Heteroscorpionate Rare‐Earth Metal Zwitterionic Complexes: Syntheses, Characterization, and Heteroselective Catalysis on the Ring‐Opening Polymerization of <i>rac</i>‐Lactide

Zhang, Zhichao; Cui, Dongmei

doi:10.1002/chem.201102074

Cited by 58 publications

(37 citation statements)

References 76 publications

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“…The two lutetium complexes 1 and 2 are approximately an order of magnitude slower than yttrium complexes A and B ( k obs =6.9×10 −4 , 7.9×10 −4 s −1 ). This finding is consistent with other examples of lutetium complexes 10b,f,h,j. 13 In contrast, lanthanum complex 3 was an extremely fast initiator, enabling almost complete conversion of 1000 equivalents of LA [versus initiator, in the presence of isopropyl alcohol (2 equivalents)] in less than 20 seconds (Table 1).…”

Section: Methodssupporting

confidence: 89%

“…The use of different lanthanide centers enables an investigation of the influence of atomic size and coordination environment on polymer tacticity. Both metals have precedence in lactide ROP catalysis,10 although lutetium is rarely investigated 10b,e,f,h. Okuda and co‐workers reported heteroselective (syndiotactic) dithiaalkanediyl‐bridged bis(phenolato) yttrium and lutetium catalysts, but found that the stereocontrol decreased from Y to Lu 10b,f.…”

Section: Methodsmentioning

confidence: 99%

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Metal‐Size Influence in Iso‐Selective Lactide Polymerization

et al. 2014

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Iso-selective initiators for the ring-opening polymerization (ROP) of rac-lactide are rare outside of Group 13. We describe the first examples of highly iso-selective lutetium initiators. The phosphasalen lutetium ethoxide complex shows excellent iso-selectivity, with a P i value of 0.81-0.84 at 298 K, excellent rates, and high degrees of polymerization control. Conversely, the corresponding La derivative exhibits moderate heteroselectivity (P s = 0.74, 298 K). Thus, the choice of metal center is shown to be crucial in determining the level and mode of stereocontrol. The relative order of rates for the series of complexes is inversely related to metallic covalent radius: that is, La > Y > Lu.Polylactide (PLA), a degradable polymer obtained from renewable resources, is one of the leading commercial alternatives to petrochemical plastics. [1] PLA is produced by the metal-catalyzed ring-opening polymerization (ROP) of lactide (LA). [2] The central challenge in this field of catalysis is to combine high rates with excellent stereocontrol, ideally without the need for expensive chiral auxiliaries or ligands. [3] Iso-selectivity using rac-LA is especially important and useful because the product, stereoblock/complex PLA, has superior properties. [4] For example, it is a crystalline polymer with a higher melting temperature (T m ) and better mechanical properties than isotactic poly-L-lactide (PLLA). In some cases, T m is elevated by as much as 50 8C, greatly improving thermal stability and enabling PLA to compete as an engineering polymer. [5] However, rac-LA iso-selective catalysts remain scarce, with the majority being chiral aluminum salen complexes or derivatives. [3b, 4a, 6] Although these compounds show impressive degrees of stereocontrol, they are often extremely slow and require unacceptably high catalyst loadings, typically taking hours or days to reach completion even at 1 mol % catalyst loading. There are only a handful of other, non-aluminum based, iso-selective catalysts, [7] the structures of three of the most selective of these are shown in Figure 1. [8] In 2008, Arnold and co-workers reported a homochiral yttrium complex that showed good iso-selectivity (C, P i = 0.75, 298 K). [8a,b] Subsequently, we reported yttrium phosphasalen complexes (Figure 1, structures A and B), which combined very high rates with promising isoselectivity (P i = 0.74, 298 K). [8c] Herein, we report the performance of lutetium and lanthanum phosphasalen complexes. For such Group 3 lanthanide complexes, the coordination geometries are predominantly influenced by steric factors. In this regard, it is relevant that lutetium has a slightly smaller covalent radius than yttrium (1.87 versus 1.90 ), whilst lanthanum is significantly larger (2.07 ). [9] The use of different lanthanide centers enables an investigation of the influence of atomic size and coordination environment on polymer tacticity. Both metals have precedence in lactide ROP catalysis, [10] although lutetium is rarely investigated. [10b,e,f,h] Okuda a...

