2019
DOI: 10.1021/acsomega.9b00808
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Facile Room-Temperature Preparation of Flexible Polyurethane Foams from Carbon Dioxide Based Poly(ether carbonate) Polyols with a Reduced Generation of Acetaldehyde

Abstract: Carbon dioxide (CO 2 ) is becoming more attractive as a renewable feedstock for chemical synthesis. In this study, CO 2 was incorporated into poly(ether carbonate) (PEC) polyols by using a double-metal-cyanide catalyst. By adjusting the CO 2 pressure, the content of propylene carbonate units in the PEC polyols was controlled, indicating successful and semiquantitative incorporation of CO 2 into the PEC polyols. Polyuret… Show more

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Cited by 25 publications
(27 citation statements)
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“…The composition is nowadays able to be tuned in a wide range by raising the activity of catalyst under suitable selection of protic CTA and control over reaction conditions. Especially, the Zo‐Co DMC catalyst allows CU% adjustment from Ca .15 to 65% (CO 2 content in CO 2 ‐polyol of 10‐33 wt%), while the Co salen catalyst allows the synthesis of polycarbonate polyols with negligible ether ratio, affording manifold applications such as foams (low CO 2 content), 143 adhesives (medium CO 2 content), 54 and thermoplastics (high CO 2 content) 144 . However, the current control over composition is not precise enough and upon a great compromise on reduced catalytic efficiency.…”
Section: Sustainable Co2‐polyols and Corresponding Polyurethanesmentioning
confidence: 99%
“…The composition is nowadays able to be tuned in a wide range by raising the activity of catalyst under suitable selection of protic CTA and control over reaction conditions. Especially, the Zo‐Co DMC catalyst allows CU% adjustment from Ca .15 to 65% (CO 2 content in CO 2 ‐polyol of 10‐33 wt%), while the Co salen catalyst allows the synthesis of polycarbonate polyols with negligible ether ratio, affording manifold applications such as foams (low CO 2 content), 143 adhesives (medium CO 2 content), 54 and thermoplastics (high CO 2 content) 144 . However, the current control over composition is not precise enough and upon a great compromise on reduced catalytic efficiency.…”
Section: Sustainable Co2‐polyols and Corresponding Polyurethanesmentioning
confidence: 99%
“…The physical properties of these materials limit their application to specialty polymers. A more recent development is the production of poly(ether carbonates) with the use of a different catalyst system [141,142], Figure 10b. Life cycle analysis [143] shows that the polymers still generate greenhouse gas emissions, but less so than conventional routes.…”
Section: Co 2 Capture and Utilizationmentioning
confidence: 99%
“…to construct carbamates, key intermediates for the pharmaceutical and agroindustries) [11] and polymer design (e.g. polyols used to formulate polyurethane foams), [12][13][14] as solvents and electrolytes for batteries. [11] Three main routes are implemented to prepare cyclic carbonates by the direct reaction of CO 2 with a substrate (Scheme 1).…”
Section: Introductionmentioning
confidence: 99%