AI Article Synopsis
- Hydroformylation of olefins to produce aldehydes and their subsequent conversion to amines can be enhanced using water-soluble catalysts, but this process is mainly effective for short-chain molecules due to long-chain solubility issues in water.
- Adding nonionic CE surfactants to the aqueous phase can improve the solubility of long-chain aldehydes and amines, and the study explored the solubilization capacity of different surfactants using light scattering techniques.
- The research found an optimal hydrophobic to hydrophilic chain length ratio in CE surfactants that maximizes solubilization, as well as changes in aggregate size during the solubilization of aldehydes and amines, providing
Article Abstract
Hydroformylation of olefins to aldehydes and subsequent reductive amination of aldehydes to amines takes place in an aqueous system using a water-soluble catalyst. It is limited to short-chain molecules due to an insufficient solubility of long-chain molecules in water. A promising approach to increase the solubility of long-chain aldehydes and amines is the addition of surfactants to the aqueous phase. In this work, we thus determined the solubilization capacity (SC) of different nonionic CE surfactants (CE, CE, and CE) toward long-chain aldehydes and amines. We used static and dynamic light scattering techniques to investigate the influence of both the surfactant and solute molecular structures on the SC as well as on the aggregation number () and hydrodynamic radius () of mixed aggregates. Our data reveals that an optimum ratio of hydrophobic to hydrophilic chain length of CE surfactants exists where the SC toward long-chain aldehydes and amines possesses a maximum. Further, the size of the aggregates (, ) passes through a minimum upon amine solubilization, while upon aldehyde solubilization, the aggregate size increases gradually. The results shown in this work give valuable insights to the solubilization of aldehydes and -amines into nonionic CE surfactants and facilitate the search of suitable surfactants for hydroformylation and reductive amination as "green" solvents based on the detailed knowledge about the aggregate structure.
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| http://dx.doi.org/10.1021/acs.langmuir.2c01463 | DOI Listing |
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