22870-26-4Relevant academic research and scientific papers
Novel efficient procedure for the conjugate addition of amines to electron deficient alkenes
Sun, Xudong,Du, Yijun,Li, Chunqing,Qi, Chenze
, p. 653 - 656 (2010)
The novel efficient procedure has been developed for the conjugate addition of amines to electron deficient alkenes using the novel SO3H functionalized ionic liquid as catalyst. The results showed that the novel catalyst owned high activities for the reactions with excellent yields within several minutes. Various amines and electron deficient alkenes were successfully transformed to the corresponding products in the catalytic system. Operational simplicity, without need of any solvent, low cost of the catalyst used, room temperature, high yields, reusability, excellent chemoselectivity and wide applicability are the key features of this methodology.
Photocatalytic α-Tertiary Amine Synthesis via C?H Alkylation of Unmasked Primary Amines
Alder, Catherine M.,Ballantyne, George,Cresswell, Alexander J.,Cunningham, William B.,Edwards, Lee J.,Grayson, Matthew N.,Kinsella, Anna G.,McKay, Blandine S. J.,Mules, Tom,Ryder, Alison S. H.,Turner-Dore, Jacob
supporting information, p. 14986 - 14991 (2020/06/20)
A practical, catalytic entry to α,α,α-trisubstituted (α-tertiary) primary amines by C?H functionalisation has long been recognised as a critical gap in the synthetic toolbox. We report a simple and scalable solution to this problem that does not require any in situ protection of the amino group and proceeds with 100 percent atom-economy. Our strategy, which uses an organic photocatalyst in combination with azide ion as a hydrogen atom transfer (HAT) catalyst, provides a direct synthesis of α-tertiary amines, or their corresponding γ-lactams. We anticipate that this methodology will inspire new retrosynthetic disconnections for substituted amine derivatives in organic synthesis, and particularly for challenging α-tertiary primary amines.
Deep compositional understanding of TBA: AlCl3 ionic liquid for its applications
Bhakthavatsalam, Vishnupriya,Chandra, Sudeshna,Choudhury, Rudra Prosad,Lande, Sharad V.,Pradhan, Jeevan,Sakhalkar, Mangesh
, (2020/07/31)
Chloroaluminate ionic liquids (ILs) have been immensely used as homogeneous catalyst in Friedel-Crafts reaction. We have recently synthesized chloroaluminate ILs by reacting aluminium chloride with a hydrophobic neutral ligand i.e. tributylamine (TBA:AlCl3). The current study elaborates on the investigations of the composition of the ionic liquids at various stages of their formation. The ionic liquids were synthesized using various mole ratios of tributyl amine and aluminium chloride in range of 1:1 to 1:2.3, in presence of an aromatic solvent in a one pot reaction. Various characterization techniques like Mass spectrometry, 27Al Nuclear Magnetic Resonance, 31P Nuclear Magnetic Resonance and Fourier Transform Infrared spectroscopy were used to elucidate the formation of various moieties of the TBA:AlCl3 Ionic Liquid. This study also elaborates on the investigations of the cationic and anionic moieties and their structure-property relationship for various applications. Various Friedel-Crafts reaction of industrial importance were performed using the ionic liquid having (Al2Cl7)?moiety to assess its performance and compared with conventional processes. The synthesized products were characterised by sophisticated analytical techniques like 1H NMR, 13C NMR, FTIR, GC–MS, GC-FID, to name a few. This class of ionic liquids also have importance in various electrochemical applications like aluminium deposition and aluminium batteries.
On-water magnetic NiFe2O4 nanoparticle-catalyzed Michael additions of active methylene compounds, aromatic/aliphatic amines, alcohols and thiols to conjugated alkenes
Payra, Soumen,Saha, Arijit,Banerjee, Subhash
, p. 95951 - 95956 (2016/10/25)
Here, we have demonstrated the Michael addition of active methylene compounds, aromatic/aliphatic amines, thiols and alcohols to conjugated alkenes using magnetic nano-NiFe2O4 as reusable catalyst in water. Nano-NiFe2O4 efficiently catalyzed the formation of C-C and C-X (X = N, S, O etc.) bond through 1,4-addition reactions.
Polymer coated magnetically separable organocatalyst for C[sbnd]N bond formation via aza-Michael addition
Panwar, Vineeta,Ray, Siddharth S.,Jain, Suman L.
, p. 5026 - 5032 (2016/11/02)
A polyacrylamide coated magnetite (PAM@MNP) catalyst was synthesized by following a two step approach involving the reaction of magnetite (Fe3O4) particles with coupling agent 3-(trimethoxysilyl)propyl methacrylate followed by grafting of acrylamide and subsequent polymerization via surface initiated radical polymerization technique. The synthesized organocatalyst was used for a one-pot aza-Michael addition reaction of amines with electron deficient alkenes to give β-amino carbonyls. The magnetic properties of the synthesized organocatalyst provide it a facile recovery by external magnet which eliminates the problems arising during catalyst separation by conventional filtration.
