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VIETNAM NATIONAL UNIVERSITY – HO CHI MINH CITY HO CHI MINH CITY UNIVERSITY OF TECHNOLOGY NGUYEN THI HONG ANH USING IONIC LIQUID AS SOLVENT FOR COUPLING, AND HALOGEN EXCHANGE REACTIONS PHD THESIS HO CHI MINH CITY 2018 VIETNAM NATIONAL UNIVERSITY – HO CHI MINH CITY HO CHI MINH CITY UNIVERSITY OF TECHNOLOGY NGUYEN THI HONG ANH USING IONIC LIQUID AS SOLVENT FOR COUPLING, AND HALOGEN EXCHANGE REACTIONS Major: Organic Chemical Technology Major code: 62527505 Independent examiner 1: Prof Dr Nguyen Kim Phi Phung Independent examiner 2: Assoc Prof Dr Pham Thanh Huyen Examiner 1: Assoc Prof Dr Nguyen Thi Dung Examiner 2: Assoc Prof Dr Vu Anh Tuan Examiner 3: Assoc Prof Dr Pham Thanh Quan ADVISORS: Prof Dr Phan Thanh Son Nam Dr Truong Vu Thanh DECLARATION OF ORIGINALITY I hereby declare that this is my own research study The research suitable condition and conclusions in this thesis are true, and are not copied from any other resources The literature references have been quoted with clear citation as requested Thesis Author Sign Nguyen Thi Hong Anh Page i TÓM TẮT LUẬN ÁN Trong nghiên cứu này, chất lỏng ion 1-alkyl-3-methyl imidazolium bromide tổng hợp thành công hỗ trợ vi sóng với chế độ gián đoạn 10 giây tạo chất lỏng ion có màu vàng nhạt Sau đó, chất lỏng ion đem thực phản ứng trao đổi anion với hexafluorophosphoric acid để tạo chất lỏng ion 1-alkyl-3-methyl imidazolium hexafluorophosphate Các đặc trưng cấu trúc chất lỏng ion sau tổng hợp xác định phương pháp phổ cộng hưởng từ hạt nhân (1H, 13 C NMR) phổ khối lượng (MS) Các chất lỏng ion 1-alkyl-3-methyl imidazolium khảo sát khả làm dung môi cho phản ứng ghép đôi phản ứng trao đổi halogen để tìm điều kiện thích hợp cho phản ứng đối chiếu với dung môi hữu thông thường khác Kết nghiên cứu thu tìm loại chất lỏng ion thích hợp cho phản ứng tất điều kiện thích hợp cho loại phản ứng khơng trùng hồn tồn với cơng trình khác cụ thể mô tả đây: Phản ứng 1: Ngưng tụ salicylaldehyde với methyl acetoacetate để tạo thành 3acetylcoumarin đạt độ chuyển hóa 86% 100 oC sau giờ, sử dụng chất lỏng ion [BMIM]Br làm dung môi Phản ứng 2: Ngưng tụ 1,2-phenylenediamine acetone để tổng hợp 1,5benzodiazepine tiến hành nhiệt độ thường có sử dụng chất lỏng ion [HMIM]Br làm dung mơi với độ chuyển hóa 100% sau 45 oC Phản ứng 3: N-aryl hóa piperidine 4-bromonitrobenzene để tạo 1- (4nitrophenyl)piperidine độ chuyển hóa đạt 94% sau 90 oC, sử dụng [BMIM]Br làm dung môi Phản ứng 4: Phản ứng 1-(N-morpholino)-2-chloroethane hydrochloride 2methylindole để tạo 1-(2-(N-morpholino)ethyl)-2-methylindole đạt hiệu suất khoảng 75% sau Phản ứng thực dung môi [BMIM]PF6 30 oC Phản ứng 5: Phản ứng Paal-Knorr tổng hợp pyrrole thực 2,5-hexadione amin dung môi chất lỏng ion [BMIM]PF6 với độ chuyển hóa đạt 100% thời gian 40 phút nhiệt độ 30 oC Page ii Phản ứng 6: Phản trao đổi halogen aryl iodides đồng (I) bromide thực sử dụng [BMIM]Br làm dung môi để tạo thành aryl bromide tương ứng với hiệu suất phản ứng đạt 90% sau thời gian 140 oC Ngoài ra, chất lỏng ion 1-alkyl-3-methyl imidazolium thu hồi tái sử dụng nhiều lần cho phản ứng mà hiệu giảm không đáng kể Các sản phẩm thu phản ứng xác định cấu trúc qua MS NMR Page iii ABSTRACT In this research, 1-alkyl-3-methyl imidazolium bromide ionic liquids were successfully synthesized under microwave conditions After that, 1-alkyl-3-methyl imidazolium hexafluorophosphate [AMIM]PF6 ionic liquid was prepared by anion exchange reaction of dialkylimidazolium bromide with hexafluorophosphoric acids The structural properties of prepared ionic liquids were characterized by using Nuclear Magnetic Resonance (1H, 13C NMR) and Mass Spectrometry (MS) analysis More interestingly, the results showed that dialkylimidazolium ionic liquid could effectively act as green solvents for coupling reactions, and halogen exchange reaction with high conversion under low temperature and shorter reaction time in comparison with conventional solvents Some typical results are described below: Reaction The condensation reaction of salicylaldehyde and methyl acetoacetate formed 3-acetylcoumarin with approximately 86% conversion after hours at 100 °C with, [BMIM]Br ionic liquid as a solvent Reaction The condensation reaction between 1,2-phenylenediamine and acetone to synthesize 1,5-benzodiazepine could occur at 45 oC with 100% conversion after hours in [HMIM]Br ionic liquid Reaction The N-aryl reaction between piperidine and 4-bromonitrobenzene to form 1-(4-nitrophenyl) piperidine can reach approximately 94% conversion after hours with [BMIM]Br as a solvent at 90 oC Reaction 1-(2-(N-morpholino)ethyl)-2-methylindole was synthesized by the reaction between 1-(N-morpholino)-2-chloroethane hydrochloride and 2-methylindole formed with about 75% conversion after hours in [BMIM]PF6 ionic liquid at 30 oC Reaction Paal-Knorr reaction for synthesis of pyrroles was performed [BMIM]PF6 ionic liquid with 100% conversion after 40 minutes at 30 oC Reaction Halogen exchange reaction between aryl iodides and copper (I) bromide to form aryl bromide derivatives could reach more than 90% conversion in [BMIM]Br ionic liquid as a solvent after hours at 140 oC Page iv Interestingly, the recycle of [BMIM]Br ionic liquid was performed The results showed that [BMIM]Br ionic liquid can be recovered and successfully recycled into subsequent reactions without significant loss of activity The main products were identified by GC-MS and NMR Page v ACKNOWLEDGMENT First and foremost I am deeply grateful to my advisor Prof Dr Nam Phan Thanh Son for his excellent guidance during the work It has been an honor to be his Ph.D student He has taught me, both consciously and unconsciously, how well experimental physics is done I am also thankful to Dr Truong