Heteroleptic Tin(II) Initiators for the Ring‐Opening (Co)Polymerization of Lactide and Trimethylene Carbonate: Mechanistic Insights from Experiments and Computations. Issue 40 (19th August 2013)
- Record Type:
- Journal Article
- Title:
- Heteroleptic Tin(II) Initiators for the Ring‐Opening (Co)Polymerization of Lactide and Trimethylene Carbonate: Mechanistic Insights from Experiments and Computations. Issue 40 (19th August 2013)
- Main Title:
- Heteroleptic Tin(II) Initiators for the Ring‐Opening (Co)Polymerization of Lactide and Trimethylene Carbonate: Mechanistic Insights from Experiments and Computations
- Authors:
- Wang, Lingfang
Kefalidis, Christos E.
Sinbandhit, Sourisak
Dorcet, Vincent
Carpentier, Jean‐François
Maron, Laurent
Sarazin, Yann - Abstract:
- <abstract abstract-type="main" xml:lang="en"> <title>Abstract</title> <p>The tin(II) complexes {LO<sup><italic>x</italic></sup>}Sn(X) ({LO<sup><italic>x</italic></sup>}<sup>−</sup>=aminophenolate ancillary) containing amido (<bold>1</bold>–<bold>4</bold>), chloro (<bold>5</bold>), or lactyl (<bold>6</bold>) coligands (X) promote the ring‐opening polymerization (ROP) of cyclic esters. Complex <bold>6</bold>, which models the first insertion of <sc>L</sc>‐lactide, initiates the living ROP of <sc>L</sc>‐LA on its own, but the amido derivatives <bold>1</bold>–<bold>4</bold> require the addition of alcohol to do so. Upon addition of one to ten equivalents of <italic>i</italic>PrOH, precatalysts <bold>1</bold>–<bold>4</bold> promote the ROP of trimethylene carbonate (TMC); yet, hardly any activity is observed if <italic>tert</italic>‐butyl (<italic>R</italic>)‐lactate is used instead of <italic>i</italic>PrOH. Strong inhibition of the reactivity of TMC is also detected for the simultaneous copolymerization of <sc>L</sc>‐LA and TMC, or for the block copolymerization of TMC after that of <sc>L</sc>‐LA. Experimental and computational data for the {LO<sup><italic>x</italic></sup>}Sn(OR) complexes (OR=lactyl or lactidyl) replicating the active species during the tin(II)‐mediated ROP of <sc>L</sc>‐LA demonstrate that the formation of a five‐membered chelate is largely favored over that of an eight‐membered one, and that it constitutes the resting state of the catalyst during this<abstract abstract-type="main" xml:lang="en"> <title>Abstract</title> <p>The tin(II) complexes {LO<sup><italic>x</italic></sup>}Sn(X) ({LO<sup><italic>x</italic></sup>}<sup>−</sup>=aminophenolate ancillary) containing amido (<bold>1</bold>–<bold>4</bold>), chloro (<bold>5</bold>), or lactyl (<bold>6</bold>) coligands (X) promote the ring‐opening polymerization (ROP) of cyclic esters. Complex <bold>6</bold>, which models the first insertion of <sc>L</sc>‐lactide, initiates the living ROP of <sc>L</sc>‐LA on its own, but the amido derivatives <bold>1</bold>–<bold>4</bold> require the addition of alcohol to do so. Upon addition of one to ten equivalents of <italic>i</italic>PrOH, precatalysts <bold>1</bold>–<bold>4</bold> promote the ROP of trimethylene carbonate (TMC); yet, hardly any activity is observed if <italic>tert</italic>‐butyl (<italic>R</italic>)‐lactate is used instead of <italic>i</italic>PrOH. Strong inhibition of the reactivity of TMC is also detected for the simultaneous copolymerization of <sc>L</sc>‐LA and TMC, or for the block copolymerization of TMC after that of <sc>L</sc>‐LA. Experimental and computational data for the {LO<sup><italic>x</italic></sup>}Sn(OR) complexes (OR=lactyl or lactidyl) replicating the active species during the tin(II)‐mediated ROP of <sc>L</sc>‐LA demonstrate that the formation of a five‐membered chelate is largely favored over that of an eight‐membered one, and that it constitutes the resting state of the catalyst during this (co)polymerization. Comprehensive DFT calculations show that, out of the four possible monomer insertion sequences during simultaneous copolymerization of <sc>L</sc>‐LA and TMC: 1) TMC then TMC, 2) TMC then <sc>L</sc>‐LA, 3) <sc>L</sc>‐LA then <sc>L</sc>‐LA, and 4) <sc>L</sc>‐LA then TMC, the first three are possible. By contrast, insertion of <sc>L</sc>‐LA followed by that of TMC (i.e., insertion sequence 4) is endothermic by +1.1 kcal mol<sup>−1</sup>, which compares unfavorably with consecutive insertions of two <sc>L</sc>‐LA units (i.e., insertion sequence 3) (−10.2 kcal mol<sup>−1</sup>). The copolymerization of <sc>L</sc>‐LA and TMC thus proceeds under thermodynamic control.</p> </abstract> … (more)
- Is Part Of:
- Chemistry. Volume 19:Issue 40(2013)
- Journal:
- Chemistry
- Issue:
- Volume 19:Issue 40(2013)
- Issue Display:
- Volume 19, Issue 40 (2013)
- Year:
- 2013
- Volume:
- 19
- Issue:
- 40
- Issue Sort Value:
- 2013-0019-0040-0000
- Page Start:
- 13463
- Page End:
- 13478
- Publication Date:
- 2013-08-19
- Subjects:
- Chemistry -- Periodicals
540 - Journal URLs:
- http://onlinelibrary.wiley.com/journal/10.1002/(ISSN)1521-3765 ↗
http://onlinelibrary.wiley.com/ ↗ - DOI:
- 10.1002/chem.201301751 ↗
- Languages:
- English
- ISSNs:
- 0947-6539
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 3168.860500
British Library DSC - BLDSS-3PM
British Library STI - ELD Digital store - Ingest File:
- 3218.xml