected to give rise to unique electronic properties for both the inner proton and the outer cage. In this work, we systematically investigated the geometric and electronic structures of cationic X+@C60 (X+ = H+, H3O+, and NH4+), and their corresponding neutral species (X = H2O, NH3), by quantum chemical density functional theory calculations. We show that C60 can trap H2O, NH3, H3O+ and NH4+ at the cage center and only slightly influence their geometries. The single proton clings to the inner wall of C60, forming a C-H chemical bond. The encapsulated neutral species almost do not change the electronic structure of the C60, while the internal cations have obvious effects. The charge transfer effect from the inner species to the C60 cage was found for all X@C60 (X = H2O, NH3) (about 0.0 e), X+@C60 (X+ = H3O+, NH4+) (about 0.5 e) and H+@C60 (about 1.0 e) systems. Encapsulating different forms of protons also regulates the fundamental physico-chemical properties of the hollow C60, such as the HOMO-LUMO gaps, infrared spectra, and electrostatic potential, etc., which are discussed in detail. These findings provide a theoretical insight into protons' applications, especially in energy.

Electron transport and quantum phase transitions in cumulene-connected C80H20 fulleryne: DFT and tight-binding studies

Molecular bridges are opening up exciting new applications in diverse fields, improving the efficiency of conductive inks, enhancing the performance of devices such as organic light-emitting diodes and low-cost solar cells, and advancing the development of highly sensitive sensors, chemical reactions, drug delivery systems, and more. In this paper, we study the electron transport properties of a C80H20 fulleryne (dodecahedryne) connected to two cumulene electrodes. Using density functional theory (DFT), we determine the optimal molecular bridge structure. Based on the IR vibration spectra, different stable phases of the molecular bridge are obtained. The corresponding tight-binding (TB) parameters of the cage are obtained by assigning appropriate values of the length and type of bonds for the fulleryne cage through matching the HOMO-LUMO gap between the DFT calculations and the TB parameters. The electron transport for the desired structures is investigated using the obtained tight-binding parameters and the non-equilibrium Green's function (NEGF) method. Finally, it is concluded that among the five possible configurations for the cumulene-dodecahedryne -cumulene molecular bridge, only one specific configuration—where the electrodes are one edge apart—exhibits metallic behavior, while other positions act as insulators. In addition, the system exhibits quantum phase transitions from metal to semiconductor and from insulator to metal in the presence of critical electric fields. The ability to control quantum phase transitions in these molecular systems can be leveraged to develop qubits for quantum computing. The unique properties can be utilized to design advanced molecular electronic devices.

Probing the Electric Field Response of a Water Molecule Confined in Small Carbon Nanocages: A Density Functional Theory Investigation.

We consider a water molecule under tight confinement in the small-sized fullerenes (C , C , C ) within the density functional theory (DFT) calculations with suitable exchange-correlation functionals. Such nanoscopic molecular cages provide an ideal setup to study their characteristic properties not present in the condensed phase. The water molecule entirely loses its feature of typical water when it is confined in small fullerenes of size equal to C or smaller, in which the asymmetric O-H stretching vibration occurs at a lower wavenumber than the symmetric stretching. We study the response of the confined water molecule to the applied electric fields in terms of change in geometrical parameters, NMR spin-spin coupling constants, dipole moment, HOMO-LUMO (HL) gap, and vibrational frequency shift. The electric field shielding property of small-sized fullerene cages is explored and found to be strongly correlated with the HL gap. Since the electric field modulates the gap to decrease generally, shielding efficiency varies with field strength, thereby making large fields better shielded than small fields for the small penetration factor at large fields. The results that hold significance for technological applications are discussed.

One-Pot Divergent Synthesis of a 13-Ring Triquinone and its Facile Conversion to a [4.4.4]Tridecastarphene.

Acenes are notable for their optoelectronic properties and applications in organic electronics. Starphenes are structurally related molecules possessing three acene arms that radiate linearly from a central benzene ring (i. e., linearly annellated triphenylenes). Large starphenes have been prepared using convergent syntheses involving transition metal catalyzed cyclotrimerizations of either preformed acenes or arynes. Here, we report a one-pot divergent synthesis of a 13-ring triquinone that is readily converted to a [4.4.4]tridecastarphene derivative. The one-pot procedure involves the sequential reactions of three 1,4-anthraquinones with o-quinodimethane derivatives that are generated sequentially from a stable, trisulfone precursor. The resulting [4.4.4]tridecastarphene derivative bearing p-(t-butyl)phenyl substituents was characterized by 1H NMR, 13C NMR and UV-vis spectroscopies, as well as mass spectrometry, cyclic voltammetry and differential pulse voltammetry. Theoretical and experimental studies reveal a relatively high-lying HOMO orbital (about -4.70 to -4.86 eV) and a relatively small HOMO-LUMO gap (2.1 eV), suggesting utility as a p-type organic semiconductor. Our [4.4.4]tridecastarphene derivative photooxidizes in a CH2Cl2 solution exposed to ambient light and air with a half-life of 150 minutes at room temperature, but shows no sign of degradation after 12 months in the solid-state. Our [4.4.4]tridecastarphene derivative also shows excellent solubility in a number of organic solvents including dichloromethane, chloroform and toluene, potentially enabling printed electronic applications.

