Cupric Halide Halogenations

Castro, C. E.; Gaughan, E. J.; Owsley, Dennis C.

doi:10.1021/jo01013a069

Cited by 95 publications

(44 citation statements)

References 1 publication

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“…Acids 2 and 3 a-c were prepared stereoselectively in good yields, using a previously developed direct halogena-tion reaction of propiolic acid derivatives (Scheme 3). [17] Acid 3 d was obtained by following a procedure, based on that described by Castro et al [18] In a similar study, using b-iodoacrylic acid derivatives as substrates, we reported very similar conclusions. [16] The minimum requirements for good performances in this process were at least 0.2 equivalents of CuI, 2 equivalents of K 2 CO 3 , 2 equivalents of terminal alkyne and the acid in a polar solvent, such as DMF or DMSO, with temperatures between 55 and 65 8C.…”

supporting

confidence: 66%

Carboxylate‐Directed Tandem Functionalisations of α,β‐Dihaloalkenoic Acids with 1‐Alkynes: A Straightforward Access to (Z)‐Configured, α,β‐Substituted γ‐Alkylidenebutenolides

Ngi¹,

Cherry²,

Héran³

et al. 2011

Chemistry A European J

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An easy and mild copper(I)‐catalysed lactonisation of readily available (E)‐2,3‐dihalopropenoic acid derivatives regio‐ and stereoselectively leads to rarely described (Z)‐3‐halo‐5‐ylidene‐5H‐furan‐2‐ones. These compounds are subsequently able to undergo classical Pd‐catalysed cross‐coupling reactions, providing 3‐substituted and 3,4‐disubstituted 5‐ylidene‐5H‐furan‐2‐ones (see scheme).

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supporting

confidence: 66%

Carboxylate‐Directed Tandem Functionalisations of α,β‐Dihaloalkenoic Acids with 1‐Alkynes: A Straightforward Access to (Z)‐Configured, α,β‐Substituted γ‐Alkylidenebutenolides

Ngi¹,

Cherry²,

Héran³

et al. 2011

Chemistry A European J

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“…Its dependence on chloride can also be established because chloride in CuCl 2 is very reactive with many carbon-based compounds. This compound is commonly used for the chlorination of carbonyls 18 and aromatics 19 and as a catalyst for carbonyl compound reactions with alkenes 20 . By fixing the position of the carbon-oxygen ( C O) bond on the surface and reducing CuCl 2 in the electrolyte 21 , we can easily generate an additional redox CuCl layer (Fig.…”

mentioning

confidence: 99%

Synergistic interaction between redox-active electrolyte and binder-free functionalized carbon for ultrahigh supercapacitor performance

et al. 2013

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Development of supercapacitors with high-energy density and high-power density is a tremendous challenge. Although the use of conductive carbon materials is promising, other methods are needed to reach high cyclability, which cannot be achieved by fully utilizing the surface-oxygen redox reactions of carbon. Here we introduce an effective strategy that utilizes Cu 2 þ reduction with carbon-oxygen surface groups of the binder-free electrode in a new redox-active electrolyte. We report a 10-fold increase in the voltammetric capacitance (4,700 F g À 1 ) compared with conventional electrolyte. We measured galvanostatic capacitances of 1,335 F g À 1 with a retention of 99.4% after 5,000 cycles at 60 A g À 1 in a threeelectrode cell and 1,010 F g À 1 in a two-electrode cell. This improvement is attributed to the synergistic effects between surface-oxygen molecules and electrolyte ions as well as the low charge transfer resistance (0.04 O) of the binder-free porous electrode. Our strategy provides a versatile method for designing new energy storage devices and is promising for the development of high-performance supercapacitors for large-scale applications.

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“…Although we have no evidence about the reaction mechanism, the above intramolecular cyclizations can be explained by the disproportionation of CuBr 2 to CuBr and Br 2 in acetonitrile solution. 24 The generated bromine reacted with the alkene function to form the unstable bromonium cation intermediates which were attacked by sterically close phenolic group. Incidentally, this is an unprecedented route to the synthesis of chroman skeleton.…”

Section: Methodsmentioning

confidence: 99%

Microwave-Accelerated Alkylation of Arenes/Heteroarenes with Benzylic Alcohols Using Antimony(III) Chloride as Catalyst: Synthesis of O-Heterocycles

Shukla¹,

Choudhary²,

Nayak³

2011

Synlett

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An efficient protocol for alkylation of electron-rich arenes/heteroarenes with benzylic alcohols under microwave irradiation using antimony(III) chloride as catalyst has been developed. The mild reaction conditions, high yields, operational simplicity, and applicability to various substrates render the approach a useful route for the synthesis of diaryl/triarylalkane. In addition, a new route for the conversion of ortho-alkenylated phenols into functionalized O-heterocycles has been accomplished.

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Cupric Halide Halogenations

Cited by 95 publications

References 1 publication

Carboxylate‐Directed Tandem Functionalisations of α,β‐Dihaloalkenoic Acids with 1‐Alkynes: A Straightforward Access to (Z)‐Configured, α,β‐Substituted γ‐Alkylidenebutenolides

Carboxylate‐Directed Tandem Functionalisations of α,β‐Dihaloalkenoic Acids with 1‐Alkynes: A Straightforward Access to (Z)‐Configured, α,β‐Substituted γ‐Alkylidenebutenolides

Synergistic interaction between redox-active electrolyte and binder-free functionalized carbon for ultrahigh supercapacitor performance

Microwave-Accelerated Alkylation of Arenes/Heteroarenes with Benzylic Alcohols Using Antimony(III) Chloride as Catalyst: Synthesis of O-Heterocycles

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