Vu Thanh, who guided me through my studies with kindness and huge encouragement, especially during a difficult period of studying to complete my thesis I am indebted to the organic department members including: Dr Le Thi Hong Nhan, Dr Le Thanh Dung, Dr Tong Thanh Danh and PhD student Le Vu Ha, who had accompanied me throughout the process of implementing the thesis Additionally, I will never forget the support, encouragement and great memories of my colleagues that we had been experienced during working time in the Manar laboratory-University of Technology, Vietnam National University HCMC I am especially thankful to my husband, Associate Professor Dr Nguyen Van Cuong for his love and support during my study He is always there for me whenever I need him I am also deeply thankful to my little angels, Nguyen Tuan Thanh and Nguyen Anh Thanh Ngoc for giving me smile and motivation to try myself best to anything I am extremely grateful to my parents, my sisters and my brothers for their priceless consolation, encouragement and support through my academic work Last, but not least, I wish to thank to my colleagues, my friends at Ho Chi Minh City University of Food Industry for their supports during the work Nguyen Thi Hong Anh, 2018 Page vi TABLE OF CONTENTS DECLARATION OF ORIGINALITY i TÓM TẮT LUẬN ÁN ii ABSTRACT iv ACKNOWLEDGMENT vi TABLE OF CONTENTS vii LIST OF FIGURES xi LIST OF SCHEMES xiii LIST OF TABLES .xvi LIST OF ABBREVIATION xvii INTRODUCTION xix CHAPTER 1.1 LITERATURE REVIEW .1 IONIC LIQUIDs (ILs) .1 1.1.1 Introduction to ionic liquids 1.1.2 Imidazolium ionic liquids 1.1.3 Synthesis of Ionic Liquids 1.1.4 Properties of ILs 1.2 Ionic liquids as solvents 12 1.2.1 Heck reaction 15 1.2.2 Reaction of bromobenzene with butyl acrylate in molten tetraalkylammonium and tetraalkylphosphonium bromide salts (Suzuki reaction) .15 1.2.3 The esterification .16 1.2.4 Transition metal catalysis 17 1.2.5 Alkene hydrogenation reactions 17 1.2.6 Hydroformylation 18 1.2.7 Oxidation 19 1.3 Reactions Literature review .19 1.3.1 Condensative reaction .19 Page vii 1.3.2 Carbon-Nitrogen coupling 24 1.3.3 Halogen exchange .34 1.4 AIMS AND OBJECTIVES .39 CHAPTER EXPERIMENTAL .40 2.1 Materials and instrumentation 40 2.2 Synthesis of ionic liquids 42 2.2.1 Preparation of 1-alkyl-3-methylimidazolium bromide 42 2.2.2 Preparation of 1-alkyl-3-methylimidazolium hexafluorophosphate [AMIM]PF6] ILs 44 2.3 Studied Reaction 46 2.3.1 Synthesis of coumarin derivatives 46 2.3.2 Synthesis of 1,5-benzodiazepine derivatives 47 2.3.3 Synthesis of 1-(4-nitrophenyl)piperidine derivatives 48 2.3.4 Synthesis of 1-[2-(N-morpholino)ethyl]-2-methylindole derivatives .49 2.3.5 Synthesis of pyrrole derivatives 50 2.3.6 Halogen exchange reaction .51 CHAPTER 3.1 RESULTS AND DISCUSSION 53 The synthesis of ionic liquids 53 3.1.1 The synthesis of [AMIM]Br 53 3.1.1 [AMIM]Br ILs characterization 55 3.1.2 The synthesis of [AMIM]PF6 58 3.1.3 [AMIM]PF6 ILs characterization 60 3.2 Synthesis of coumarin derivatives (Reaction 1) 62 3.2.1 Effect of the alkyl chain length in the cation of ionic liquid on reaction conversion 63 3.2.2 Effect of various anion species of ionic liquid on the reaction conversion .64 3.2.3 Effect of different solvents on the reaction conversion 65 3.2.4 Reusability of [BMIM]Br ionic liquid 67 3.3 Synthesis of 1,5-benzodiazepine derivatives (Reaction 2) 69 3.3.1 Effect of temperature on the reaction conversion .69 3.3.2 Effect of [HMIM]Br concentration on the reaction conversion .70 Page viii [45] [46] [47] [48] [49] [50] [51] [52] [53] [54] [55] [56] [57] [58] A J Carmichael, and K R Seddon, Polarity study of some 1‐alkyl‐3‐methylimidazolium ambient‐temperature ionic liquids with the solvatochromic dye, Nile Red, Journal of Physical Organic Chemistry, vol 13, no 10, pp 591-595, 2000 A E Visser, R P Swatloski, W M Reichert, R Mayton, S Sheff, A Wierzbicki, J H Davis, and R D Rogers, Task-specific ionic liquids incorporating novel cations for the coordination and extraction of Hg2+ and Cd2+: synthesis, characterization, and extraction studies, Environmental science & technology, vol 36, no 11, pp 2523-2529, 2002 R Renner, Ionic liquids: an industrial cleanup solution, Environmental science & technology, vol 35, no 19, pp 410A-413A, 2001 J Gorman, Faster, better, cleaner?: New liquids take aim at old‐fashioned chemistry, Science News, vol 160, no 10, pp 156-158, 2001 J F Brennecke, and E J Maginn, Ionic liquids: innovative fluids for chemical processing, AIChE Journal, vol 47, no 11, pp 2384-2389, 2001 Q Yang, and D D Dionysiou, Photolytic degradation of chlorinated phenols in room temperature ionic liquids, Journal of Photochemistry and Photobiology A: Chemistry, vol 165, no 1, pp 229-240, 2004 K Seddon, Room-temperature ionic liquids: neoteric solvents for clean catalysis, Kinetics and Catalysis, vol 37, no 5, pp 693-697, 1995 C Lagrost, D Carrie, M Vaultier, and P Hapiot, Reactivities of some electrogenerated organic cation radicals in room-temperature ionic liquids: toward an alternative to volatile organic solvents?, The Journal of Physical Chemistry A, vol 107, no 5, pp 745-752, 2003 A Shariati, and C J Peters, High-pressure phase equilibria of systems with ionic liquids, The Journal of Supercritical Fluids, vol 34, no 2, pp 171-176, 2005 A Shariati, K Gutkowski, and C J Peters, Comparison of the phase behavior of some selected binary systems with ionic liquids, AIChE Journal, vol 51, no 5, pp 1532-1540, 2005 H Zhao, S Xia, and P Ma, Use of ionic liquids as ‘green’solvents for extractions, Journal of chemical technology and biotechnology, vol 80, no 10, pp 1089-1096, 2005 C Chiappe, M Malvaldi, and C S Pomelli, Ionic liquids: Solvation ability and polarity, Pure and Applied Chemistry, vol 81, no 4, pp 767-776, 2009 C Reichardt, Polarity of ionic liquids determined empirically by means of solvatochromic pyridinium N-phenolate betaine dyes, Green Chemistry, vol 7, no 5, pp 339-351, 2005 F V Bright, and G A Baker, Comment on “How Polar Are Ionic Liquids? Determination of the Static Dielectric Constant of an Imidazolium-based Ionic Liquid by Microwave Dielectric Spectroscopy”, The Journal of Physical Chemistry B, vol 110, no 11, pp 5822-5823, 2006 122 [59] [60] [61] [62] [63] [64] [65] [66] [67] [68] [69] [70] [71] [72] J.