A Greener Higher Olefin Hydroformylation Process

Bala Subramaniam

doi:10.1017/9781139026260.009

8 - A Greener Higher Olefin Hydroformylation Process

Published online by Cambridge University Press: 15 September 2022

Bala Subramaniam

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Bala Subramaniam: Affiliation:
University of Kansas

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Summary

Higher olefin hydroformylation with syngas to produce linear aldehydes uses cobalt-based catalyst complexes, which requires rather high temperatures (>180°C) and pressures (~20 MPa). Further, it entails substantial solvent usage to recover and recycle the cobalt complex. Rh-based catalysts are known to operate at milder conditions (<100°C and a few MPa) and are much more active and selective toward the linear aldehyde. However, Rh is three orders of magnitude more expensive than cobalt and requires near-quantitative recovery for economic viability. A new 1-octene hydroformylation process that uses carbon-dioxide expanded liquid (CXL) as solvent medium and a nanofiltration membrane to substantially retain the Rh-catalyst complex in the reactor was demonstrated by researchers at the University of Kansas Center for Environmentally Beneficial Catalysis to outperform the cobalt-based process, with capital investment being 30% lower than the Co-based process. Gate-to-gate life cycle assessments show that the CXL process is environmentally friendlier than the conventional process in most impact categories such as ecotoxicity, greenhouse gas emissions and smog formation.

Keywords

1-octene hydroformylation carbon dioxide-expanded liquids life cycle assessment cobalt rhodium catalyst

Type: Chapter
Information: Green Catalysis and Reaction Engineering
An Integrated Approach with Industrial Case Studies
, pp. 167 - 188

DOI: https://doi.org/10.1017/9781139026260.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

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8 - A Greener Higher Olefin Hydroformylation Process

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