Issue 3, 2022

Separation of bio-based glucaric acid via antisolvent crystallization and azeotropic drying

Abstract

Glucaric acid is regarded as a top-value added compound from biomass, however, due to prevalent lactonization, the recovery of purified glucaric acid is challenging. Accordingly, an efficient method for glucaric acid separation, especially its diacid form, is necessary to facilitate its valorization. Here, we report a robust separation process that produces glucaric acid crystals from fermentation broth. This process first recovers purified monopotassium glucarate from broth and then recovers purified glucaric acid through acidification and antisolvent crystallization. Isopropanol was found to be an effective antisolvent reducing the solubility of glucaric acid while concomitantly forming an azeotrope with water. This allows solvent removal at low temperature through azeotropic drying, which avoids lactonization, and thus prevents impurities in the resulting crystals. Overall, this process was found to separate monopotassium glucarate and glucaric acid with a recovery yield of >99.9% and 71% at purities of ca. 95.6 and 98.3%, respectively. Process modeling demonstrates the ability to recycle the antisolvents IPA and acetone with >99% recovery and determined the energy input to be ∼20 MJ kg−1 for isolation of monopotassium glucarate and 714 MJ kg−1 for glucaric acid (0.06 M). The approach detailed in this work is likely applicable to the separation of other highly oxygenated bio-carboxylic acids (e.g., mevalonic acid) from fermentation broths, as well as to their recovery from abiotic reaction solutions.

Graphical abstract: Separation of bio-based glucaric acid via antisolvent crystallization and azeotropic drying

Supplementary files

Article information

Article type
Paper
Submitted
26 Oct 2021
Accepted
03 Jan 2022
First published
18 Jan 2022
This article is Open Access
Creative Commons BY license

Green Chem., 2022,24, 1350-1361

Separation of bio-based glucaric acid via antisolvent crystallization and azeotropic drying

H. Choi, N. E. Soland, B. L. Buss, N. C. Honeycutt, E. G. Tomashek, S. J. Haugen, K. J. Ramirez, J. Miscall, E. C. D. Tan, T. N. Smith, P. O. Saboe and E. M. Karp, Green Chem., 2022, 24, 1350 DOI: 10.1039/D1GC03984A

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