Shopping Cart (0)
My Account

Shopping Cart
SELECTBIO Conferences Innovations in Microfluidics & 3D-Printing Europe 2024

Simon Kuhn's Biography



Simon Kuhn, Associate Professor, Katholieke Universiteit Leuven

Dr Kuhn received his Diploma from TU Munich in 2004, and his PhD from ETH Zurich in 2008. From 2008-2010, he worked as Scientist at the Paul Scherrer Institute (PSI), Switzerland, and from 2010-2012 as post-doctoral Fellow at the Massachusetts Institute of Technology (MIT), USA. Dr Kuhn joined the Department of Chemical Engineering at UCL as Lecturer in 2012, and in July 2014 he was appointed associate professor at KU Leuven. His research interests lie in the characterization of transport processes in complex flows using experiments and modeling, scaling-up microchemical systems, and design of advanced flow reactors for process intensification.

Simon Kuhn Image

Microfluidic Approaches for the Controlled Synthesis of Particles

Tuesday, 26 March 2024 at 09:00

Add to Calendar ▼2024-03-26 09:00:002024-03-26 10:00:00Europe/LondonMicrofluidic Approaches for the Controlled Synthesis of ParticlesInnovations in Microfluidics and 3D-Printing Europe 2024 in Rotterdam, The NetherlandsRotterdam, The NetherlandsSELECTBIOenquiries@selectbiosciences.com

Microfluidic flow reactors offer several advantages compared to conventional batch reactors, such as improved control, increased performance, and enhanced process safety. The integration of crystallization in these devices has remained difficult, as crystals tend to clog the flow channels. Both active (with an externally applied force, e.g. ultrasound) and passive methods (without external forces, e.g. multiphase flow) have been proposed to tackle this issue. Many crystallization processes rely on the addition of seeds to induce secondary nucleation. Seeding in continuous microfluidic reactors is rarely done, as the seeds are continuously flushed out and the clogging susceptibility increases. This contribution presents a seeded microfluidic nucleation section which can be used for continuous cooling crystallization. The performance of the off-line continuous seeding platform is established via the seed delivery efficiency, a measure for the seed transport through the seeding module, for constant and oscillatory flows. Second, the yields of seeded and unseeded crystallization are evaluated in the presence and absence of microbubbles. A statistically significant increase in the net yield was obtained when comparing unseeded and seeded crystallization, which can be attributed to the increased nucleation rates because of secondary nucleation. It is shown that also in the presence of seeds, the addition of microbubbles increases the productivity. Advancing to zeolite synthesis, a seeded milli-fluidic crystallizer is developed, which also features low frequency ultrasound integration, which is known to speed up crystallization kinetics during the synthesis thanks to the formation and collapse of cavitation bubbles, creation of local hotspots, intense mixing and enhanced dissolution of the amorphous species, which shorten induction time and increase growth rate. This system enables to compare the synthesis conditions in batch, silent and sonicated, and in continuous, silent and sonicated, in terms of residence time, crystallinity, and solid yield. Secondly, the change in the product characteristics, such as morphology, crystal size and crystal size distribution, pore size and its distribution in the framework is characterized. This work provides valuable insights into the design and operation of continuous crystallization processes.


Add to Calendar ▼2024-03-25 00:00:002024-03-26 00:00:00Europe/LondonInnovations in Microfluidics and 3D-Printing Europe 2024Innovations in Microfluidics and 3D-Printing Europe 2024 in Rotterdam, The NetherlandsRotterdam, The NetherlandsSELECTBIOenquiries@selectbiosciences.com