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Section: Methodssupporting

confidence: 89%

Section: Methodsmentioning

confidence: 99%

Metal‐Size Influence in Iso‐Selective Lactide Polymerization

et al. 2014

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“…In addition, the molecular weight of the polymers increases linearly with the ratio of [ rac ‐LA] 0 /[ 1a ] 0 (Table , entries 2, 9–12), which strongly suggests the controllable polymerization processes were initiated by complex 1a (SI Figure S20). These experimental results reveal that monoguanidinate rare‐earth metal aminobenzyl enolate complexes display efficient catalytic activity in the ROP of rac ‐lactide …”

Section: Resultsmentioning

confidence: 79%

Synthesis, Structure, and Reactivity of Monoguanidinate Rare‐Earth Metal Aminobenzyl Enolate Complexes

Jiang

Zhang

2020

Eur J Inorg Chem

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Two monoguanidinate rare‐earth metal aminobenzyl enolate complexes LRE(CH2C6H4NMe2‐o)(OCH=CH2)(THF) (L = (PhCH2)2NC(NC6H3iPr2‐2,6)2; RE = Y (1a), Lu (1b)) were synthesized via two pathways of the ring‐opening of THF, and their reactivities with some molecules were also explored. Reaction of complex 1a with iPrNCNiPr gave the insertion product LY[(NiPr2)2CCH2C6H4NMe2‐o](OCH=CH2)(THF) (2). Whereas, in the case of PhNCS, LY[SC(CH2C6H4NMe2‐o)NPh](OCH=CH2)(THF) (3) and the ligands redistribution binuclear yttrium enolate complex [LY(µ‐OCH=CH2)(OCH=CH2)]2 (4) were obtained. The protonolysis products LY(NHPh)(OCH=CH2)(THF)2 (5), LY(NHPh)2(THF)2 (6) and LY(NPh2)(OCH=CH2)(THF)2 (7) were achieved by reaction of 1a with arylamine. Moreover, the THF ring‐opening insertion products with unique structures {LY[O(CH2)4PPh2][µ‐O(CH2)4PPh2]}2 (8) and {LY(SCH2C6H4NMe2‐o)[µ‐O(CH2)4SCH2C6H4NMe2‐o]}2 (9) were afforded through reactions of complex 1a with diphenylphosphine and elemental sulfur. It was the first example of THF activation promoted by rare‐earth metal thiolate complex. And some interesting chemical transformations were observed in our work. Complexes 1 could also serve as efficient initiators in the ring‐opening polymerization of rac‐lactide.

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“…It is noteworthy that this compound has been demonstrated to be a potent inhibitor of the Kv1.5 potassium channel and a possible treatment for atrial fibrillation. 8a The prior synthesis provided only 2% yield of this biologically interesting compound, whereas the yield was significantly improved employing our method.…”

mentioning

confidence: 92%

“…8 Surprisingly, very few methods have been reported for their synthesis. Classical methods involve the use of Michaelis-Arbuzov or Michaelis-Becker reactions (Scheme 1).…”

mentioning

confidence: 99%

Palladium-Catalyzed α-Arylation of Benzylic Phosphine Oxides

2013

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A novel approach to prepare diarylmethyl phosphine oxides from benzyl phosphine oxides via deprotonative cross-coupling processes (DCCP) is reported. The optimization of the reaction was guided by High-Throughput Experimentation (HTE) techniques. The Pd(OAc)2/Xantphos-based catalyst enabled the reaction between benzyl diphenyl or dicyclohexyl phosphine oxide derivatives and aryl bromides in good to excellent yields (51–91%).

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Heteroscorpionate Rare‐Earth Metal Zwitterionic Complexes: Syntheses, Characterization, and Heteroselective Catalysis on the Ring‐Opening Polymerization of rac‐Lactide

Cited by 58 publications

References 76 publications

Metal‐Size Influence in Iso‐Selective Lactide Polymerization

Metal‐Size Influence in Iso‐Selective Lactide Polymerization

Synthesis, Structure, and Reactivity of Monoguanidinate Rare‐Earth Metal Aminobenzyl Enolate Complexes

Palladium-Catalyzed α-Arylation of Benzylic Phosphine Oxides

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