-M Lee, S Ruckes, and J M Prausnitz, Solvent polarities and kamlet-taft parameters for ionic liquids containing a pyridinium cation, The Journal of Physical Chemistry B, vol 112, no 5, pp 1473-1476, 2008 D E Kaufmann, M Nouroozian, and H Henze, Molten salts as an efficient medium for palladium catalyzed CC coupling reactions, Synlett, vol 1996, no 11, pp 1091-1092, 1996 C J Mathews, P J Smith, and T Welton, Palladium catalysed Suzuki crosscoupling reactions in ambient temperature ionic liquids, Chemical Communications, no 14, pp 1249-1250, 2000 H.-P Zhu, F Yang, J Tang, and M.-Y He, Brønsted acidic ionic liquid 1methylimidazolium tetrafluoroborate: a green catalyst and recyclable medium for esterification, Green Chemistry, vol 5, no 1, pp 38-39, 2003 A C Cole, J L Jensen, I Ntai, K L T Tran, K J Weaver, D C Forbes, and J H Davis, Novel Brønsted acidic ionic liquids and their use as dual solvent− catalysts, Journal of the American Chemical Society, vol 124, no 21, pp 59625963, 2002 R T Carlin, and J S Wilkes, Complexation of Cp2MCl2 in a chloroaluminate molten salt: relevance to homogeneous Ziegler-Natta catalysis, Journal of Molecular Catalysis, vol 63, no 2, pp 125-129, 1990 P A Chaloner, M A Esteruelas, F Joo, and L Oro, Homogeneous Hydrogenation, Netherlands: Springer Netherlands, 1994 M Medved, P Wasserscheid, and T Melin, Ionic liquids as active separation layer in supported liquid membranes, Chemie Ingenieur Technik, vol 73, no 6, pp 715-715, 2001 F Favre, H Olivier-Bourbigou, D Commereuc, and L Saussine, Hydroformylation of 1-hexene with rhodium in non-aqueous ionic liquids: how to design the solvent and the ligand to the reaction, Chemical Communications, no 15, pp 1360-1361, 2001 D Zhao, M Wu, Y Kou, and E Min, Ionic liquids: applications in catalysis, Catalysis today, vol 74, no 1–2, pp 157-189, 2002 M F Sellin, P B Webb, and D J Cole-Hamilton, Continuous flow homogeneous catalysis: hydroformylation of alkenes in supercritical fluid–ionic liquid biphasic mixtures, Chemical Communications, no 8, pp 781-782, 2001 V V Namboodiri, R S Varma, E Sahle-Demessie, and U R Pillai, Selective oxidation of styrene to acetophenone in the presence of ionic liquids, Green Chemistry, vol 4, no 2, pp 170-173, 2002 M A Martins, C P Frizzo, D N Moreira, N Zanatta, and H G Bonacorso, Ionic liquids in heterocyclic synthesis, Chem Rev, vol 108, no 6, pp 2015-2050, 2008 S Verma, S Kumar, S L Jain, and B Sain, Thiourea dioxide promoted efficient organocatalytic one-pot synthesis of a library of novel heterocyclic compounds, Organic & biomolecular chemistry, vol 9, no 20, pp 6943-6948, 2011 123 [73] [74] [75] [76] [77] [78] [79] [80] [81] [82] [83] [84] [85] D Z Qiang, J B Shi, B A Song, and X H Liu, Novel 2H-chromen derivatives: design, synthesis and anticancer activity, RSC Advances, vol 4, no 11, pp 56075617, 2014 M N Deshmukh, R Burud, C Baldino, P C M Chan, and J Liu, A Practical and Environmentally Friendly Preparation of 3-Carboxycoumarins, Synthetic Communications, vol 33, no 19, pp 3299-3303, 2003 H Valizadeh, and H Gholipour, Imidazolium-Based Phosphinite Ionic Liquid (ILOPPh2) as Reusable Catalyst and Solvent for the Knoevenagel Condensation Reaction, Synthetic Communications, vol 40, no 10, pp 1477-1485, 2010 N Aider, A Smuszkiewicz, E Pérez-Mayoral, E Soriano, R M Martín-Aranda, D Halliche, and S Menad, Amino-grafted SBA-15 material as dual acid–base catalyst for the synthesis of coumarin derivatives, Catalysis Today, vol 227, pp 215-222, 2014 T S Shaikh, K A Undale, D S Gaikwad, and D M Pore, Envirocat EPZ-10: An efficient catalyst for the synthesis of 3-acetoacetylcoumarins, Comptes Rendus Chimie, vol 14, no 11, pp 987-990, 2011 A E R S Khder, S A Ahmed, K S Khairou, and H M Altass, Competent, selective and high yield of 7-hydroxy-4-methyl coumarin over sulfonated mesoporous silica as solid acid catalysts, Journal of Porous Materials, vol 25, no 1, pp 1-13, 2018 B Z Kurt, N Ozten Kandas, A Dag, F Sonmez, and M Kucukislamoglu, Synthesis and biological evaluation of novel coumarin-chalcone derivatives containing urea moiety as potential anticancer agents, Arabian Journal of Chemistry, 2017/10/07/, 2017 (Corrected Proof) H Xu, L Laraia, L Schneider, K Louven, C Strohmann, A P Antonchick, and H Waldmann, Highly enantioselective catalytic vinylogous propargylation of coumarins yields a class of autophagy inhibitors, Angewandte Chemie International Edition, vol 56, no 37, pp 11232-11236, 2017 N N Karade, S V Gampawar, S V Shinde, and W N Jadhav, L-Proline catalyzed solvent-free knoevenagel condensation for the synthesis of 3-substituted coumarins, Chinese Journal of Chemistry, vol 25, no 11, pp 1686-1689, 2007 E Aktoudianakis, and A P Dicks, Convenient microscale synthesis of a coumarin laser dye analog, J Chem Educ, vol 83, no 2, pp 287, 2006 B Karami, and M Kiani, ZrOCl2.8H2O/SiO2: An efficient and recyclable catalyst for the preparation of coumarin derivatives by Pechmann condensation reaction, Catalysis Communications, vol 14, no 1, pp 62-67, 2011 D Q Xu, W L Yang, S P Luo, B T Wang, J Wu, and Z Y Xu, Fischer indole synthesis in brønsted acidic ionic liquids: a green, mild, and regiospecific reaction system, European journal of organic chemistry, vol 2007, no 6, pp 1007-1012, 2007 H R Shaterian, and M Aghakhanizadeh, Ionic-liquid-catalyzed green synthesis of coumarin derivatives under solvent-free conditions, Chinese Journal of Catalysis, vol 34, no 9, pp 1690-1696, 2013 124 [86] [87] [88] [89] [90] [91] [92] [93] [94] [95] [96] [97] [98] S Bednarz, and D Bogdal, Kinetic study of the condensation of salicylaldehyde with diethyl malonate in a nonpolar solvent catalyzed by secondary amines, International Journal of Chemical Kinetics, vol 41, no 9, pp 589-598, 2009 R H Vekariya, and H D Patel, Recent advances in the synthesis of coumarin derivatives via knoevenagel condensation: A Review, Synthetic Communications, vol 44, no 19, pp 2756-2788, 2014 S S Bahekar, and D B Shinde, Samarium (III) catalyzed one-pot construction of coumarins, Tetrahedron letters, vol 45, no 43, pp 7999-8001, 2004 D.