Lipase immobilization on hyroxypropyl methyl cellulose support and its applications for chemo-selective synthesis of β-amino ester compounds
Badgujar, Kirtikumar C.,Bhanage, Bhalchandra M.
, p. 1420 - 1433 (2016/10/03)
The present study carried out the synthesis of β-amino ester compounds using lipase immobilized on hyroxypropyl methyl cellulose (HMC) support. Initially various lipases (biocatalysts) from different origin were immobilized and subsequently screened to obtain the robust biocatalyst. The lipase Pseudomonas fluorescence (PFL) immobilized on HMC was displayed highest lipase activity, protein content and retention of activity. The physical and biochemical characterization verified immobilization of lipase PFL on the HMC support. This immobilized biocatalyst HMC:PFL (3.5:1) was successfully applied for the practical biocatalytic applications to synthesize variety of β-amino esters. Various eight reaction parameters were optimized in details to achieve the maximum yield and chemo-selectively. The developed biocatalytic protocol was successfully applied to synthesize different industrially important β-amino esters compounds (21 substrates) with an excellent yield (>90%) and remarkable chemo selectivity (>94%). Interestingly, the immobilized HMC:PFL lipase showed 2.1–2.5 folds higher bio-catalytic activity and five times recyclability as compared to the free PFL. The plausible mechanism for lipase catalyzed synthesis of β-amino ester compounds was also proposed.
Aza-Michael reaction: Selective mono- versus bis-addition under environmentally-friendly conditions
Bosica, Giovanna,Spiteri, Jonathan,Borg, Caroline
, p. 2449 - 2454 (2014/04/03)
Aza-Michael reactions between primary amines and methyl propenoate have been investigated under environmentally-friendly solventless heterogeneous catalysis in order to obtain the mono- or the bis-adduct. The reaction conditions can be altered so as to maximise the yields of the required product with high selectivity.
Chemo/regioselective Aza-Michael additions of amines to conjugate alkenes catalyzed by polystyrene-supported AlCl3
Dai, Liyan,Zhang, Yi,Dou, Qianqian,Wang, Xiaozhong,Chen, Yingqi
, p. 1712 - 1716 (2013/03/13)
A simple and efficient procedure is presented for Aza-Michael additions of various amines with conjugate alkenes bearing electron withdrawing group catalyzed by polystyrene-supported aluminum chloride (Ps-AlCl3) without the use of any solvents. The catalyst shows high catalytic activity for both aromatic amines and aliphatic amines. Chemoselective additions of the two types of amines with conjugate alkenes are achieved. Regioselective additions of two different amino groups in one molecule proceed smoothly. Ps-AlCl 3 has better recyclability and can be reused several times without apparent loss of activity.
Carbon dioxide as a reversible amine-protecting agent in selective Michael additions and acylations
Peeters, Annelies,Ameloot, Rob,De Vos, Dirk E.
, p. 1550 - 1557 (2013/09/24)
Carbon dioxide can be used as a temporary protecting group for amines. A carbamic acid is formed reversibly when CO2 is bubbled through a solution of a sufficiently basic primary amine at room temperature and atmospheric pressure. This reaction is employed for the protection of the amine functionality in several reactions at room temperature where inter- or intramolecular selectivity is desired. The concept is demonstrated for the selective Michael additions to methyl acrylate of a normally less reactive sulfonamide in the presence of a strong amine nucleophile, or of a cyclic secondary amine in the presence of an aliphatic primary amine, or of a β-ketoester in the presence of amines. The selective acylation of an alcohol in the presence of an amine can be achieved under a CO2 atmosphere as well.
Highly efficient nanocrystalline zirconosilicate catalysts for the aminolysis, alcoholysis, and hydroamination reactions
Kore, Rajkumar,Srivastava, Rajendra,Satpati, Biswarup
, p. 2891 - 2904 (2014/01/06)
Nanocrystalline zirconosilicates and titanosilicates with MFI framework structure were hydrothermally synthesized by the addition of organosilanes in the synthesis composition of conventional zirconosilicate and titanosilicate materials. Materials were characterized by a complementary combination of X-ray diffraction, nitrogen sorption, scanning/transmission electron microscopy (S/TEM), ammonia temperature-programmed desorption (TPD), Fourier transform infrared (FT-IR) spectroscopy, and ultraviolet-visible (UV-vis) spectroscopic investigations. Nanocrystalline zeolite catalysts of the present study are reusable. They exhibit significantly higher catalytic activities in aminolysis and alcoholysis compared with the hitherto known catalysts. A range of β-amino alcohols/β-alkoxy alcohols with high regioselectivity were synthesized using zirconosilicates. Application of these materials was also extended in the synthesis of aminoesters by the hydroamination reaction of methyl acrylates and amines. Structure activity relationship was explained based on acidity measurements, reactivity of amines/alcohols, and adsorption of reactants on catalysts.
