Publications


Here you will find all publications of the Institut of Multiphase Flows that have a DOI or an ISBN. The individual entries can be downloaded in BibTex format.

For a detailed search in our list, please click here.

Posters of conventions and conferences can be found here.


[145524]
Title: Comparative investigation of fine bubble and macrobubble aeration on gas utility and biotransformation productivity
Written by: Thomas, B.; Ohde, D.; Matthes, S.; Engelmann, C.; Bubenheim, P.; Terasaka, K.; Schlüter, M.; Liese, A.
in: Biotechnology and Bioengineering 2020
Volume: Number:
on pages:
Chapter:
Editor:
Publisher:
Series:
Address:
Edition:
ISBN:
how published:
Organization:
School:
Institution:
Type:
DOI: https://doi.org/10.1002/bit.27556
URL:
ARXIVID:
PMID:

[doi] [BibTex]

Note:

Abstract: The sufficient provision of oxygen is mandatory for enzymatic oxidations in aqueous solution, however, in process optimization this still is a bottleneck that cannot be overcome with the established methods of macrobubble aeration. Providing higher mass transfer performance through microbubble aerators, inefficient aeration can be overcome or improved. Investigating the mass transport performance in a model protein solution, the microbubble aeration results in higher kLa values related to the applied airstream in comparison with macrobubble aeration. Comparing the aerators at identical kLa of 160 and 60 1/h, the microbubble aeration is resulting in 25 and 44 times enhanced gas utility compared with aeration with macrobubbles. To prove the feasibility of microbubbles in biocatalysis, the productivity of a glucose oxidase catalyzed biotransformation is compared with macrobubble aeration as well as the gas-saving potential. In contrast to the expectation that the same productivities are achieved at identically applied kLa, microbubble aeration increased the gluconic acid productivity by 32% and resulted in 41.6 times higher oxygen utilization. The observed advantages of microbubble aeration are based on the large volume-specific interfacial area combined with a prolonged residence time, which results in a high mass transfer performance, less enzyme deactivation by foam formation, and reduced gas consumption. This makes microbubble aerators favorable for application in biocatalysis.