Evolution of Catalysts Directed by Genetic Algorithms in a Plug-Based Microfluidic Device Tested with Oxidation of Methane by Oxygen

Kreutz, Jason E.; Shukhaev, Anton; Du, Wenbin; Druskin, Sasha C.; Daugulis, Olafs; Ismagilov, Rustem F.

doi:10.1021/ja909853x

Cited by 118 publications

(93 citation statements)

References 79 publications

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“…The group of Ismagilov used this evolution protocol to determine a new generation of active homogeneous catalyst systems for the aerobic oxidation of methane to methanol. 162 Parameters chosen were the catalysts itself (gene A), co-catalysts (gene B) and ligands (gene C). Microfluidic devices were used in order to run numerous reactions in parallel while minimizing consumption of reagents, reducing waste and improving safety.…”

Section: Transition Metal-catalyzed Aerobic Oxidation Processes In Comentioning

confidence: 99%

Liquid phase oxidation chemistry in continuous-flow microreactors

et al. 2016

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Continuous-flow liquid phase oxidation chemistry in microreactors receives a lot of attention as the reactor provides enhanced heat and mass transfer characteristics, safe use of hazardous oxidants, high interfacial areas, and scale-up potential. In this review, an up-to-date overview of both technological and chemical aspects of liquid phase oxidation chemistry in continuous-flow microreactors is given. A description of mass and heat transfer phenomena is provided and fundamental principles are deduced which can be used to make a judicious choice for a suitable reactor. In addition, the safety aspects of continuous-flow technology are discussed. Next, oxidation chemistry in flow is discussed, including the use of oxygen, hydrogen peroxide, ozone and other oxidants in flow. Finally, the scale-up potential for continuous-flow reactors is described.

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Section: Transition Metal-catalyzed Aerobic Oxidation Processes In Comentioning

confidence: 99%

Liquid phase oxidation chemistry in continuous-flow microreactors

et al. 2016

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“…The requirement of two oxidation states has been a particularly vexing issue with these systems, and the development of processes with oxidants other than Pt IV has been challenging. [20,54,55] Periana et al developed an alternative to Pt IV as a stoichiometric oxidant in Pt-catalyzed methane functionalization. [14] The reaction of methane in sulfuric acid catalyzed by (bpym)PtCl 2 (bpym = 2,2'-bipyrimidine) produces methyl bisulfate in greater than 70 % yield based on methane [Equation (2)].…”

mentioning

confidence: 99%

Catalytic Oxy‐Functionalization of Methane and Other Hydrocarbons: Fundamental Advancements and New Strategies

Webb¹,

Bolaño²,

Gunnoe³

2010

ChemSusChem

116

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“…The high-throughput and spatial separation of samples make droplet microfluidics perfectly suitable for discovery chemistry-screening the libraries of compounds in search of, e.g. new catalysts (Goodell et al, 2009;Kreutz et al, 2010). Droplet microfluidics is also a perfect tool to investigate the chemical communication of compartments comprising chemical oscillators such as the Belousov-Zhabotinsky reaction (Guzowski et al, 2016).…”

Section: Chemistry In Dropletsmentioning

confidence: 99%

Droplet Microfluidics as a Tool for the Generation of Granular Matters and Functional Emulsions

Opalski

Kamiński

Garstecki

2019

KONA

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Emulsion-a liquid dispersed in another liquid-is in many respects very similar to granular matter. In the early 2000s a new technology-droplet microfluidics-began emerging from the wider field of microfluidics. Droplet microfluidics was quickly established as a discipline of science and engineering and has been used for the generation of highly uniform emulsions. The last few years have brought significant advances to the field, directed towards a wide range of applications in material sciences-from synthesis of nanoparticles in droplets to assembling complex droplets and using droplets as templates for ordered materials, with applications in food, cosmetic and diagnostic industries. Droplet microfluidic platforms are also successfully used as analytical tools in molecular biology and biochemistry, in e.g. high-throughput screening, digital assays, encapsulation of single cells, sequencing technologies, and in point-of-care diagnostic applications. This article provides an accessible overview of the physical phenomena observed in multiphase flow at the microscale and the techniques in droplet microfluidics systems. We also present the most interesting applications and potential further directions of research in this fascinating young field of science and engineering.

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Evolution of Catalysts Directed by Genetic Algorithms in a Plug-Based Microfluidic Device Tested with Oxidation of Methane by Oxygen

Cited by 118 publications

References 79 publications

Liquid phase oxidation chemistry in continuous-flow microreactors

Liquid phase oxidation chemistry in continuous-flow microreactors

Catalytic Oxy‐Functionalization of Methane and Other Hydrocarbons: Fundamental Advancements and New Strategies

Droplet Microfluidics as a Tool for the Generation of Granular Matters and Functional Emulsions

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