Exploiting Noncovalent Interactions for Room-Temperature Heteroselective <i>rac</i>-Lactide Polymerization Using Aluminum Catalysts

Gesslbauer, Sami; Savela, Risto; Chen, Y.; White, Andrew J. P.; Romain, Charles

doi:10.1021/acscatal.9b00875

Cited by 47 publications

(44 citation statements)

References 61 publications

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“…The importance of non-covalent interactions for the formation of catalytic complexes in lactide polymerization was demonstrated by Romain et al in a recent publication [131] involved the DFT modeling at the ωB97xD [88]/6-31G(d,p) level of theory of ( dl )-LA ROP catalyzed by aluminium complex 51 (Figure 19). The calculations established that the NH hydrogen bond donors are well positioned in the catalytic pocket to interact with the reactive species (lactide, growing polymer) and to form hydrogen bonds (Figure 26).…”

Section: Coordination Polymerization Of Lactides and Glycolidementioning

confidence: 99%

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Coordination Ring-Opening Polymerization of Cyclic Esters: A Critical Overview of DFT Modeling and Visualization of the Reaction Mechanisms

Nifant’ev

Ivchenko

2019

Molecules

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Ring-opening polymerization (ROP) of cyclic esters (lactones, lactides, cyclic carbonates and phosphates) is an effective tool to synthesize biocompatible and biodegradable polymers. Metal complexes effectively catalyze ROP, a remarkable diversity of the ROP mechanisms prompted the use of density functional theory (DFT) methods for simulation and visualization of the ROP pathways. Optimization of the molecular structures of the key reaction intermediates and transition states has allowed to explain the values of catalytic activities and stereocontrol events. DFT computation data sets might be viewed as a sound basis for the design of novel ROP catalysts and cyclic substrates, for the creation of new types of homo- and copolymers with promising properties. In this review, we summarized the results of DFT modeling of coordination ROP of cyclic esters. The importance to understand the difference between initiation and propagation stages, to consider the possibility of polymer–catalyst coordination, to figure out the key transition states, and other aspects of DFT simulation and visualization of ROP have been also discussed in our review.

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Section: Coordination Polymerization Of Lactides and Glycolidementioning

confidence: 99%

“…Mononuclear metal complexes studied in DFT modeling of lactide ROP [50,75,119,120,121,122,123,124,125,126,127,128,129,130,131,132,133,134,135,136,137,138,139,140]. …”

Section: Figures and Schemesmentioning

confidence: 99%

Coordination Ring-Opening Polymerization of Cyclic Esters: A Critical Overview of DFT Modeling and Visualization of the Reaction Mechanisms

Nifant’ev

Ivchenko

2019

Molecules

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“…The importance of H-bonding interactions has recently been showed by Romain for lactide polymerisation. 81 For the Fe(III)-salen-acetate complexes, activity was increased by installing a planar phenyl ring into the Fe(III)-salen ethylene backbone {Fe(11)OAc, 52% vs. Fe(9)OAc, 28% and Fe(12)OAc, 59% vs. Fe(10)OAc, 43%}. Indeed Fe(12)OAc gave the second highest activity observed in this study, however, this was accompanied by a decrease in product selectivity to 84%.…”

Section: Epoxide and Co 2 Couplingmentioning

confidence: 99%

The synthesis, characterisation and application of iron(iii)–acetate complexes for cyclic carbonate formation and the polymerisation of lactide

et al. 2019

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“…Whereas the latter trend is monotonous in the case of lactide (P r = 0.55 (R' = Me), 0.81 (tBu), 0.91 (CMe 2 Ph), 0.95 (CMe 2 tBu), 0.95 (CPh 3 )), the "most crowded" complexes hence being the best, it is not the case for the ROP of rac-BL Me (P r = 0.56 (R' = Me), 0.80 (tBu), 0.83 (CMe 2 C 6 H 4 (p-CF 3 )), 0.91 (CMe 2 Ph), 0.70 (CMe 2 tBu), 0.96 (CPh 3 )). In this latter ROP,a ne lectron-rich aryl group on the R' substituent is also beneficiala nd necessary for achieving high syndiotacticity.A sd iscussed in details in a recentf eature article, [10] this was accounted for by the occurrence of attractive CÀH···p(aryl) interactions between the aryl groups from the R' ortho-substituent andt he acidic CÀHo ft he methylene of the last inserted monomer unit within the growing poly(alkoxybutyryl) chain;s uch so-called "second-sphere" or "non-covalent" interactions (NCIs) [11] are illustrated in Fig In 2009, Coates and Thomas reportedt hat the ROP of rac-BL Me and related b-lactonesb earing alkyl side-groups higher than Me, using the yttrium-salan complex Y{ON Me N Me O tBu2 }a lso generates highly syndiotactic PBHAs (P r = 0.90-0.94). [7] In 2018, Cui and collaboratorsr evisited this chemistry by tuning the substituents on the Na toms of the salan ligand framework, and further using ytterbium(III) in addition to yttrium(III)c omplexes for the ROP of rac-BL Me .…”

Section: From Syndiotactictoi Sotactic Pbhas Pghas and Pahasmentioning

confidence: 99%

Recent Advances in Metal‐Mediated Stereoselective Ring‐Opening Polymerization of Functional Cyclic Esters towards Well‐Defined Poly(hydroxy acid)s: From Stereoselectivity to Sequence‐Control

Shakaroun

Guillaume

et al. 2019

Chemistry A European J

108

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Poly(hydroxy acid)s are a family of biocompatible and (bio)degradable polyesters with various outcomes in different domains of application. To date, poly(hydroxy acid)s are best prepared by ring‐opening polymerization (ROP) of the corresponding cyclic esters. Using racemic chiral monomers featuring side‐chain groups enables to access, providing a stereoselective catalyst/initiator system is implemented, stereoregular functional polymers, thereby improving their physico–chemical properties, and ultimately, widening their range of uses. Here, we highlight a few important advances in metal‐mediated stereoselective ROP of cyclic esters towards the synthesis of (functional) stereoregular poly(hydroxy acid)s that have recently been disclosed, emphasizing on (functional) β‐ and γ‐lactones, diolide and O‐carboxyanhydride (OCA) monomers and yttrium‐based catalysis. Fine‐tuning of the substituents flanked on the catalyst ligand enables reaching poly(hydroxy acid)s with syndiotactic and also isotactic microstructures. The stereocontrol mechanisms at work and their probable origin, relying on steric but also electronic factors imparted in particular by the ligand substituents, are discussed. Taking advantage of such stereoselective ROPs, original copoly(hydroxy acid)s with gradient or alternated patterns then become accessible from the use of mixtures of chemically different, oppositely configured enantiopure monomers.

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Exploiting Noncovalent Interactions for Room-Temperature Heteroselective rac-Lactide Polymerization Using Aluminum Catalysts

Cited by 47 publications

References 61 publications

Coordination Ring-Opening Polymerization of Cyclic Esters: A Critical Overview of DFT Modeling and Visualization of the Reaction Mechanisms

Coordination Ring-Opening Polymerization of Cyclic Esters: A Critical Overview of DFT Modeling and Visualization of the Reaction Mechanisms

The synthesis, characterisation and application of iron(iii)–acetate complexes for cyclic carbonate formation and the polymerisation of lactide

Recent Advances in Metal‐Mediated Stereoselective Ring‐Opening Polymerization of Functional Cyclic Esters towards Well‐Defined Poly(hydroxy acid)s: From Stereoselectivity to Sequence‐Control

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