-Q Shi, Y Zhou, and S.-F Rong, Ionic liquid,[BMIM]Br, as an efficient promoting medium for synthesis of 3-acetoacetylcoumarin derivatives without the use of any catalyst, Synthetic Communications®, vol 39, no 19, pp 3500-3508, 2009 X Mi, C Wang, M Huang, Y Wu, and Y Wu, Preparation of 3-acyl-4arylcoumarins via metal-free tandem oxidative acylation/cyclization between alkynoates with aldehydes, The Journal of organic chemistry, vol 80, no 1, pp 148-155, 2014 S K Gadakh, S Dey, and A Sudalai, Rh-catalyzed synthesis of coumarin derivatives from phenolic acetates and acrylates via C–H bond activation, The Journal of organic chemistry, vol 80, no 22, pp 11544-11550, 2015 H S P Rao, and S Sivakumar, Condensation of α-aroylketene dithioacetals and 2-hydroxyarylaldehydes results in facile synthesis of a combinatorial library of 3aroylcoumarins, The Journal of organic chemistry, vol 71, no 23, pp 8715-8723, 2006 S K Ha, D Shobha, E Moon, M A Chari, K Mukkanti, S.-H Kim, K.-H Ahn, and S Y Kim, Anti-neuroinflammatory activity of 1,5-benzodiazepine derivatives, Bioorganic & medicinal chemistry letters, vol 20, no 13, pp 3969-3971, 2010 M Rekha, A Hamza, B Venugopal, and N Nagaraju, Synthesis of 2-substituted benzimidazoles and 1,5-disubstituted benzodiazepines on alumina and zirconia catalysts, Chinese Journal of Catalysis, vol 33, no 2, pp 439-446, 2012 Y.-S An, Z.-F Hao, X.-J Zhang, and L.-Z Wang, Efficient synthesis and biological evaluation of a novel series of 1,5-benzodiazepine derivatives as potential antimicrobial agents, Chemical Biology & Drug Design, vol 88, no 1, pp 110-121, 2016 W Ben-Cherif, R Gharbi, H Sebai, D Dridi, N A Boughattas, and M BenAttia, Neuropharmacological screening of two 1,5-benzodiazepine compounds in mice, Comptes rendus biologies, vol 333, no 3, pp 214-219, 2010 P Attri, and M Pal, Simple ammonium ionic liquid catalyses the 1,5benzodiazepine derivatives under mild conditions, Green Chemistry Letters and Reviews, vol 3, no 3, pp 249-256, 2010 X Zhou, M Y Zhang, S T Gao, J J Ma, C Wang, and C Liu, An efficient synthesis of 1,5-benzodiazepine derivatives catalyzed by boric acid, Chinese Chemical Letters, vol 20, no 8, pp 905-908, 2009 125 [99] [100] [101] [102] [103] [104] [105] [106] [107] [108] [109] [110] S Sibous, T Ghailane, S Houda, R Ghailane, S Boukhris, and A Souizi, Green and efficient method for the synthesis of 1,5-benzodiazipines using phosphate fertilizers as catalysts under free solvent, Mediterranean Journal of Chemistry, vol 6, no 3, pp 53-59, 2017 R A De Silva, S Santra, and P R Andreana, A tandem one-pot, microwaveassisted synthesis of regiochemically differentiated 1,2,4,5-tetrahydro-1,4benzodiazepin-3-ones, Organic letters, vol 10, no 20, pp 4541-4544, 2008 G D Yadav, and A R Yadav, Selective Green Synthesis of 1,5-Benzodiazepine over Modified Heteropolyacid as Nanocatalyst: Kinetics and Mechanism, Industrial & Engineering Chemistry Research, vol 52, no 50, pp 17812-17820, 2013 M Balakrishna, and B Kaboudin, A simple and new method for the synthesis of 1, 5-benzodiazepine derivatives on a solid surface, Tetrahedron Letters, vol 42, no 6, pp 1127-1129, 2001 M A Chari, and K Syamasundar, Polymer (PVP) supported ferric chloride: an efficient and recyclable heterogeneous catalyst for high yield synthesis of 1,5benzodiazepine derivatives under solvent free conditions and microwave irradiation, Catalysis communications, vol 6, no 1, pp 67-70, 2005 S Cacchi, G Fabrizi, A Goggiamani, and A Iazzetti, Construction of the 1,5benzodiazepine skeleton from o-phenylendiamine and propargylic alcohols via a domino gold-catalyzed hydroamination/cyclization process, Organic letters, vol 18, no 15, pp 3511-3513, 2016 M N Timofeeva, S A Prikhod’ko, K N Makarova, M E Malyshev, V N Panchenko, A B Ayupov, and S H Jhung, Iron-containing materials as catalysts for the synthesis of 1, 5-benzodiazepine from 1,2-phenylenediamine and acetone, Reaction Kinetics, Mechanisms and Catalysis, vol 121, no 2, pp 689-699, 2017 Q Geng, H Zhang, W Cao, and Y Chen, A Facile Synthesis of N‐Aryl Substituted Piperidones, Chinese Journal of Chemistry, vol 27, no 10, pp 19952000, 2009 C Mauger, O Buisine, S Caravieilhes, and G Mignani, Successful application of microstructured continuous reactor in the palladium catalysed aromatic amination, Journal of organometallic chemistry, vol 690, no 16, pp 3627-3629, 2005 G Evano, N Blanchard, and M Toumi, Copper-mediated coupling reactions and their applications in natural products and designed biomolecules synthesis, Chemical reviews, vol 108, no 8, pp 3054-3131, 2008 X.-H Fan, G Li, and L.-M Yang, Room-temperature nickel-catalyzed amination of heteroaryl/aryl chlorides with Ni (II)–(σ-Aryl) complex as precatalyst, Journal of Organometallic Chemistry, vol 696, no 13, pp 2482-2484, 2011 Y.