Redox Control of a Ring-Opening Polymerization Catalyst

Broderick, Erin M.; Guo, Neng; Vogel, Carola; Xu, Cuiling; Sutter, Jörg; Miller, Jeffrey T.; Meyer, Karsten; Mehrkhodavandi, Parisa; Diaconescu, Paula L.

doi:10.1021/ja2036089

Cited by 241 publications

(197 citation statements)

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“…43,[59][60][61] We first introduced a Schiff base derivative, salfen, to cerium and yttrium 78 and later developed the phosfen ligand that could be cleanly oxidized by a ferrocenium oxidant to enable redox controlled catalysis. 61 The salfan, thiolfan and thiolfan* ligands were found to fit group 4 metals well and have been exploited in redox-switchable copolymerization processes. 43 …”

Section: A Synthesis and Electronic Properties Of Ferrocenebased Ligmentioning

confidence: 99%

“…[59][60][61]78 Due to the high acidity of the phenolic proton of H 2 (OEEO fc ), the installation of the metal fragment was facile; the choice of synthetic routes was mainly based on the desired composition of the pre-catalysts used for polymerization and the ease of availability of a metal precursor. Group 4 metal complexes supported by salfan, thiolfan, and thiolfan* ligands were prepared in a similar way using Zr(OtBu) 4 or Ti(OiPr) 4 as metal precursors.…”

Section: B Synthesis Of Rare-earth Metal Complexes Supported By Ferrmentioning

confidence: 99%

“…59 Therefore, we achieved control of lactide polymerization by chemically oxidizing or reducing the catalyst at a remote site of catalysis, the ferrocene backbone of the phosfen ligand (Figure 2). 61 The difference in reactivity between the oxidized and reduced forms of the catalyst was attributed to changes in their electronic profiles. We hypothesized that the oxidized ferrocenium ligand would make the rare-earth metal center so electron deficient that once the substrate binds to the metal it cannot leave, thus interrupting the catalytic cycle.…”

Section: E Redox-switchable Catalysis Enabled By Redox Active Metalsmentioning

confidence: 99%

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Reactivity and Properties of Metal Complexes Enabled by Flexible and Redox-Active Ligands with a Ferrocene Backbone

Huang

Diaconescu

2016

Inorg. Chem.

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Our group has focused on the organometallic chemistry of rare-earth metals and actinides for a decade. By installing ferrocene diamide ligands at electropositive metal centers, we have been able to disclose unprecedented reactivity toward aromatic N-heterocycles, arenes, and other small molecules such as P 4 . Systematic studies employing X-ray crystallography, spectroscopy, cyclic voltammetry, and DFT calculations revealed that the ferrocene backbone could stabilize the electron-deficient metal through a donor-acceptor type interaction. Most noteworthy is that this interaction can be readily turned on or off by the addition or removal of a Lewis base. In addition to its flexible coordination, the redox active nature of the ferrocene backbone enabled us to explore redox-switchable transformations. The introduction of ferrocene-based ligands into organolanthanide chemistry not only helped to study intriguing fundamental problems but also led to fruitful chemistry including small molecule activation and controlled co-polymerization reactions.3

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Section: A Synthesis and Electronic Properties Of Ferrocenebased Ligmentioning

confidence: 99%

Section: B Synthesis Of Rare-earth Metal Complexes Supported By Ferrmentioning

confidence: 99%

Section: E Redox-switchable Catalysis Enabled By Redox Active Metalsmentioning

confidence: 99%

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Reactivity and Properties of Metal Complexes Enabled by Flexible and Redox-Active Ligands with a Ferrocene Backbone

Huang

Diaconescu

2016

Inorg. Chem.

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“…[3][4][5][6][7][8][9][10][11][12][13] Lactide polymerizations have been particularly well examined, but many of the precatalysts [14][15][16][17][18][19][20] often require initiators. β-butyrolactone, 8,21 ε-caprolactone, 20 and trimethylene carbonate 22 polymerizations have also been achieved by indium catalysts. Although less studied, low catalyst loadings 21 and the potential range of lactone and carbonate monomers 23 make their polymerization a promising area toward finding new biodegradable polymers.…”

mentioning

confidence: 99%

“…24 Phosphinimine analogues with yttrium and indium also demonstrated good activity in lactide and trimethylene carbonate polymerizations. 22 Therefore, we decided to combine indium's activity with the Schiff base, ferrocene-derived ligand in order to study the activity of the resulting complexes toward a broad range of cyclic ester polymerizations. Additional motivation was found from recent studies that point to the biocompatibility, robustness, and high activity of indium catalysts in the ring opening polymerization of cyclic esters.…”

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confidence: 99%

High activity of an indium alkoxide complex toward ring opening polymerization of cyclic esters

Quan

Diaconescu

2015

Chem. Commun.

