Aldehydes and ketones influence reactivity and selectivity in nickel-catalysed Suzuki–Miyaura reactions

Cooper, Alasdair; Leonard, David K.; Bajo, Sonia; Burton, Paul M.; Nelson, David J.

doi:10.1039/c9sc05444h

Cited by 33 publications

(37 citation statements)

References 48 publications

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“…As expected, the less active unsubstituted chlorobenzene required heating at 80 °C to obtain similar yields. Of note, the same results were observed when the reaction of complex I with chlorobenzene was carried out in the presence of high excess of acetone, showing that acetone does not inhibit the oxidative addition process . Moreover, addition of chlorobenzene to a 1:1 mixture of I and ( L1 ) 2 Ni(0) led to quantitative formation of the oxidative addition product II b (Figure S7), indicating that ( L1 ) 2 Ni(0) is a reactive species …”

Section: Methodssupporting

confidence: 69%

Nickel‐Catalyzed Mono‐Selective α‐Arylation of Acetone with Aryl Chlorides and Phenol Derivatives

et al. 2020

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The challenging nickel‐catalyzed mono‐α‐arylation of acetone with aryl chlorides, pivalates, and carbamates has been achieved for the first time. A nickel/Josiphos‐based catalytic system is shown to feature unique catalytic behavior, allowing the highly selective formation of the desired mono‐α‐arylated acetone. The developed methodology was applied to a variety of (hetero)aryl chlorides including biologically relevant derivatives. The methodology has been extended to the unprecedented coupling of acetone with phenol derivatives. Mechanistic studies allowed the isolation and characterization of key Ni0 and NiII catalytic intermediates. The Josiphos ligand is shown to play a key role in the stabilization of NiII intermediates to allow a Ni0/NiII catalytic pathway. Mechanistic understanding was then leveraged to improve the protocol using an air‐stable NiII pre‐catalyst.

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Section: Methodssupporting

confidence: 69%

Nickel‐Catalyzed Mono‐Selective α‐Arylation of Acetone with Aryl Chlorides and Phenol Derivatives

et al. 2020

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“…Following on from this study, Cooper et al have investigated how common functional groups can interact with nickel(0) complexes and influence the rate and selectivity of oxidative addition (Scheme 6); 38 model nickel complexes with dppf ligands were utilised, and were compared to the analogous palladium complexes in Suzuki-Miyaura cross-coupling reactions. 39 Aldehyde-and ketonesubstituted aryl chlorides underwent unexpectedly rapid oxidative addition to [Ni(COD)(dppf)].…”

Section: Reactions With Aryl Halidesmentioning

confidence: 99%

“…This exceptional reactivity of aromatic halides bearing aldehyde and ketone groups was then exploited to achieve selective Suzuki-Miyaura cross-coupling reactions; 38 Catalysis Science & Technology Mini review coupling was achieved at the site that was in conjugation with the aldehyde or ketone. This selectivity was such that the normal order of reactivity of aryl halides (I > Br > Cl) could be overturned, and was attributed to a 'ring-walking' process where the nickel moves from the initial site of coordination across a π-system to the aryl halide.…”

Section: Reactions With Aryl Halidesmentioning

confidence: 99%

“…However, aldehydes and ketones (without halide functional groups) can act as inhibitors in these reactions, which prevents a potential drawback to the use of nickel catalysis. 38 Palladium has been shown not to interact strongly enough to induce these selectivity and inhibition effects observed with nickel. 39 In light of the much wider scope of electrophiles that are reactive with nickel in cross-coupling catalysis, 15,52 there can be selectivity challenge in nickel catalysis if the substrate is highly functionalised.…”

Section: Reactions With Aryl Halidesmentioning

confidence: 99%

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Reactions of nickel(0) with organochlorides, organobromides, and organoiodides: mechanisms and structure/reactivity relationships

Greaves

Humphrey

Nelson

2021

Catal. Sci. Technol.