-J Cherng, Efficient nucleophilic substitution reaction of aryl halides with amino acids under focused microwave irradiation, Tetrahedron, vol 56, no 42, pp 8287-8289, 2000 126 [111] M R Crampton, Nucleophilic Aromatic Substitution, "Organic reaction mechanisms", pp 155-165: John Wiley & Sons, Ltd, 2007 [112] E Santos Santos, I C Gavilán García, E F Lejarazo Gómez, and M A VilchisReyes, Synthesis of Aryl-substituted 2,4-dinitrophenylamines: nucleophilic aromatic substitution as a problem-solving and collaborative-learning approach, Journal of Chemical Education, vol 87, no 11, pp 1230-1232, 2010 [113] S M Raders, and J G Verkade, P (i-BuNCH2CH2)3N: an efficient promoter for the microwave synthesis of diaryl ethers, Tetrahedron Letters, vol 49, no 21, pp 3507-3511, 2008 [114] M Mečiarová, Š Toma, and P Magdolen, Ultrasound effect on the aromatic nucleophilic substitution reactions on some haloarenes, Ultrasonics sonochemistry, vol 10, no 4, pp 265-270, 2003 [115] Q Shen, and J F Hartwig, [(CyPF-tBu)PdCl2]: An air-stable, one-component, highly efficient catalyst for amination of heteroaryl and aryl halides, Organic letters, vol 10, no 18, pp 4109-4112, 2008 [116] B Fors, and S Buchwald, A multiligand-based palladium catalyst for cn crosscoupling reactions, Synfacts, vol 2011, no 02, pp 0199-0199, 2011 [117] D S Surry, and S L Buchwald, Dialkylbiaryl phosphines in Pd-catalyzed amination: a user's guide, Chemical Science, vol 2, no 1, pp 27-50, 2011 [118] J F Hartwig, Approaches to catalyst discovery New carbon–heteroatom and carbon–carbon bond formation, Pure and Applied Chemistry, vol 71, no 8, pp 1417-1423, 1999 [119] J Jiao, X.-R Zhang, N.-H Chang, J Wang, J.-F Wei, X.-Y Shi, and Z.-G Chen, A facile and practical copper powder-catalyzed, organic solvent-and ligand-free Ullmann amination of aryl halides, The Journal of organic chemistry, vol 76, no 4, pp 1180-1183, 2011 [120] W Zhou, M Fan, J Yin, Y Jiang, and D Ma, CuI/oxalic diamide catalyzed coupling reaction of (hetero) aryl chlorides and amines, Journal of the American Chemical Society, vol 137, no 37, pp 11942-11945, 2015 [121] B K Banik, I Banik, M Renteria, and S K Dasgupta, A straightforward highly efficient Paal–Knorr synthesis of pyrroles, Tetrahedron letters, vol 46, no 15, pp 2643-2645, 2005 [122] B Wang, Y Gu, C Luo, T Yang, L Yang, and J Suo, Pyrrole synthesis in ionic liquids by Paal–Knorr condensation under mild conditions, Tetrahedron letters, vol 45, no 17, pp 3417-3419, 2004 [123] G Minetto, L F Raveglia, A Sega, and M Taddei, Microwave‐Assisted Paal– Knorr Reaction–Three‐Step Regiocontrolled Synthesis of Polysubstituted Furans, Pyrroles and Thiophenes, European journal of organic chemistry, vol 2005, no 24, pp 5277-5288, 2005 [124] S K De, Ruthenium (III) chloride as a novel and efficient catalyst for the synthesis of substituted pyrroles under solvent-free conditions, Catalysis Letters, vol 124, no 3-4, pp 174-177, 2008 127 [125] V Amarnath, K Amarnath, W M Valentine, M A Eng, and D G Graham, Intermediates in the Paal-Knorr synthesis of pyrroles 4-Oxoaldehydes, Chemical research in toxicology, vol 8, no 2, pp 234-238, 1995 [126] V Amarnath, D C Anthony, K Amarnath, W M Valentine, L A Wetterau, and D G Graham, Intermediates in the Paal-Knorr synthesis of pyrroles, The Journal of Organic Chemistry, vol 56, no 24, pp 6924-6931, 1991 [127] T N Danks, Microwave assisted synthesis of pyrroles, Tetrahedron letters, vol 40, no 20, pp 3957-3960, 1999 [128] Z.-H Zhang, J.-J Li, and T.-S Li, Ultrasound-assisted synthesis of pyrroles catalyzed by zirconium chloride under solvent-free conditions, Ultrasonics sonochemistry, vol 15, no 5, pp 673-676, 2008 [129] R Sreekumar, and R Padmakumar, Simple, efficient and convenient synthesis of pyrroles and pyrazoles using zeolites, Synthetic communications, vol 28, no 9, pp 1661-1665, 1998 [130] S K Pasha, V Satyanarayana, A Sivakumar, K Chidambaram, and L J Kennedy, Catalytic applications of nano β-PbO in Paal–Knorr reaction, Chinese Chemical Letters, vol 22, no 8, pp 891-894, 2011 [131] R Yan, X Kang, X Zhou, X Li, X Liu, L Xiang, Y Li, and G Huang, I2Catalyzed Synthesis of substituted pyrroles from α-amino carbonyl compounds and aldehydes, The Journal of organic chemistry, vol 79, no 1, pp 465-470, 2013 [132] H Tsuji, K.-i Yamagata, Y Ueda, and E Nakamura, Indium-catalyzed synthesis of furans and pyrroles via cyclization of α-propargyl-β-keto esters, Synlett, vol 2011, no 07, pp 1015-1017, 2011 [133] S Maiti, S Biswas, and U Jana, Iron (III)-catalyzed four-component coupling reaction of 1,3-dicarbonyl compounds, amines, aldehydes, and nitroalkanes: a simple and direct synthesis of functionalized pyrroles, The Journal of organic chemistry, vol 75, no 5, pp 1674-1683, 2010 [134] F A Carey, and R J Sundberg, Advanced organic chemistry: part a: structure and mechanisms: Springer Science & Business Media, 2007 [135] D W Kim, C E Song, and D Y Chi, Significantly enhanced reactivities of the nucleophilic substitution reactions in ionic liquid, The Journal of organic chemistry, vol 68, no 11, pp 4281-4285, 2003 [136] V H Jadhav, J G Kim, H J Jeong, and D W Kim, Nucleophilic hydroxylation in water media promoted by a hexa-ethylene glycol-bridged dicationic ionic liquid, The Journal of organic chemistry, vol 80, no 14, pp 7275-7280, 2015 [137] V Kumar, M D Alexander, M R Bell, M A Eissenstat, F M Casiano, S M Chippari, D A Haycock, D A Luttinger, J E Kuster, and M S Miller, Morpholinoalkylindenes as antinociceptive agents: novel cannabinoid receptor agonists, Bioorganic & Medicinal Chemistry Letters, vol 5, no 4, pp 381-386, 1995 [138] Y Hosohata, R M Quock, K Hosohata, A Makriyannis, P Consroe, W R Roeske, and H I Yamamura, AM630 antagonism of cannabinoid-stimulated [35 128 [139] [140] [141] [142] [143] [144] [145] [146] [147] [148] [149] [150] [151] S] GTPγS binding in the mouse brain, European journal of pharmacology, vol 321, no 1, pp R1-R3, 1997 T E D'Ambra, K G Estep, M R Bell, M A Eissenstat, K A Josef, S J Ward, D A Haycock, E R Baizman, and F M Casiano, Conformationally restrained analogs of pravadoline: nanomolar potent, enantioselective,(aminoalkyl) indole agonists of the cannabinoid receptor, Journal of medicinal chemistry, vol 35, no 1, pp 124-135, 1992 Z.