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Abstract. An indium complex supported by a ferrocene-derived Schiff base ligand has an unprecedented high activity toward ε-caprolactone, δ-valerolactone, and β-butyrolactone. L-lactide, D,L-lactide, and trimethylene carbonate polymerizations also showed moderate to high activity.Over the past two decades, the ring-opening polymerization of cyclic esters has been increasingly studied because of the promise to produce biodegradable polymers from biomass. In our recent studies, a cerium complex supported by a Schiff base ligand with a ferrocene backbone polymerized L-lactide in a controlled fashion. 24 Phosphinimine analogues with yttrium and indium also demonstrated good activity in lactide and trimethylene carbonate polymerizations. 22 Therefore, we decided to combine indium's activity with the Schiff base, ferrocene-derived ligand in order to study the activity of the resulting complexes toward a broad range of cyclic ester polymerizations. Additional motivation was found from recent studies that point to the biocompatibility, robustness, and high activity of indium catalysts in the ring opening polymerization of cyclic esters. 10,25 Herein, we report a ferrocene-derived Schiff base indium complex that possesses a remarkable range of activity toward cyclic esters and exceptionally fast polymerization rates with lactones. Compound (salfen)In(O t Bu) (salfen = 1,1'-di(2,4-di-tert-butyl-6-iminephenoxy)ferrocene) represents the first indium precatalyst capable of δ-valerolactone polymerization and the most active indium catalyst to date in the polymerization of β-butyrolactone and ε-caprolactone. The polymerization rates of ε-caprolactone are even competitive with those of current industrial catalysts.Compound (salfen)In(O t Bu) was synthesized from the reaction of (salfen)InCl and freshly sublimed KO t Bu. In turn, (salfen)InCl was synthesized by combining InCl3 with K2(salfen), which was generated from H2(salfen) and two equivalents of KH (Eq 1). Needle crystals of (salfen)InCl were isolated from a diethyl ether solution. The solid state molecular structure (Figure 1) shows a distorted octahedral indium center and a THF molecule coordinated trans to the chloride ligand. Similarly to the phosphinimine indium chloride analogue previously reported by us, 22 a long In-Fe distance (3.98 Å) and a staggered configuration of the Cp rings were apparent. Elongation of the In-heteroatom distances compared to other compounds, such as (salen)InCl (salen = N,N ' -bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediamine (rac-or (R,R)-H2(ONNO))) 9 and (phosfen)In(OPh) (phosfen = 1,1'-di(2-tert-butyl-6-diphenylphosphiniminophenoxy)ferrocene), 22 by about 0.25 Å possibly compensates for the distortion caused by the staggered Cp rings.

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Metal Phenolates as Polymerization Catalysts

Carpentier¹,

Kirillov²,

Sarazin³

2012

Patai's Chemistry of Functional Groups

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Phenolates represent versatile ligand scaffolds capable of stabilizing a large variety of both oxophilic metal centers and late transition elements. Over the past 50 years, they have played a prominent role in the rise of discrete metal complexes employed to promote, initiate and/or catalyze a variety of controlled homogeneous polymerization reactions. This chapter features a selection of the most remarkable metal phenolate complexes used in the polymerization of olefins, styrene and dienes, cyclic esters and (meth)acrylates. Coordination-insertion polymerization reactions are emphasized, but other types of mechanisms are also treated. Specifically highlighted are catalytic systems where the phenolate ligands have proved valuable ancillaries, to provide either exceptional stability to active species and to generate highly productive catalysts, and/or to control the polymerization reactions, imparting a unique capacity to obtain polymers with tailored macromolecular features: molecular weights and their dispersion, (co)monomer distribution and regio/stereoselectivity

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Redox Control of a Ring-Opening Polymerization Catalyst

Cited by 241 publications

References 38 publications

Reactivity and Properties of Metal Complexes Enabled by Flexible and Redox-Active Ligands with a Ferrocene Backbone

Reactivity and Properties of Metal Complexes Enabled by Flexible and Redox-Active Ligands with a Ferrocene Backbone

High activity of an indium alkoxide complex toward ring opening polymerization of cyclic esters

Metal Phenolates as Polymerization Catalysts

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