1246775-58-5

Upstream product

• 623-12-1 4-chloromethoxybenzene 
• 24544-04-5 2,6-diisopropylbenzenamine 
• 696-62-8 para-iodoanisole 
• 104-92-7 1-bromo-4-methoxy-benzene 

Relevant academic research and scientific papers

Room-Temperature CuI-Catalyzed Amination of Aryl Iodides and Aryl Bromides

A general and effective CuI/N′,N′-diaryl-1H-pyrrole-2-carbohydrazide catalyst system was developed for the amination of aryl iodides and bromides at room temperature with good chemoselectivity between -OH and -NH2 groups. Only 5 mol % of CuI and ligands was needed in this protocol to effect the amination of various aryl bromides and aryl iodides with a wide range of aliphatic and aryl amines (1.3 equiv).

Arylation of Amines in Alkane Solvents by using Well-Defined Palladium-N-Heterocyclic Carbene Complexes

The use of the ITent-based series of Pd-N-heterocyclic carbenes precatalysts (Tent= Tentacular) enables the Buchwald-Hartwig amine arylation reaction in apolar alkane solvents. The use of such solvents is rare because of their poor solvation properties. Nonetheless, they could be of interest for industrial applications, as they can be disposed of in an energetically favorable manner and may potentially simplify product isolation. The excellent solubility of the precatalysts permitted the desired products to be obtained in yields ranging from 75 to 96 %, even with deactivated and functionalized coupling partners. Fueling cross-couplings: The use of ITent-based Pd precatalysts (Tent=tentacular) enables the Buchwald-Hartwig amine arylation reaction in alkane solvents. Such solvents could be of interest for industrial applications, as they can be disposed of in an energetically favorable manner and may potentially simplify product isolation. Yields ranging from 75 to 96 % are obtained, even with challenging substrates.

Development of an aryl amination catalyst with broad scope guided by consideration of catalyst stability

We have developed a new dialkylbiaryl monophosphine ligand, GPhos, that supports a palladium catalyst capable of promoting carbon-nitrogen cross-coupling reactions between a variety of primary amines and aryl halides; in many cases, these reactions can be carried out at room temperature. The reaction development was guided by the idea that the productivity of catalysts employing BrettPhos-like ligands is limited by their lack of stability at room temperature. Specifically, it was hypothesized that primary amine and N-heteroaromatic substrates can displace the phosphine ligand, leading to the formation of catalytically dormant palladium complexes that reactivate only upon heating. This notion was supported by the synthesis and kinetic study of a putative off-cycle Pd complex. Consideration of this off-cycle species, together with the identification of substrate classes that are not effectively coupled at room temperature using previous catalysts, led to the design of a new dialkylbiaryl monophosphine ligand. An Ot-Bu substituent was added ortho to the dialkylphosphino group of the ligand framework to improve the stability of the most active catalyst conformer. To offset the increased size of this substituent, we also removed the para i-Pr group of the non-phosphorus-containing ring, which allowed the catalyst to accommodate binding of even very large α-tertiary primary amine nucleophiles. In comparison to previous catalysts, the GPhos-supported catalyst exhibits better reactivity both under ambient conditions and at elevated temperatures. Its use allows for the coupling of a range of amine nucleophiles, including (1) unhindered, (2) five-membered-ring N-heterocycle-containing, and (3) α-tertiary primary amines, each of which previously required a different catalyst to achieve optimal results.

Allyl complexes for use in coupling reactions

A complex of formula (1), wherein, M is palladium or nickel, R1 and R2 are independently organic groups having 1-20 carbon atoms, or R1 and R2 are linked to form a ring structure with the phosphorus atom, R3 is selected from the group consisting of substituted and unsubstituted aryl, substituted and unsubstituted heteroaryl, and substituted and unsubstituted metallocenyl, R4 is an organic group having 1-20 carbon atoms, n is 0, 1, 2, 3, 4 or 5, X is an anionic ligand. A process for the preparation of the complex, and its use in carbon-carbon or carbon-nitrogen coupling reactions is also provided.

The invention relates to a N, N - disubstituted hydrazide as ligand copper catalysis C - N coupling method (by machine translation)

The invention discloses a to N, N - disubstituted hydrazide as ligand copper catalysis C - N coupling method, the method uses the aromatic halides with amine compound as a raw material, in order to alcohol compound as the solvent, in order to copper or copper compound as a catalyst, in order to as formula I or formula II as shown by a N, N - disubstituted hydrazide as a ligand, the presence of a base, in the 10 - 130 °C generating C - N coupled reaction for generating N - aryl compound: the invention mild reaction conditions, high chemical selectivity, substrate and wide range of application, simplicity of operation, product is simple and easy to separation and environmental protection, the obtained product yield is higher. Wherein R1, R2 is selected from methyl, phenyl, 4 - methoxyphenyl, 4 - nitro-phenyl, 2 - methylphenyl, 2 - isopropyl phenyl; R3 is hydrogen or methoxy. (by machine translation)

Trineopentylphosphine: A conformationally flexible ligand for the coupling of sterically demanding substrates in the Buchwald-Hartwig amination and suzuki-miyaura reaction