-G Le, Z.-C Chen, Y Hu, and Q.-G Zheng, Organic reactions in ionic liquids: N-alkylation of phthalimide and several nitrogen heterocycles, Synthesis, vol 2004, no 02, pp 208-212, 2004 D Yue, T Yao, and R C Larock, Synthesis of 3-iodoindoles by the Pd/Cucatalyzed coupling of N,N-dialkyl-2-iodoanilines and terminal acetylenes, followed by electrophilic cyclization, The Journal of organic chemistry, vol 71, no 1, pp 62-69, 2006 Y Wang, L Li, H Ji, W Ma, C Chen, and J Zhao, Iron(III)-mediated photocatalytic selective substitution of aryl bromine by chlorine with high chloride utilization efficiency, Chemical Communications, vol 50, no 18, pp 2344-2346, 2014 G W Gribble, The diversity of naturally occurring organobromine compounds, Chemical Society Reviews, vol 28, no 5, pp 335-346, 1999 G W Gribble, Naturally occurring organofluorines, Organofluorines, pp 121136: Springer, 2002 J Magano, and J R Dunetz, Recent large‐scale applications of transition metal‐catalyzed couplings for the synthesis of pharmaceuticals, ChemInform, vol 46, no 16, 2015 I A Cade, and A F Hill, 1,1-Bis (N-methylimidazole)-2-(trimethylsilyl)-1boracyclohexa-1, 4-diene Chloride: A Stable Intermediate or Tangent en Route to 1-(N-Methylimidazole) borabenzene?, Organometallics, vol 31, no 5, pp 21122115, 2012 T Ikawa, T E Barder, M R Biscoe, and S L Buchwald, Pd-catalyzed amidations of aryl chlorides using monodentate biaryl phosphine ligands: A kinetic, computational, and synthetic investigation, Journal of the American Chemical Society, vol 129, no 43, pp 13001-13007, 2007 R Schmidt, A Stolle, and B Ondruschka, Aromatic substitution in ball mills: formation of aryl chlorides and bromides using potassium peroxomonosulfate and NaX, Green Chemistry, vol 14, no 6, pp 1673-1679, 2012 X Shen, A M Hyde, and S L Buchwald, Palladium-catalyzed conversion of aryl and vinyl triflates to bromides and chlorides, Journal of the American Chemical Society, vol 132, no 40, pp 14076-14078, 2010 H Wu, and J Hynes Jr, Copper-catalyzed chlorination of functionalized arylboronic acids, Organic letters, vol 12, no 6, pp 1192-1195, 2010 T D Sheppard, Metal-catalysed halogen exchange reactions of aryl halides, Organic & biomolecular chemistry, vol 7, no 6, pp 1043-1052, 2009 129 [152] J Zanon, A Klapars, and S L Buchwald, Copper-catalyzed domino halide exchange-cyanation of aryl bromides, Journal of the American Chemical Society, vol 125, no 10, pp 2890-2891, 2003 [153] P Barthazy, A Togni, and A Mezzetti, Catalytic Fluorination by Halide Exchange with 16-Electron Ruthenium (II) Complexes X-ray Structure of [Tl(μF)2Ru (dppe)2]PF6, Organometallics, vol 20, no 16, pp 3472-3477, 2001 [154] A Vigalok, Metal‐mediated formation of carbon–halogen bonds, Chemistry-a European Journal, vol 14, no 17, pp 5102-5108, 2008 [155] F Mo, J M Yan, D Qiu, F Li, Y Zhang, and J Wang, Gold‐catalyzed halogenation of aromatics by n‐halosuccinimides, Angewandte Chemie, vol 122, no 11, pp 2072-2076, 2010 [156] D A Watson, M Su, G Teverovskiy, Y Zhang, J García-Fortanet, T Kinzel, and S L Buchwald, Formation of ArF from LPdAr(F): Catalytic conversion of aryl triflates to aryl fluorides, Science, vol 325, no 5948, pp 1661-1664, 2009 [157] T O Bayraktaroglu, M A Gooding, S F Khatib, H Lee, M Kourouma, and R G Landolt, Hypochlorite-induced substitution of chlorine for iodine in aromatic compounds and the role of iodyl intermediates, The Journal of Organic Chemistry, vol 58, no 5, pp 1264-1265, 1993 [158] S Imhaoulène, L Vivier, M Guisnet, G Pérot, and M Gubelmann, Exchange of halogens between aromatic compounds in the presence of Cu-HZSM-5 zeolite, Tetrahedron, vol 50, no 45, pp 12913-12922, 1994 [159] F Bonnichon, G Grabner, G Guyot, and C Richard, Photochemistry of substituted 4-halogenophenols: effect of a CN substituent, Journal of the Chemical Society, Perkin Transactions 2, no 6, pp 1203-1210, 1999 [160] R Cramer, and D R Coulson, Nickel-catalyzed displacement reactions of aryl halides, The Journal of Organic Chemistry, vol 40, no 16, pp 2267-2273, 1975 [161] R K Arvela, and N E Leadbeater, Fast and easy halide exchange in aryl halides, Synlett, vol 2003, no 08, pp 1145-1148, 2003 [162] A Klapars, and S L Buchwald, Copper-catalyzed halogen exchange in aryl halides: an aromatic Finkelstein reaction, Journal of the American Chemical Society, vol 124, no 50, pp 14844-14845, 2002 [163] R S Varma, R Dahiya, and S Kumar, Clay catalyzed synthesis of imines and enamines under solvent-free conditions using microwave irradiation, Tetrahedron letters, vol 38, no 12, pp 2039-2042, 1997 [164] B áM Chanda, One-pot synthesis of coumarins Catalysis by the solid base, calcined Mg-Al hydrotalcite, Green Chemistry, vol 1, no 3, pp 163-165, 1999 [165] D Xiao, J R Rajian, A Cady, S Li, R A Bartsch, and E L Quitevis, Nanostructural organization and anion effects on the temperature dependence of the optical Kerr effect spectra of ionic liquids, The Journal of Physical Chemistry B, vol 111, no 18, pp 4669-4677, 2007 [166] A Mirjafari, N Mobarrez, R A O’Brien, J H Davis Jr, and J Noei, Microwavepromoted one-pot conversion of alcohols to oximes using 1-methylimidazolium 130 [167] [168] [169] [170] [171] [172] [173] [174] [175] [176] [177] [178] nitrate,[HMIM][NO3], as a green promoter and medium, Comptes Rendus Chimie, vol 14, no 12, pp 1065-1070, 2011 Z Duan, Y Gu, and Y Deng, Neutral