On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂
Removal of brominated flame retardants (BFRs) from polymers before disposal or recycling will alleviate negative environmental effects and ensure safe usage of recycled products. Extraction of BFRs in supercritical CO2 is appealing but also presents challenges to industries due to limited solubility...
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sg-ntu-dr.10356-1673882023-05-23T15:38:07Z On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂ Xia, Dong Maurice, Ange Leybros, Antoine Lee, Jong-Min Grandjean, Agnes Gabriel, Jean-Christophe P. School of Chemical and Biomedical Engineering Energy Research Institute @ NTU (ERI@N) Engineering::Environmental engineering::Waste management Engineering::Chemical engineering::Chemical processes Extraction Kinetic Removal of brominated flame retardants (BFRs) from polymers before disposal or recycling will alleviate negative environmental effects and ensure safe usage of recycled products. Extraction of BFRs in supercritical CO2 is appealing but also presents challenges to industries due to limited solubility and lack of kinetic studies. For a more comprehensive evaluation of supercritical extraction potentialities, we (i) developed an on-line pressure apparatus that is compatible with both the FTIR and UV-vis spectrometers to enable kinetic and thermodynamic studies; (ii) studied kinetic extraction involving three conventional and two novel BFRs as well as three typical polymeric matrix. Solubilities were determined using the gravimetric method or X-ray fluorescence. FTIR exhibited a superior applicability compared to UV-vis in the following BFR extraction's time-dependency binary and ternary systems. We observed that faster stirring speed, higher temperature, and finer particle size can accelerate the overall extraction kinetics. In binary systems, it took less than 2 h to achieve equilibrium for each BFR at 60 °C, 25 MPa and 1000 rpm. In the presence of polymeric matrix, slower extraction kinetics were observed due to the occurrence of competitive dissolution and molecular diffusion within the matrix. Mathematical models derived from irreversible desorption and Fick's diffusion laws fitted well with the observed extraction kinetics of BFRs, thus enabling us to identify the rate-determining step. The high solubilization rate coefficients that we measured for BFRs revealed that the dynamic extraction process in up-scaling design could compensate for the low solubility with flowing supercritical CO2. Ministry of National Development (MND) National Environmental Agency (NEA) National Research Foundation (NRF) Submitted/Accepted version All authors acknowledge financial support from SCARCE laboratory. SCARCE is supported by the Na- tional Research Foundation, Singapore; Prime Minister’s Office, Singapore,;the Ministry of National Development, Singapore; Na- tional Environment Agency, Singapore; and the Ministry of Sus- tainability and the Environment, Singapore; under the Closing the Waste Loop R&D Initiative as part of the Urban Solutions & Sus- tainability - Integration Fund (Award No. USS-IF-2018-4). 2023-05-22T05:16:35Z 2023-05-22T05:16:35Z 2021 Journal Article Xia, D., Maurice, A., Leybros, A., Lee, J., Grandjean, A. & Gabriel, J. P. (2021). On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂. Chemosphere, 263, 128282-. https://dx.doi.org/10.1016/j.chemosphere.2020.128282 0045-6535 https://hdl.handle.net/10356/167388 10.1016/j.chemosphere.2020.128282 33297226 2-s2.0-85090550911 263 128282 en USS-IF-2018-4 Chemosphere © 2020 Elsevier Ltd.. All rights reserved. This paper was published in Chemosphere and is made available with permission of Elsevier Ltd. application/pdf |
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Engineering::Environmental engineering::Waste management Engineering::Chemical engineering::Chemical processes Extraction Kinetic Xia, Dong Maurice, Ange Leybros, Antoine Lee, Jong-Min Grandjean, Agnes Gabriel, Jean-Christophe P. On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂ |
| description |
Removal of brominated flame retardants (BFRs) from polymers before disposal or recycling will alleviate negative environmental effects and ensure safe usage of recycled products. Extraction of BFRs in supercritical CO2 is appealing but also presents challenges to industries due to limited solubility and lack of kinetic studies. For a more comprehensive evaluation of supercritical extraction potentialities, we (i) developed an on-line pressure apparatus that is compatible with both the FTIR and UV-vis spectrometers to enable kinetic and thermodynamic studies; (ii) studied kinetic extraction involving three conventional and two novel BFRs as well as three typical polymeric matrix. Solubilities were determined using the gravimetric method or X-ray fluorescence. FTIR exhibited a superior applicability compared to UV-vis in the following BFR extraction's time-dependency binary and ternary systems. We observed that faster stirring speed, higher temperature, and finer particle size can accelerate the overall extraction kinetics. In binary systems, it took less than 2 h to achieve equilibrium for each BFR at 60 °C, 25 MPa and 1000 rpm. In the presence of polymeric matrix, slower extraction kinetics were observed due to the occurrence of competitive dissolution and molecular diffusion within the matrix. Mathematical models derived from irreversible desorption and Fick's diffusion laws fitted well with the observed extraction kinetics of BFRs, thus enabling us to identify the rate-determining step. The high solubilization rate coefficients that we measured for BFRs revealed that the dynamic extraction process in up-scaling design could compensate for the low solubility with flowing supercritical CO2. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Xia, Dong Maurice, Ange Leybros, Antoine Lee, Jong-Min Grandjean, Agnes Gabriel, Jean-Christophe P. |
| format |
Article |
| author |
Xia, Dong Maurice, Ange Leybros, Antoine Lee, Jong-Min Grandjean, Agnes Gabriel, Jean-Christophe P. |
| author_sort |
Xia, Dong |
| title |
On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂ |
| title_short |
On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂ |
| title_full |
On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂ |
| title_fullStr |
On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂ |
| title_full_unstemmed |
On-line spectroscopic study of brominated flame retardant extraction in supercritical CO₂ |
| title_sort |
on-line spectroscopic study of brominated flame retardant extraction in supercritical co₂ |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/167388 |
| _version_ |
1772828785190633472 |