Trineopentylphosphine (TNpP) in combination with palladium provides a highly effective catalyst for the Buchwald-Hartwig coupling of sterically demanding aryl bromides and chlorides with sterically hindered aniline derivatives. Excellent yields are obtain

Efficient catalytic aryl amination of bromoarenes using 3-iminophosphine palladium(II) chloride

While pursuing the development of new hydroamination catalysts, a 3-iminophosphine palladium(II) chloride complex [(3IP)PdCl2] was synthesized that has subsequently proven to be an effective precatalyst for the aryl amination of bromoarenes. This (3IP)PdCl2 complex has been utilized in the catalytic aryl amination of both bromobenzene and bromopyridine derivatives, specifically yielding excellent activity in coupling reactions involving bromobenzene, 4-bromotoluene, and 2-bromopyridine. Using a standard set of catalytic conditions, many alkyl and aryl amines have been investigated as coupling partners in the aryl amination of bromoarenes. In general, secondary alkyl amines and ortho-substituted anilines proved to be the best substrates for this reaction, commonly giving quantitative conversion to products, while primary amines and other anilines gave only poor to moderate results. Catalytic screening data, product yields, and full characterization of isolated products are included.

Air-stable Pd(R-allyl)LCl (L= Q-Phos, P(t-Bu)3, etc.) Systems for C-C/N Couplings: Insight into the Structure - Activity Relationship and Catalyst Activation Pathway

A series of Pd(R-allyl)LCl complexes [R = H, 1-Me, 1-Ph, 1-gem-Me 2, 2-Me; L = Q-Phos, P(t-Bu)3, P(t-Bu)2-(p- NMe2C6H4), P(t-Bu)2Np] have been synthesized and evaluated in the Buchwald - Hartwig aminations in detail, in addition to the preliminary studies on Suzuki coupling and α-arylation reactions. Pd(crotyl)Q-PhosCl (9) was found to be a superior catalyst to the other Q-Phos-based catalysts, and the reported in situ systems, in model coupling reactions involving 4-bromoanisole substrate with either N-methylaniline or 4-tertbutylbenzeneboronic acid. Precatalyst 9 also performed better (Figure presented) than the catalysts bearing P(t-Bu)2(p- NMe2C6H4) ligand; however, it is comparable to the new crotyl catalysts bearing P(t-Bu)3 or P(t-Bu)2Np ligands. In α-arylation of a biologically important model substrate, 1-tetralone, Pd(allyl)P(t-Bu)2(p-NMe2C6H 4)Cl (15) was found to be the best catalyst. The reason for the relatively higher activity of the crotyl complexes in comparison to the allyl derivatives in C-N bond formation reactions was investigated using X-ray crystallography in conjunction with NMR spectroscopic studies.

Synthesis and X-ray structure determination of highly active Pd(II), Pd(I), and Pd(0) complexes of Di(tert -butyl)neopentylphosphine (DTBNpP) in the arylation of amines and ketones

The air-stable complex Pd(eta;3-allyl)(DTBNpP)Cl (DTBNpP = di(tert-butyl)neopentylphosphine) serves as a highly efficient precatalyst for the arylation of amines and enolates using aryl bromides and chlorides under mild conditions with yields ranging from 74% to 98%. Amination reactions of aryl bromides were carried out using 1-2 mol % Pd(η3-allyl)(DTBNpP)Cl at 23-50 °C without the need to exclude oxygen or moisture. The C-N coupling of the aryl chlorides occurred at relatively lower temperature (80-100 °C) and catalyst loading (1 mol %) using the Pd(eta;3-allyl) (DTBNpP)Cl precatalyst than the catalyst generated in situ from DTBNpP and Pd2(dba)3 (100-140 °C, 2-5 mol % Pd). Other Pd(DTBNpP)2-based complexes, (Pd(DTBNpP)2 and Pd(DTBNpP)2Cl2) were ineffective precatalysts under identical conditions for the amination reactions. Both Pd(DTBNpP)2 and Pd(DTBNpP)2Cl2 precatalysts gave nearly quantitative conversions to the product in the α-arylation of propiophenone with p-chlorotoluene and p-bromoanisole at a substrate/catalyst loading of 100/1. At lower substrate/ca'alyst loading (1000/1), the conversions were lower but comparable to that of Pd(t-Bu3P)2. In many cases, the tri-tert-butylphosphine (TTBP) based Pd(I) dimer, [Pd(μ-Br)(TTBP)] 2, stood out to be the most reactive catalyst under identical conditions for the enolate arylation. Interestingly, the air-stable Pd(I) dimer, Pd2(DTBNpP)2(μ-Cl)(μ-allyl), was less active in comparison to [Pd(μ-Br)(TTBP)]2 and Pd(eta;3-allyl) (DTBNpP)Cl. The X-ray crystal structures of Pd(eta;3-allyl)(DTBNpP) Cl, Pd(DTBNpP)2Cl2, Pd(DTBNpP)2, and Pd 2(DTBNpP)2(μ-Cl)(μ-allyl) are reported in this paper along with initial studies on the catalyst activation of the Pd(eta;3-allyl)(DTBNpP)Cl precatalyst.