ionic liquid [BMIM] BF promoted highly selective esterification of tertiary alcohols by acetic anhydride, Journal of Molecular Catalysis A: Chemical, vol 246, no 1, pp 70-75, 2006 N T H Anh, N C Huong, N D Khoa, L V Ha, and P T S Nam, Catalyst-free synthesis of Coumarin derivatives using 1-butyl-3-methylimidazolium bromide ionic liquid as a reusable promoting medium,, Journal of Catalysis and Adsorption, vol 3, pp 69-75, 2014 S Seki, T Kobayashi, Y Kobayashi, K Takei, H Miyashiro, K Hayamizu, S Tsuzuki, T Mitsugi, and Y Umebayashi, Effects of cation and anion on physical properties of room-temperature ionic liquids, Journal of Molecular Liquids, vol 152, no 1, pp 9-13, 2010 N V Plechkova, and K R Seddon, Ionic liquids:“designer” solvents for green chemistry, Methods and Reagents for Green Chemistry, pp 105-130, 2007 N T H A L V Ha, N A Tuan, and P T S Nam, Ionic liquid-promoted Narylation between piperidine and 4-bromonitrobenzene without catalyst, Journal of Chemistry, , vol vol 51 (2AB), pp pp 96-102, 2013 N T H A L V Ha, V H L Phuong, and P T S Nam, Imidazolium-based ionic liquid as a promising green solvent for aza-Micheal reaction between primary amines and ethyl acrylate at ambient temperature, Journal of Chemistry,, vol vol 51 (4AB) pp pp 219-225, 2013 N T H A L V Ha, H D Hiep, and P T S Nam, Paal-Knorr condensation between 2,5-hexanedione and aromatic amines promoted by recyclable imidazolium-based ionic liquid, Journal of Catalysis and Adsorption, vol vol (1), no pp 94-11, 2013 C Wakai, A Oleinikova, M Ott, and H Weingärtner, How polar are ionic liquids? Determination of the static dielectric constant of an imidazolium-based ionic liquid by microwave dielectric spectroscopy, The Journal of Physical Chemistry B, vol 109, no 36, pp 17028-17030, 2005 P Kisanga, X Fei, and J Verkade, P(RNCH2CH2)3N: An efficient promoter for the synthesis of 3-substituted coumarins, Synthetic communications, vol 32, no 8, pp 1135-1144, 2002 S Zhou, J Jia, J Gao, L Han, Y Li, and W Sheng, The one-pot synthesis and fluorimetric study of 3-(2′-benzothiazolyl) coumarins, Dyes and Pigments, vol 86, no 2, pp 123-128, 2010 A H Jadhav, A Chinnappan, R H Patil, S V Kostjuk, and H Kim, Short oligo ethylene glycolic tailor-made ionic liquids as highly efficient and reusable catalyst for one-pot synthesis of 1,5-benzodiazepine derivatives under solvent free condition, Chemical Engineering Journal, vol 240, pp 228-234, 2014 M Pozarentzi, J Stephanidou-Stephanatou, and C A Tsoleridis, An efficient method for the synthesis of 1,5-benzodiazepine derivatives under microwave 131 [179] [180] [181] [182] [183] [184] [185] [186] [187] [188] [189] [190] [191] irradiation without solvent, Tetrahedron letters, vol 43, no 9, pp 1755-1758, 2002 A H Jadhav, and H Kim, Solvent free synthesis of 1,5-benzodiazepine derivatives over the heterogeneous silver salt of silicotungstic acid under ambient conditions, RSC Advances, vol 3, no 15, pp 5131-5140, 2013 C Cadena, J L Anthony, J K Shah, T I Morrow, J F Brennecke, and E J Maginn, Why is CO2 so soluble in imidazolium-based ionic liquids?, Journal of the American Chemical Society, vol 126, no 16, pp 5300-5308, 2004 E.-i Negishi, P C C Halogen, D Choueiry, K Hiroi, K K M Hii, K Oshima, M Ogasawara, T Hayashi, A J Canty, and A Suzuki, Handbook of organopalladium chemistry for organic synthesis, 2002 J S Wilkes, Properties of ionic liquid solvents for catalysis, Journal of Molecular Catalysis A: Chemical, vol 214, no 1, pp 11-17, 2004 K Dong, S Zhang, D Wang, and X Yao, Hydrogen bonds in imidazolium ionic liquids, The Journal of Physical Chemistry A, vol 110, no 31, pp 9775-9782, 2006 N Narendar, and S Velmathi, Copper-catalyzed C–N coupling reactions of aryl halides with α-amino acids under focused microwave irradiation, Tetrahedron Letters, vol 50, no 36, pp 5159-5161 , 2009 B C Ranu, and S Banerjee, Ionic liquid as catalyst and reaction medium The dramatic influence of a task-specific ionic liquid,[BMIM]OH, in michael addition of active methylene compounds to conjugated ketones, carboxylic esters, and nitriles, Organic letters, vol 7, no 14, pp 3049-3052, 2005 A R Gholap, N S Chakor, T Daniel, R J Lahoti, and K V Srinivasan, A remarkably rapid regioselective synthesis of β-enaminones using silica chloride in a heterogeneous as well as an ionic liquid in a homogeneous medium at room temperature, Journal of Molecular Catalysis A: Chemical, vol 245, no 1, pp 3746, 2006 Y.-S Choi, Y N Shim, J Lee, J H Yoon, C S Hong, M Cheong, H S Kim, H G Jang, and J S Lee, Ionic liquids as benign catalysts for the carbonylation of amines to formamides, Applied Catalysis A: General, vol 404, no 1, pp 87-92, 2011 I Fernandez, G Frenking, and E Uggerud, Rate-determining factors in nucleophilic aromatic substitution reactions, The Journal of organic chemistry, vol 75, no 9, pp 2971-2980, 2010 S Caron, and A Ghosh, Nucleophilic aromatic substitution, Practical Synthetic Organic Chemistry: Reactions, Principles, and Techniques, pp 237-253, 2011 P T S Nam, L V Ha, and C N D Quyen, Microwave-assisted synthesis of pravadoline in ionic liquids as green solvents, Journal of Chemistry, vol 49, pp 500-506, 2011 P T S Nam, L V Ha, and B V H Huynh, Paal-Knorr reaction between 2,5hexanedione and cyclohexylamine in ionic liquid as green solvent, Journal of Chemistry, vol 49, pp 597-602, 2011 132 [192] N M Correa, E N Durantini, and J J Silber, Non‐aqueous reverse micelles media for the SNAr reaction between 1‐fluoro‐2, 4‐dinitrobenzene and piperidine, Journal of physical organic chemistry, vol 19, no 12, pp 805-812, 2006 [193] J C Lee, J.