5 results on '"Aquino, Adelia J. A."'
Search Results
2. A comprehensive analysis of charge transfer effects on donor‐pyrene (bridge)‐acceptor systems using different substituents.
- Author
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Borges, Itamar, Guimarães, Roberta M. P. O., Monteiro‐de‐Castro, Gabriel, Rosa, Nathália M. P., Nieman, Reed, Lischka, Hans, and Aquino, Adelia J. A.
- Subjects
CHARGE transfer ,ELECTRON donors ,POLYCYCLIC aromatic hydrocarbons ,SOLAR cells ,ORGANIC compounds ,ELECTROPHILES - Abstract
The alternant polycyclic aromatic hydrocarbon pyrene has photophysical properties that can be tuned with different donor and acceptor substituents. Recently, a D (donor)‐Pyrene (bridge)‐A (acceptor) system, DPA, with the electron donor N,N‐dimethylaniline (DMA), and the electron acceptor trifluoromethylphenyl (TFM), was investigated by means of time‐resolved spectroscopic measurements (J. Phys. Chem. Lett. 2021, 12, 2226–2231). DPA shows great promise for potential applications in organic electronic devices. In this work, we used the ab initio second‐order algebraic diagrammatic construction method ADC(2) to investigate the excited‐state properties of a series of analogous DPA systems, including the originally synthesized DPAs. The additionally investigated substituents were amino, fluorine, and methoxy as donors and nitrile and nitro groups as acceptors. The focus of this work was on characterizing the lowest excited singlet states regarding charge transfer (CT) and local excitation (LE) characters. For the DMA‐pyrene‐TFM system, the ADC(2) calculations show two initial electronic states relevant for interpreting the photodynamics. The bright S1 state is locally excited within the pyrene moiety, and an S2 state is localized ~0.5 eV above S1 and characterized as a donor to pyrene CT state. HOMO and LUMO energies were employed to assess the efficiency of the DPA compounds for organic photovoltaics (OPVs). HOMO‐LUMO and optical gaps were used to estimate power conversion and light‐harvesting efficiencies for practical applications in organic solar cells. Considering the systems using smaller D/A substituents, compounds with the strong acceptor NO2 substituent group show enhanced CT and promising properties for use in OPVs. Some of the other compounds with small substituents are also found to be competitive in this regard. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
3. Adsorption process of polar and nonpolar compounds in a nanopore model of humic substances.
- Author
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Tunega, Daniel, Gerzabek, Martin H., Haberhauer, Georg, Lischka, Hans, Solc, Roland, and Aquino, Adelia J. A.
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HUMUS ,POLAR molecules ,MCPA (Herbicide) ,CONSTRAINTS (Physics) ,POLYCYCLIC aromatic hydrocarbons - Abstract
Humic substances (HSs) as a major part of soil organic matter (SOM) are complex combinations of natural organic matter, which are ubiquitous in the environment and occur predominantly in soils, residues and natural water. They play a crucial role in the fate and behaviour of contaminants in the environment. In this work, an HS nanopore model was based on a structural motif containing polar and nonpolar domains. The polar domain was represented by the carboxyl groups that predominate in the composition of HSs, whereas the nonpolar domain was constructed by aliphatic chains. The effect of hydrophobic/hydrophilic interactions on sorption in HSs was analysed by the inclusion of the nonpolar polycyclic aromatic hydrocarbon naphthalene and the polar herbicide 2‐methyl‐4‐chlorophenoxyacetic acid (MCPA) in the nanopore. Water cluster was also included to allow the formation of the water molecular bridges (WaMB), which stabilized the whole system. Thermodynamic potential‐of‐mean‐force (PMF) calculations by means of classical molecular dynamics simulations were performed to investigate the effect of polar and nonpolar domains in the adsorption mechanism. The polar MCPA molecule was stabilized at the hydrophilic water–HS interface, whereas nonpolar naphthalene was stabilized inside of the hydrophobic nanovoid of the HS nanopore model. The obtained results demonstrated that the adsorption strength of HSs regarding polar and nonpolar species is similar, but the adsorption mechanisms differ. Highlights: The work elucidates the adsorption mechanism of polar and nonpolar species in SOM at the molecular scale.The derived HS model was suitable to describe and explain the adsorption properties of SOM by means of constrained molecular dynamics simulations.Adsorption mechanisms for polar and nonpolar species in SOM differ. Polar molecules prefer the water–SOM interface, whereas nonpolar molecules are trapped in hydrophobic nanovoids of SOM.Molecular dynamics simulation is an effective method providing a detailed description of the adsorption processes in SOM. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
4. Structures and binding energies for complexations of different spin states of Ni+ and Ni2+ to aromatic molecules.
- Author
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Kerkeni, Boutheïna, Aquino, Adelia J. A., Berman, Michael R., and Hase, William L.
