Modeling and Simulation of Reaction Environment in Photoredox Catalysis: A Critical Review

Oliveira, Gabriela Xavier de; Lira, Jéssica Oliveira de Brito; Riella, Humberto Gracher; Soares, Cíntia; Padoin, Natan

doi:10.3389/fceng.2021.788653

Cited by 4 publications

(3 citation statements)

References 119 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Leveraging this data, a light source model is formulated, which then facilitates the simulation of the maximal photon flux reaching the reaction mixture. This simulation employs ray-tracing, [14][15][16] taking into account the reactor's material composition and geometric design. Armed with this insight, the experimental outcomes of chemical actinometry are repurposed to discern the effective optical path length rather than the photon flux.…”

Section: Introductionmentioning

confidence: 99%

A facile strategy to determine photon flux and effective optical path length in intensified continuous-flow photoreactors

Zondag,

Schuurmans,

Chaudhuri

et al. 2024

Preprint

View full text Add to dashboard Cite

Photocatalysis for small molecule activation has seen significant advancements over the past decade, yet its scale-up remains a challenge due to photon attenuation effects. A promising solution lies in harnessing high photonic intensities paired with continuous-flow reactor technology. However, a deep grasp of photon transport is essential, typically demanding resource-intensive experiments. To address this, we introduce an innovative approach to photochemical reactor setup characterization, starting with radiometric light source analysis and progressing to a 3D reactor simulation for photon flux determination. Contrary to conventional techniques that prioritize complete photon absorption, our technique operates optimally when the reaction mixture is unsaturated. This strategy decouples photon flux and path length determination, substantially curtailing the experimental process. The workflow proves versatile across various reactor systems, simplifying intricate light interactions into a single one-dimensional parameter, i.e., the effective optical path length. Combined with the photon flux, this parameter effectively characterizes photochemical setups, irrespective of scale, geometry, light intensity, or photocatalyst concentration. Employing radiometry further offers insights into light source positioning and reactor design, and obviates the need for repeated chemical actinometry measurements due to light source degradation. Additionally, the proposed workflow facilitates experiments at lower concentrations, ensuring optimal reactor operation. In essence, our approach provides a thorough, efficient, and consistent framework for reactor irradiation characterization.

show abstract

Section: Introductionmentioning

confidence: 99%

A facile strategy to determine photon flux and effective optical path length in intensified continuous-flow photoreactors

Zondag,

Schuurmans,

Chaudhuri

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…Furthermore, computational modeling guides the design and optimization of metal-organic frameworks (MOFs) for photocatalysis [27,28], emphasizing the tailoring of band edge positions to achieve optimal photocatalytic performance. Additionally, the application of modeling and simulation through computational fluid dynamics (CFD) proves critical in the design and optimization of microreactors employed in photoredox catalysis [29,30]. This computational approach enhances our understanding of reagent interactions and the influence of light within the reaction medium.…”

Section: Introductionmentioning

confidence: 99%

Advances in Computational Methods for Modeling Photocatalytic Reactions: A Review of Recent Developments

Gusarov

2024

Materials

View full text Add to dashboard Cite

Photocatalysis is a fascinating process in which a photocatalyst plays a pivotal role in driving a chemical reaction when exposed to light. Its capacity to harness light energy triggers a cascade of reactions that lead to the formation of intermediate compounds, culminating in the desired final product(s). The essence of this process is the interaction between the photocatalyst’s excited state and its specific interactions with reactants, resulting in the creation of intermediates. The process’s appeal is further enhanced by its cyclic nature—the photocatalyst is rejuvenated after each cycle, ensuring ongoing and sustainable catalytic action. Nevertheless, comprehending the photocatalytic process through the modeling of photoactive materials and molecular devices demands advanced computational techniques founded on effective quantum chemistry methods, multiscale modeling, and machine learning. This review analyzes contemporary theoretical methods, spanning a range of lengths and accuracy scales, and assesses the strengths and limitations of these methods. It also explores the future challenges in modeling complex nano-photocatalysts, underscoring the necessity of integrating various methods hierarchically to optimize resource distribution across different scales. Additionally, the discussion includes the role of excited state chemistry, a crucial element in understanding photocatalysis.

show abstract

“…The CFD simulation provides the parameters having a considerable effect on the product yield, which leads to performing fewer experimental investigations and helps to study a wider range of operating parameters [17]. The photoredox catalysis process in a microreactor was investigated using CFD to gain more detailed understanding of the process, design, and optimization of microreactors [19].…”

Section: Introductionmentioning

confidence: 99%

Modeling and Simulation of N‐(3‐Aminio‐4 methylphenyl)benzamide Synthesis in a Microreactor

Cao,

Ghadiri

2023

Chem Eng & Technol

View full text Add to dashboard Cite

N‐(3‐Amino‐4‐methylphenyl)benzamide is an intermediate product for the production of several medicines. Microreactor technology is a new concept for the continuous synthesis of chemicals. The computational fluid dynamics method was used to simulate the flow synthesis of N‐(3‐amino‐4‐methylphenyl)benzamide. There was good agreement between experimental data and modeling outputs. The effect of operating parameters such as temperature and residence time on system performance was investigated. The results revealed that an increase in temperature from 30 to 70 °C led to the enhancement of N‐(3‐amino‐4‐methylphenyl)benzamide production from about 42 to 76 % at a residence time of 420 s. It was found that the residence time and temperature have the largest influence on N‐(3‐amino‐4‐methylphenyl)benzamide production. Byproduct production was also increased by increasing the temperature and residence time.

show abstract

Modeling and Simulation of Reaction Environment in Photoredox Catalysis: A Critical Review

Cited by 4 publications

References 119 publications

A facile strategy to determine photon flux and effective optical path length in intensified continuous-flow photoreactors

A facile strategy to determine photon flux and effective optical path length in intensified continuous-flow photoreactors

Advances in Computational Methods for Modeling Photocatalytic Reactions: A Review of Recent Developments

Modeling and Simulation of N‐(3‐Aminio‐4 methylphenyl)benzamide Synthesis in a Microreactor

Contact Info

Product

Resources

About