Litcius/Paper detail

Laboratory Ozonolysis Using an Integrated Batch–DIY Flow System for Renewable Material Production

Thien An Phung Hai, Anton A. Samoylov, Bhausaheb S. Rajput, Michael D. Burkart

2022ACS Omega15 citationsDOIOpen Access PDF

Abstract

Flow chemistry offers a solution for replacing batch methods in chemical preparation where intermediates or products may pose toxicity or instability hazards. Ozonolysis offers an ideal opportunity for flow chemistry solutions, but multiple barriers to entry exist for use of these methods, including equipment cost and performance optimization. To address these challenges, we developed a programmable DIY syringe pump system to use for a continuous flow multireactor process using 3D-printed parts, off-the-shelf stepper motors, and an Arduino microcontroller. Reaction kinetics of ozonide formation informed the use of an integrated batch-flow approach, where ozone addition to an olefin was timed to coincide with fluid movement of a single-syringe pump, followed by downstream Pinnick oxidation and reductive quench in flow. The system was demonstrated by continuous preparation of azelaic acid from ozonolysis of palmitoleic acid, a process limited to low production volumes via batch chemistry. High total production of azelaic acid with 80% yield was obtained from an algae oil sourced unsaturated fatty acid: a product with important applications in medicine, cosmetics, and polymers. This low-cost, scalable approach offers the potential for rapid prototyping and distributed chemical production.

Topics & Concepts

OzonolysisProduction (economics)Renewable energyProcess engineeringIntegrated productionMaterial flowFlow (mathematics)Environmental scienceWaste managementPulp and paper industryComputer scienceChemistryEngineeringOrganic chemistryMathematicsElectrical engineeringEconomicsBiologyGeometryMacroeconomicsEcologyInnovative Microfluidic and Catalytic Techniques InnovationCatalytic Processes in Materials ScienceMicrofluidic and Capillary Electrophoresis Applications