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BINDING energy , *POLYCYCLIC aromatic hydrocarbons , *ELECTRON configuration , *COMPLEXATION reactions , *ELECTRON affinity , *NUCLEAR spin - Abstract
Density functional theory calculations, using the B3LYP parameterisation, were performed to determine structures, vibrational frequencies, and binding energies for complexation of Ni+ and Ni2+ cations with benzene and naphthalene molecules and clusters. The calculations employed the Stuttgart basis set with ECP pseudo potentials for the Ni cations and basis sets of at least triple ζ plus polarisation, and diffuse quality for C and H. The effect of electron correlation on non-bonded interactions was accounted for by the Grimme GD3 dispersion correction. Counterpoise computations were made for BSSE. Comparison between experiment and theory provide fascinating new insight into the bonding for these prototypical organometallic (OM) complexes. These structures have a sandwich topology, indicating major structural reorganisations occuring when benzene or naphthalene interact with Ni cations. Adiabatic electron affinities and ionisation potentials agree well with experiment when available. Binding energies were also determined, providing insight into the stability of the complexes. The results presented here provide important information for future studies to address additional investigations of both problems of the electronic structure properties of these complexes, as well as the role of the polycyclic aromatic hydrocarbons (PAHs) in the interstellar medium (ISM) and soot formation in combustion. The Ni+/Ni2+ + aromatic organometallic bonding is of the same order of stability as an aromatic C–H bond. Such bonding modifies the IR spectrum of the complexed aromatic molecules by enhancing the 3.3 μm feature and decreasing the C–H bands in the 11–12 μm range (γ C–H). Organometallic complexation reactions may contribute significantly to metal depletion in the ISM. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
5. A theoretical study of carbon-based functionalized materials
- Author
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Nieman, Reed, Lischka, Hans, Aquino, Adelia J. A., and Krempner, Clemens
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Photovoltaics ,Biradical ,Graphene ,Multireference ,DFT ,Polycyclic aromatic hydrocarbons - Abstract
This dissertation will examine the electronic properties of several materials used in state-of-the art technology and ongoing scientific investigation by means of high-level ab initio quantum chemical calculations. In this way, the application of such calculations to graphene reactivity and defects, organic photovoltaic processes, and excited states and biradical character of polycyclic aromatic hydrocarbons (PAH) is presented. Graphene reactivity and defect characterization is currently the source of intense scrutiny. The reactivity of pristine graphene and single and double carbon vacancies toward a hydrogen radical was assessed using complete active space self-consistent field theory (CASSCF) and multireference configuration interaction singles and doubles (MR-CISD) calculations using a pyrene model. While all carbon centers formed stable, novel C-H bonds, the single carbon defect was found to be most stabilizing thanks to the dangling bond at the six-membered ring. Bonding at this carbon center shows interaction with several closely-spaced electronic excited states. A rigid scan was also used to show the dynamic landscape of the potential energy surfaces of these structures. Double carbon vacancy pyrene and circumpyrene were used to investigate the structure and electronic states of an intrinsic silicon impurity in graphene by density functional theory (DFT) methods. The ground state was found to be low spin, non-planar and D2 symmetric with a nearby low spin, planar state with D2h symmetry. Characterization with natural bond orbital (NBO) analyses showed that the hybridization in the non-planar structure is sp3 and sp2d in the planar structure. Charge transfer from the silicon dopant to the surrounding carbon atoms is demonstrated via analysis with natural charges and molecular electrostatic potential (MEP) plots. Experiment shows drastically enhanced power conversion efficiency (PCE) in a bulk heterojunction (BHJ) device consisting of poly(3-hexylthiophene-2, 5-diyl) (P3HT), terthiophene (T3), and fullerene (C60). This BHJ scheme was investigated using DFT and several environmental models. The state-specific (SS) environment was found to best reproduce the experimental findings showing that initial photoexcitation of a local, bright exciton at P3HT was able to decay through several charge transfer (CT) bands of P3HT→C60 and T3→C60 character explaining the increased PCE. The spectra calculated for the isolated system and linear response (LR) environment were very similar to each other and showed the initial photoexcitation at P3HT decayed instead into bands of local C60 excitonic states quenching the CT states. Crucial benchmark calculations of the structure and electronic excited states missing from the current literature were performed for oligomers of poly(p-phenylenevinylene) (PPV) dimers using high-level scaled opposite-spin (SOS) second-order Møller-Plesset (SOS-MP2) and second-order algebraic diagrammatic construction (SOS-ADC(2)) calculations. Comparisons were also made to DFT methods. The dimer structures were studied in two conformations: sandwich-stacked and displaced; the latter exhibited greater stacking interactions. Good agreement was found between the cc-pVQZ and aug-cc-pVQZ basis sets and the cc-pVTZ basis. Comparisons of the interaction energies were made to the complete basis set limit. Basis set superposition error was also accounted for. The excited state spectra presented a varied and dynamic picture that was analyzed using transition density matrices and natural transition orbitals (NTOs). The assessment of the biradical character of several trans-diindenoacenes, cis-diindenoacenes, and trans-indenoindenodi(acenothiophenes) was accomplished utilizing the multireference averaged quadratic coupled-cluster (MR-AQCC) method. These systems have been previously identified as highly reactive in experiments, often subject to unplanned side-reactions. The biradical character was characterized using the singlet-triplet splitting energy (∆ES-T), effective number of unpaired electrons (NU), and unpaired electron density. For all structures, low spin ground states were found. In addition, increasing the number of core benzene rings decreased the ∆ES-T, increased the NU, and increased the unpaired electron density. Good agreement to experimental values for the ∆ES-T is also demonstrated.
- Published
- 2019
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