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“…The partial introduction of the COOH group at the terminal of P3HT was also confirmed by MALDI‐TOF mass spectroscopy (Figure S9, Supporting Information). The incomplete chain‐end functionalization reactions might be possibly caused by the presence of carbonyl groups from the large excess amount of terminator 1c′ , which may stabilize the ─C─Ni─Br terminal too much via a Ni/C═O interaction, [ 54 ] reducing the reactivity of the quasi‐living end of P3HT. Although increasing the ratio of [ t Bu 4 ZnLi 2 ] 0 /[ 1c ] 0 from 1.1 to 2.0 led to the complete Zn─I exchange reaction (100%), the chain‐end functionalization failed only reaching Fn = 23%, unfortunately ( 5f , Table 1, Figures S10 and S11, Supporting Information).…”

Section: Methodsmentioning

confidence: 99%

Direct Synthesis of Chain‐end‐functionalized Poly(3‐hexylthiophene) without Protecting Groups Using a Zincate Complex

Inagaki

Yamamoto

Higashihara

2020

Macromol. Rapid Commun.

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and such a breakthrough allows the synthesis of more complicated block copolymers and branched polymers, such as star and graft copolymers, containing P3HT segments with low Ð M values. [13][14][15][16][17][18][19][20][21][22][23][24] Chain-end-functionalized P3HTs, which can also be easily synthesized by such a living polymerization, have received much attention, because the chain-end moiety itself frequently affects device performances in organic electronics. [25][26][27] In addition, chain-end-functionalized P3HTs are used to prepare quantum dots through the coordination between the functional groups and heavy metals. [28] Such quantum dots improve their dispersibility while maintaining a higher conductivity than using normal nonconjugated dispersants. In addition, the chain ends can be used as reactive sites, when synthesizing block and branched copolymers via a crossover reaction, linking reaction, etc. A summary of the synthesis and utilization of chain-end-functionalized P3HTs has been well reviewed elsewhere. [29] Currently, there are three major methods for chain-end functionalization based on the KCTP: a) Initiation method: [30][31][32][33][34] a method using an initiator having a functional group. Since the initiation reaction in a living polymerization is utilized, the quantitative chain-end functionality (Fn) is guaranteed unless the initiation efficiency is incomplete or chain transfer reactions occur. However, it sometimes suffers from the instability of the functional initiators derived from the low ability of the coexistence of functional moieties and Ni species. b) Termination method: [10,[35][36][37][38][39][40][41][42] a method involving the reaction between Ni-Br chain-end-functionalized P3HT and a Grignard-type terminator having a functional group. This method is simple because Ni-based functional initiators are unnecessary. However, excess amounts of the terminators are required to achieve a high functionality. c) Postfunctionalization method: [43][44][45] a method involving site transformation reactions of α-chain-endor ω-chain-end-functionalized polymers. This method is more generalized because various functional groups can be introduced through the precursory chain ends. However, it requires tedious multistep reactions. Each method has advantages and disadvantages, however, method b has been still widely used because of its straightforward strategy. Even when selecting method b, the Grignard reagents having a high basicity must be used in the KCTP method.

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Aldehydes and ketones influence reactivity and selectivity in nickel-catalysed Suzuki–Miyaura reactions

Abstract: Aldehydes and ketones can have beneficial or detrimental effects on nickel-catalysed reactions. When present on the aryl halide, excellent site-selectivity can be achieved; when present as additives, they inhibit the reaction.

Cited by 33 publications

References 48 publications

Nickel‐Catalyzed Mono‐Selective α‐Arylation of Acetone with Aryl Chlorides and Phenol Derivatives

Nickel‐Catalyzed Mono‐Selective α‐Arylation of Acetone with Aryl Chlorides and Phenol Derivatives

Reactions of nickel(0) with organochlorides, organobromides, and organoiodides: mechanisms and structure/reactivity relationships

Direct Synthesis of Chain‐end‐functionalized Poly(3‐hexylthiophene) without Protecting Groups Using a Zincate Complex

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