57272-10-3Relevant academic research and scientific papers
Convenient and direct azidation of sec -benzyl alcohols by trimethylsilyl azide with bismuth(III) triflate catalyst
Tummatorn, Jumreang,Thongsornkleeb, Charnsak,Ruchirawat, Somsak,Thongaram, Phanida,Kaewmee, Benyapa
, (2015)
Sec-Benzyl azides were efficiently prepared by bismuth(III)-catalyzed direct azidation of sec-benzyl alcohols. The reaction was applied to a variety of substrates to provide the desired products in up to 99% yield within a short reaction time.
Facile Direct Coupling Reactions of MOM-protected Benzylic Alcohols Using Aluminum Chloride
Bui, Tien Tan,Kim, Hee-Kwon
supporting information, p. 1195 - 1198 (2021/08/03)
MOM group is one of the most commonly used protecting groups for alcohols. This study describes novel direct functionalization of the MOM-protected benzylic alcohols. Preparation of allylic compounds from benzyl MOM ethers was successfully achieved by utilization of allyltrimethylsilane and AlCl3. In addition, direct azidation of benzyl MOM ethers using TMSN3 was successful carried out under AlCl3-mediated reaction conditions. These results demonstrate that this novel synthetic procedure is a promising approach to direct functionalization of MOM-protected alcohols including allylation and azidation.
Direct AlCl3-catalyzed transformation of benzyl THP ethers and allyl benzyl ethers
Bui, Tien Tan,Kim, Hee-Kwon
, p. 388 - 397 (2020/10/15)
THP and allyl groups are frequently used for the protection of alcohols. In this study, novel direct transformations of benzyl THP ethers and allyl benzyl ethers, protected forms of alcohols, are reported. TMSN3 and AlCl3 were employ
A Direct Br?nsted Acid-Catalyzed Azidation of Benzhydrols and Carbohydrates
Regier, Jeffery,Maillet, Robert,Bolshan, Yuri
, p. 2390 - 2396 (2019/04/14)
Benzhydryl alcohols were converted into their corresponding diarylazidomethane analogues using azidotrimethylsilane (TMSN3) in the presence of a catalytic amount of a Br?nsted acid HBF4·OEt2. The azidation reactions proceeded in high yields and demonstrated excellent functional group tolerance to electron-donating and electron-withdrawing substituents. In addition, a range of unprotected functional groups including amine, amide, aldehyde and alcohol were well-tolerated. Furthermore, this methodology was successfully applied to carbohydrates for the preparation of the corresponding azide derivatives.
Highly selective direct azidation of alcohols over a heterogeneous povidone-phosphotungstic solid acid catalyst
Kamble, Sumit,More, Sagar,Rode, Chandrashekhar
, p. 10240 - 10245 (2016/12/06)
A simple protocol for the selective azidation of alcohols is developed using a solid acid hybrid of a povidone and phosphotungstic acid (PVP-PWA) using azidotrimethylsilane as an azide source at room temperature. In a broad substrate scope, various activated as well as unactivated benzylic and diphenyl alcohols were treated smoothly with TMS-N3 to selectively produce only azide products with excellent yields in a very short reaction time of 2 h. FT-IR confirmed the stability of the catalyst with retention of the Keggins structure after the reaction. Recycling experiments demonstrated the reusability of the PVP-PWA (3?:?1) several times without losing its original activity.
Direct Conversion of Aldehydes and Ketones into Azides by Sequential Nucleophilic Addition and Substitution
Goswami, Pratik P.,Suding, Victoria P.,Carlson, Angela S.,Topczewski, Joseph J.
supporting information, p. 4805 - 4809 (2016/10/13)
This report describes the direct conversion of aldehydes and ketones into alkyl azides by the addition of common organometallic reagents and tandem conversion of the resulting alkoxides without isolation of the intermediate alcohols. A wide range of aldehydes and organometallic reagents (R–Li or R–MgX) are suitable participants in this process. Additional reaction telescoping beyond azide formation is demonstrated.
Convenient and direct azidation of sec -benzyl alcohols by trimethylsilyl azide with bismuth(III) triflate catalyst
Tummatorn, Jumreang,Thongsornkleeb, Charnsak,Ruchirawat, Somsak,Thongaram, Phanida,Kaewmee, Benyapa
, p. 323 - 329 (2015/02/19)
Sec-Benzyl azides were efficiently prepared by bismuth(III)-catalyzed direct azidation of sec-benzyl alcohols. The reaction was applied to a variety of substrates to provide the desired products in up to 99% yield within a short reaction time.
ZrCl 4-catalyzed C-O bond to C-N bond formation: Synthesis of 1,2,3-triazoles and their biological evaluation
Sharma, Gangavaram V. M.,Kumar, Kandikonda Suresh,Kumar, Buddana Sudheer,Reddy, Sheri Venkata,Prakasham, Reddy Shetty,Hugel, Helmut
supporting information, p. 3156 - 3164 (2015/10/12)
A simple and efficient protocol was developed for the synthesis of aryl azides directly from aryl carbinols using ZrCl4 as a Lewis acid catalyst. The azides were converted to novel triazoles under click reaction conditions, which were evaluated
Indium(III) bromide catalyzed direct azidation of α-hydroxyketones using TMSN3
Kumar, Anil,Sharma, Ramesh K.,Singh, Tej V.,Venugopalan, Paloth
, p. 10724 - 10732 (2013/12/04)
The direct catalytic azidation of 2-hydroxy-1,2,2-triarylethanones occurs at room temperature using 2 mol % of InBr3 as Lewis acid and TMSN3 as soluble azide source. 2-Azido-1,2,2-triarylethanones have been isolated in excellent yields. The role of aryl group and stereoelectronic factors indicate that the mechanism may involve the formation of a stable carbenium ion towards azidation.
A mild and efficient method for formation of C-N bond from benzyl alcohols and sulfonamide, carboxamide, 4-nitroanline and azide catalysed by SnCl 4
Li, Lingjun,Zhu, Anlian,Yao, Huiwen,Wei, Yujing,Yang, Di,Li, Jianping,Zhang, Guisheng
experimental part, p. 511 - 513 (2010/12/25)
A mild and efficient method for the formation of C-N bonds is reported with SnCl4 as an inexpensive catalyst. With 10 mol% of SnCl4, the direct substitution reaction of secondary benzyl alcohols with a sulfonamide, a carboxamide, 4-nitroaniline and an azide proceeds well in good to excellent yields at room temperature.