Consecutive Trifluoromethylation of C88(7) Fullerene: A Theoretical Study

AbstractThe trifluoromethylation of C88(7) fullerene has been systematically studied using an energy‐controlled consecutive CF3 addition approach. The thermodynamically favored C88(7)(CF3)2n isomers with 2n = 2–20 were predicted at the DFT B3LYP‐D3BJ/6–311G* level of theory for the first time, in harmony with the two experimentally characterized isomers C88(7)(CF3)12/16. It was found that these stable isomers are formed mainly by 1,4‐additions of CF3 groups, and meanwhile, there are a few stable isomers with isolated CF3 groups for 2n ≤ 12, with ortho addition for 2n > 12, and with triple‐hexagon‐junction addition for the highest degree of trifluoromethylation (2n ≥ 18). The addition patterns of CF3 groups were discussed in terms of the local structural motif of the pristine cage and the formation of stabilizing substructures of local aromaticity. The possible trifluoromethylation pathways of C88(7) were proposed on the basis of the relative Gibbs free energies. The results show that almost all the intermediate isomers for the thermodynamically most stable isomers of C88(7)(CF3)2n possess low relative Gibbs free energies (below 14 kJ·mol−1). Moreover, the hardness, chemical potential, electrophilicity index, electron affinity, HOMO and LUMO energies, and HOMO–LUMO gaps of the thermodynamically most stable C88(7)(CF3)2n isomers were also calculated.

A new chalcone derivative: Synthesis, crystal structure, Hirshfeld surface, quantum chemical investigations, Druggability and human Cathepsin D inhibitory activity

This paper presents the synthesis of a novel chalcone derivative, and its molecular structure has been determined by NMR and single-crystal X-ray diffraction analysis. The molecules are connected via OH⋅⋅⋅O, CH⋅⋅⋅O, and CH⋅⋅⋅S hydrogen bonds along with CH⋅⋅⋅π and π⋅⋅⋅π interactions. Hirshfeld surface studies have been conducted to comprehensively quantify the patterns of intermolecular interactions. DFT calculations provided insights into the nature of the molecule, including frontier molecular orbital, ADCH charge, Molecular Electrostatic Potential and Natural Bond Orbitals analysis using the optimized structure by B3LYP/6–311 G (d, p) level. The calculated HOMO-LUMO gap (3.23 eV) indicates decent softness and reactivity of the target molecule. The molecular docking studies reveal that the target compound exhibits a high binding affinity with Human Cathepsin D (CatD), with a docking score of -7.58 kcal/mol. The assessment of drug-likeness properties and ADMET (absorption, distribution, metabolism, excretion, and toxicity) profiles further support its potential as a potent CatD inhibitor candidate for medication development.

Loading of metformin on C24 fullerene decorated with alkaline earth metals: Molecular computational assessment for drug delivery

The discovery of new drug carriers is one of the interesting topics in biological sciences, which in recent years have been combined with theoretical chemistry to accelerate this process by using materials around nanometers in size. We used a novel approach based on molecular thermodynamics for analysis of nanomaterials with advanced structures for drug delivery applications. Fullerene and its derivatives have been evaluated in many studies as various drug agents and obtainable results have been achieved. Here, by trapping Mg and Ca atoms in the C24 cage, the electronic properties are improved to better interact with the metformin molecule. The adsorption energies were estimated using the developed quantum modeling approach. Adsorption energies are -4.98 eV, -5.91 and -6.07 eV for pure C24, Mg@C24, and Ca@C24, respectively. MEP and DOS plots indicated that reduction of the HOMO-LUMO gaps in the considered clusters creates a stronger connection between the MF molecule and the nanocage, and the electron localization function identified that the interaction kind is covalent.

Experimental and theoretical studies of a new NLO active organic salt of 2-amino-4-hydroxy-6-methylpyrimidine and 4-hydroxybenzoic acid

The new monohydrate organic salt (AHMPHB) of 2-amino-4-hydroxy-6-methylpyrimidine (AHMP) with 4-hydroxybenzoic acid (HBA) was successfully synthesized and grown as an organic single crystal with characteristic optical quality using the slow evaporation technique (SET). The structural study of the grown crystal was performed using single-crystal XRD. The XRD results revealed that AHMPHB belongs to the triclinic system with space group P-1. Various functional groups of AHMPHB were identified using Raman and FTIR spectroscopic analyses. The optimized geometry and other theoretical results were determined by the DFT/B3LYP method at the 6–311++G(d,p) basis set. The H⋅⋅⋅H and O⋅⋅⋅H intermolecular forces are dominated in the crystal packing and these were explored using Hirshfeld surface and fingerprint plot analyses. TG and DTA studies demonstrate that AHMPHB remains stable up to 140 °C. According to UV–Vis spectral analysis, AHMPHB has exhibited high transparency in the visible region with a direct band gap of 4.10 eV. The NLO measurement of AHMPHB was done using the Z-scan method. The energy of the HOMO-LUMO gap of 4.37 eV was predicted using DFT calculations. NBO analysis was performed to represent the charge transfer between localized bonds and lone pairs. Moreover, the MEP maps, HOMO-LUMO profiles and theoretical NLO parameters of AHMPHB and its constituents are also obtained.