Advances in solar cell technology require designing of new organic dye sensitizers for dye-sensitized solar cells with high power conversion efficiency to circumvent the disadvantages of silicon-based solar cells. In silico studies including quantitative structureproperty relationship analysis combined with quantum chemical analysis were employed to understand the primary electron transfer mechanism and photo-physical properties of 273 arylamine organic dyes from 11 diverse chemical families explicit to iodine electrolyte. The direct quantitative structure-property relationship models enable identification of the essential electronic and structural attributes necessary for quantifying the molecular prerequisites of 11 classes of arylamine organic dyes, responsible for high power conversion efficiency of dye-sensitized solar cells. Tetrahydroquinoline, N,N′-dialkylaniline and indoline have been least explored classes under arylamine organic dyes for dye-sensitized solar cells. Therefore, the identified properties from the corresponding quantitative structure-property relationship models of the mentioned classes were employed in designing of "lead dyes". Followed by, a series of electrochemical and photo-physical parameters were computed for designed dyes to check the required variables for electron flow of dye-sensitized solar cells. The combined computational techniques yielded seven promising lead dyes each for all three chemical classes considered. Significant (130, 183, and 46%) increment in predicted %power conversion efficiency was observed comparing with the existing dye with highest experimental %power conversion efficiency value for tetrahydroquinoline, N,N′-dialkylaniline and indoline, respectively maintaining required electrochemical parameters.
Seven ‘lead’ dye-sensitizers from Tetrahydroquinoline (THQ) family were proposed and designed based on the structural attributes via quantitative-structure property relationship (QSPR) modeling. They were screened rationally through different computational approaches to explore their potential applications as photosensitizers for dye-sensitized solar cells (DSSCs). Compelling photophysical properties such as electron injection driving force, electron injection time, and dye regeneration were studied for the isolated dyes under the DFT and TD-DFT frameworks. Index of spatial extent (S, D, and ∆q), the strength of charge transfer and separation along with the charge transfer process is explored. First principle approach including van der Waals density functional calculation of dye@TiO2 interface indicates that all of the designed dyes have optimal interfacial behavior. Bader charge analysis, partial density of state (PDOS), charge density and electrostatic potential difference calculation confirms that THQ7 and THQ9 are the most efficient dye-sensitizers. The other five designed dyes also possess the required properties to emerge as effective dye-sensitizers potentially better than those already utilized.
Seven D−A−π−A-based indoline (IND) dyes that were designed via quantitative-structure−property relationship modeling have been comprehensively investigated using computational approaches to evaluate their prospect of application in future dye-sensitized solar cells (DSSCs). An array of optoelectronic properties of the isolated dye and dyes adsorbed on a TiO 2 cluster that simulates the semiconductor were explored by density functional theory (DFT) and time-dependent DFT methods. Light absorption spectra, vertical dipole moment, shift of the conduction band of semiconductor, excited state lifetime, driving force of electron injection, photostability of the excited state, and exciton binding energy were computed. Our study showed that the presence of an internal acceptor such as pyrido[3,4-b]pyrazine (pyrazine) would influence greater the open circuit voltage (V OC ), compared to the benzothiadiazole moiety. Considering the balance between the V OC and J SC (short circuit current) along with the all calculated characteristics, the IND3, IND5, and IND10 are the most suited among the designed dyes to be used as potential candidates for the photo-efficient DSSCs. The present study provides the results of rational molecular design followed by exploration of photophysical properties to be used as a valuable reference for the synthesis of photo-efficient dyes for DSSCs.
The D–D−π–A framework based dyes are competent for lowering the aggregation and reducing the charge recombination inherently due to their 3D structures. Seven D–D−π–A-based N,N′-diphenyl-aniline (NNdPA) dyes are designed and investigated using cluster and periodic density functional theory (DFT) approaches to evaluate their prospect of application in the future dye-sensitized solar cells (DSSCs). The critical parameters related to short-circuit photocurrent density (J SC ) and open-circuit voltage (V OC ) of the considered dyes such as the driving force of electron injection (ΔG Inject ), the spontaneity of dye regeneration (ΔG Reg ), the exciton binding synergy (E b ), the charge transfer length (d CT ), the reorganization energy (λ Total ), the shift of the conduction band of TiO2 (ΔE CB ), the projected density of states (PDOS), and the chemical reactivity parameters were computed. Computed results implied that the fused π-conjugation bridge, along with the benzothiadiazole (BTD) unit, improves the absorption spectrum and charge separation. Also, incorporation of the benzene ring lowers λ Total with balancing its counterparts’ reorganization energy. Considering the dye characteristics after electron injection, NNdPA04 with large Stokes shift would possess the most stable excited state due to longer excited state lifetime, τ e , with the lowest driving force between excited state oxidation potential and conduction band minimum of TiO2. We found that the presence of the benzene ring in the fused π-conjugation unit increases the light harvesting by shifting the UV–vis spectrum to a longer wavelength. The values of ΔE CB and ΔG Reg suggest that the NNdPA04 and NNdPA10 would be able to suppress the charge recombination and thus enhance V OC of NNdPA-based dyes. The outcomes inferred that the designed NNdPA04 dye could be the lead candidate for the photoefficient NNdPA-based DSSCs. Our work also provides a rational insight into designing the D–D−π–A dyes with a fused π-conjugation.
Post silicon solar cell era involves light-absorbing dyes for dye-sensitized solar systems (DSSCs). Therefore, there is great interest in the design of competent organic dyes for DSSCs with high power conversion efficiency (PCE) to bypass some of the disadvantages of silicon-based solar cell technologies, such as high cost, heavy weight, limited silicon resources, and production methods that lead to high environmental pollution. The DSSC has the unique feature of a distance-dependent electron transfer step. This depends on the relative position of the sensitized organic dye in the metal oxide composite system. In the present work, we developed quantitative structure-property relationship (QSPR) models to set up the quantitative relationship between the overall PCE and quantum chemical molecular descriptors. They were calculated from density functional theory (DFT) and time-dependent DFT (TD-DFT) methods as well as from DRAGON software. This allows for understanding the basic electron transfer mechanism along with the structural attributes of arylamine-organic dye sensitizers for the DSSCs explicit to cobalt electrolyte. The identified properties and structural fragments are particularly valuable for guiding time-saving synthetic efforts for development of efficient arylamine organic dyes with improved power conversion efficiency.
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