Determining Optical Band Gaps of MOFs

Fabrizio, Kevin; Lê, Khoa N.; Andreeva, A. B.; Hendon, Christopher H.; Brozek, Carl K.

doi:10.1021/acsmaterialslett.1c00836

Cited by 32 publications

(29 citation statements)

References 49 publications

(74 reference statements)

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“…According to Figure c(i–iii), the diffuse reflectance spectra (DRS) were applied to specify the band gap energy. The band gap energy can be precisely calculated based on computational routes, such as Kubelka Munk or Tauc plot approaches . The highest energy gap was attained in the order of ZnO NRs, Fe 3 O 4 NPs, and the Fe 3 O 4 @PVA–Au/ZnO magnetic photocatalytic system.…”

Section: Results and Discussionmentioning

confidence: 99%

“…The band gap energy can be precisely calculated based on computational routes, such as Kubelka Munk or Tauc plot approaches. 66 The highest energy gap was attained in the order of ZnO NRs, Fe 3 O 4 NPs, and the Fe 3 O 4 @PVA−Au/ZnO magnetic photocatalytic system. The electron transition from the valence band (VB) to the conduction band (CB) of Au with a band gap value of 3.4 eV provides exciton (electron−hole pairs).…”

Section: Optimization Of the Conditions And Photocatalyticmentioning

confidence: 95%

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Efficient Photodegradation of Eriochrome Black-T by a Trimetallic Magnetic Self-Synthesized Nanophotocatalyst Based on Zn/Au/Fe-Embedded Poly(vinyl alcohol)

et al. 2022

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This study presents a novel photocatalytic system for photocatalytic degradation of Eriochrome black-T (EBT) dye via green light-emitting diode (LED) light exposure. This photocatalyst is comprised of nanoscale components, i.e., poly-(vinyl alcohol) (PVA), magnetic iron oxide nanoparticles (Fe 3 O 4 NPs), gold NPs (Au NPs), and zinc oxide nanorods (ZnO NRs), rendering an active high surface area. The most highlighted property from the structural facet is the superparamagnetic behavior of Fe 3 O 4 NPs, which provides a facile collection of magnetic photocatalyst NPs from the reaction flask and is successfully recycled eight times without considerable reduction in catalytic behavior. Briefly, the photocatalytic degradation at its highest efficiency reached 51.4% (10 ppm dye solution, 5.0 mL) and 64.75% (8 ppm dye solution, 5.0 mL) utilizing 10 mg of the designed photocatalyst (formulated as Fe 3 O 4 @PVA−Au/ZnO), a magnetic photocatalytic system under green LED light (7 W, 526 nm) exposure for 60 min. Besides, the photocatalytic degradation mechanism of the EBT dye by the as-prepared photocatalyst was proposed. Based on the obtained results, the presented photocatalytic method was recommended for scaling up and large-scale exploitation for the purification of the water resources.

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Section: Results and Discussionmentioning

confidence: 99%

Section: Optimization Of the Conditions And Photocatalyticmentioning

confidence: 95%

Efficient Photodegradation of Eriochrome Black-T by a Trimetallic Magnetic Self-Synthesized Nanophotocatalyst Based on Zn/Au/Fe-Embedded Poly(vinyl alcohol)

et al. 2022

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show abstract

“…Skillful exploration of data through data-mining and big data approaches as well as electronic structure modeling have greatly benefited the fields of MOFs and perovskites. 103,[110][111][112][113][114][115][116][117][118][119] Machine learning and high throughput techniques have been routinely em-ployed to screen the chemical space of hybrid materials with the goal of proposing new MOF and perovskite structures that are suitable for industrial applications, including but not limited to catalysis, [120][121][122][123] gas storage and separation, 124 and optoelectronics. [125][126][127][128] While materials modeling based on data-driven approaches has achieved some remarkable success in predicting electronic properties (e.g., band gaps, charge densities, electronic couplings, oscillator strengths, etc.…”

Section: Introductionmentioning

confidence: 99%

Connecting the dots for fundamental understanding of structure–photophysics–property relationships of COFs, MOFs, and perovskites using a Multiparticle Holstein Formalism

Ghosh

Paesani

2023

Chem. Sci.

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“…Skillful exploration of data through data-mining and big data approaches as well as electronic structure modeling have greatly benefited the fields of MOFs and perovskites. 103,[110][111][112][113][114][115][116][117][118][119] Machine learning and high throughput techniques have been routinely employed to screen the chemical space of hybrid materials with the goal of proposing new MOF and perovskite structures that are suitable for different applications, including but not limited to catalysis, [120][121][122][123] gas storage and separation, 124 and optoelectronics. [125][126][127][128] While materials modeling based on data-driven approaches has achieved some remarkable success in predicting electronic properties (e.g., band gaps, charge densities, electronic couplings, oscillator strengths, etc.…”

Section: Introductionmentioning

confidence: 99%

Connecting the Dots for Fundamental Understanding of Structure-Photophysics-Property Relationships of COFs, MOFs, and Perovskites using a Multiparticle Holstein Formalism

Ghosh

Paesani

2022

Preprint

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Photoactive organic and hybrid organic-inorganic materials, such as conjugated polymers, covalent organic frameworks (COFs), metal-organic frameworks (MOFs), and layered perovskites, display intriguing photophysical signatures upon interaction with light. Elucidating structure-photophysics-property relationships across a broad range of functional materials is nontrivial and requires our fundamental understanding of the intricate interplay among excitons (electron-hole pair), polarons (charges), bipolarons, phonons (vibrations), inter-layer stacking interactions, and different forms of structural and conformational defects. In parallel with electronic structure modeling and data-driven science that are actively pursued to successfully accelerate materials discovery, an accurate, computationally inexpensive, and physically-motivated theoretical model, which consistently makes quantitative connections with conceptually complicated experimental observations, is equally important. Within this context, the first part of this Perspective highlights a unified theoretical framework in which the electronic coupling as well as the local coupling between the electronic and nuclear degrees of freedom can be efficiently described for a wide range of quasiparticles with similarly structured Holstein-style Hamiltonians. The second part of this Perspective discusses excitonic and polaronic photophysical signatures in polymers, COFs, MOFs, and perovskites, and makes a unique attempt to bridge the gap between different research fields using a common theoretical construct - the Multiparticle Holstein Formalism. We envision that the synergistic integration of state-of-the-art computational approaches with the Multiparticle Holstein Formalism will help identify and establish new, transformative design strategies that will guide the synthesis and characterization of next-generation energy materials optimized for a broad range of optoelectronic, spintronic, and photonic applications.

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Determining Optical Band Gaps of MOFs

Cited by 32 publications

References 49 publications

Efficient Photodegradation of Eriochrome Black-T by a Trimetallic Magnetic Self-Synthesized Nanophotocatalyst Based on Zn/Au/Fe-Embedded Poly(vinyl alcohol)

Efficient Photodegradation of Eriochrome Black-T by a Trimetallic Magnetic Self-Synthesized Nanophotocatalyst Based on Zn/Au/Fe-Embedded Poly(vinyl alcohol)

Connecting the dots for fundamental understanding of structure–photophysics–property relationships of COFs, MOFs, and perovskites using a Multiparticle Holstein Formalism

Connecting the Dots for Fundamental Understanding of Structure-Photophysics-Property Relationships of COFs, MOFs, and Perovskites using a Multiparticle Holstein Formalism

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