-H Choi, and J S Lee, Microwave-assisted synthesis of diaryl ethers from reactions of phenols with nitroaryl fluorides under solvent-free conditions, Bulletin-Korean Chemical Society, vol 25, no 8, pp 1117-1118, 2004 [194] P Wipf, and S M Lynch, Synthesis of highly oxygenated dinaphthyl ethers via snar reactions promoted by barton's base, Organic letters, vol 5, no 7, pp 11551158, 2003 [195] M R Crampton, T A Emokpae, C Isanbor, A S Batsanov, J A Howard, and R Mondal, Effects of ortho‐and para‐ring activation on the kinetics of snar reactions of 1‐chloro‐2‐nitro‐and 1‐phenoxy‐2‐nitrobenzenes with aliphatic amines in acetonitrile, European journal of organic chemistry, vol 2006, no 5, pp 1222-1230, 2006 [196] S O de Silva, and V Snieckus, Indole N-alkylation of tryptamines via dianion and phthalimido intermediates New potential indolealkylamine haptens, Canadian Journal of Chemistry, vol 56, no 12, pp 1621-1627, 1978 [197] G Rubottom, and J Chabala, N-Alkylindoles From The Alkylation Of Sodium Indolide In Hexamethylphosphoric Triamide: 1-Benzylindole, Org Synth., vol 54, pp 60, 1974 [198] H Heaney, and S V Ley, 1-Benzylindole, Org Synth, vol 54, pp 58, 1974 [199] K Sukata, N-alkylation of pyrrole, indole, and several other nitrogen heterocycles using potassium hydroxide as a base in the presence of polyethylene glycols or their dialkyl ethers, Bulletin of the Chemical Society of Japan, vol 56, no 1, pp 280-284, 1983 [200] M A Zahran, and A M Ibrahim, Synthesis and cellular cytotoxicities of new Nsubstituted indole-3-carbaldehyde and their indolylchalcones, Journal of chemical sciences, vol 121, no 4, pp 455-462, 2009 [201] M R Bell, T E D'Ambra, V Kumar, M A Eissenstat, J L Herrmann Jr, J R Wetzel, D Rosi, R E Philion, and S J Daum, Antinociceptive (aminoalkyl) indoles, Journal of medicinal chemistry, vol 34, no 3, pp 1099-1110, 1991 [202] M J Earle, P B McCormac, and K R Seddon, The first high yield green route to a pharmaceutical in a room temperature ionic liquid, Green Chemistry, vol 2, no 6, pp 261-262, 2000 [203] P Formentı́n, H Garcı́a, and A Leyva, Assessment of the suitability of imidazolium ionic liquids as reaction medium for base-catalysed reactions: case of Knoevenagel and Claisen–Schmidt reactions, Journal of Molecular Catalysis A: Chemical, vol 214, no 1, pp 137-142, 2004 [204] N Azizi, A Khajeh-Amiri, H Ghafuri, M Bolourtchian, and M R Saidi, Ironcatalyzed inexpensive and practical synthesis of N-substituted pyrroles in water, Synlett, vol 2009, no 14, pp 2245-2248, 2009 [205] P Wasserscheid, and T Welton, Ionic Liquids in Synthesis Wiley-VCH Verlag GmbH & Co KGaA, 2002 133 [206] K A Connors, Chemical kinetics: the study of reaction rates in solution, United States of America: John Wiley & Sons, 1990 [207] P Wasserscheid, and W Keim, Ionic liquids—new “solutions” for transition metal catalysis, Angewandte Chemie International Edition, vol 39, no 21, pp 3772-3789, 2000 [208] B Mothana, and R J Boyd, A density functional theory study of the mechanism of the Paal–Knorr pyrrole synthesis, Journal of Molecular Structure: THEOCHEM, vol 811, no 1, pp 97-107, 2007 [209] V Polshettiwar, B Baruwati, and R S Varma, Magnetic nanoparticle-supported glutathione: a conceptually sustainable organocatalyst, Chemical Communications, no 14, pp 1837-1839, 2009 [210] R A V Cárdenas, B O Q Leal, A Reddy, D Bandyopadhyay, and B K Banik, Microwave-assisted polystyrene sulfonate-catalyzed synthesis of novel pyrroles, Organic and medicinal chemistry letters, vol 2, no 1, pp 1, 2012 [211] S Z Yuan, J Liu, and L Xu, A convenient synthesis of pyrroles catalyzed by acidic resin under solvent-free condition, Chinese Chemical Letters, vol 21, no 6, pp 664-668, 2010 [212] M Banik, B Ramirez, A Reddy, D Bandyopadhyay, and B K Banik, Polystyrenesulfonate-catalyzed synthesis of novel pyrroles through Paal-Knorr reaction, Organic and medicinal chemistry letters, vol 2, no 1, pp 1-4, 2012 [213] J Arnold, T Bayraktaroglu, R Brown, C Heiermann, W Magnus, A Ohman, and R Landolt, Hypochlorite-induced substitution of chlorine for bromine in aromatic compounds, The Journal of Organic Chemistry, vol 57, no 1, pp 391393, 1992 134 LIST OF PUBLICATIONS Nguyen Thi Hong Anh, Nguyen Cam Huong, Nguyen Dang Khoa, Le Vu Ha, Phan Thanh Son Nam, Catalyst-free synthesis of Coumarin derivatives using 1-butyl-3methylimidazolium bromide ionic liquid as a reusable promoting medium, Journal of Catalysis and Adsorption, Vol.3 (No1), P69-75., 2014 Nguyen Thi Hong Anh, Nguyen Cam Huong, Nguyen Dang Khoa, Le Vu Ha, Phan Thanh Son Nam, 1-hexyl-3-methylimidazolium bromide ionic liquid as an efficient and recyclable catalyst for the synthesis of 1,5-benzodiazepine derivatives, Journal of Catalysis and Adsorption, Vol.3 (No1), P56-62., 2014 L V Ha, N T H Anh, H D Hiep, and P T S Nam, "Paal-Knorr condensation between 2,5-hexanedione and aromatic amines promoted by recyclable imidazoliumbased ionic liquid," Journal of Catalysis and Adsorption, vol (1), P 94-11, 2013 Le Vu Ha, Nguyen Thi Hong Anh, Nguyen Anh Tuan, Phan Thanh Son Nam, “Ionic liquid-promoted n-arylation between piperidine and 4-bromonitrobenzene without catalyst”, Viet Nam Journal of Chemistry, Vol.51(2AB), P.96-102, 2013 Phan Thanh Son Nam, Le Khac Anh Ky, Nguyen Thi Hong Anh, Truong Thi Kim Ngan, “The ionic liquid-mediated paal-knorr reaction between benzylamine and hexane-2,5-dione”, Viet Nam Journal of Chemistry, Vol.50(4A), P.69-72, 2012 Anh T H Nguyen, Dat P Nguyen, Ngan T K Phan, Nam T S Phan, Thanh Truong, “A copper-mediated reverse aromatic Finkelstein reaction in ionic liquid”, Journal of Advanced Research, 10, P 9–13, 2018 (Impact Factor: 4.327) 135 APPENDICES 136 ... CITY HO CHI MINH CITY UNIVERSITY OF TECHNOLOGY NGUYEN THI HONG ANH USING IONIC LIQUID AS SOLVENT FOR COUPLING, AND HALOGEN EXCHANGE REACTIONS Major: Organic Chemical Technology Major code: 62527505... Synthesis of Ionic Liquids 1.1.3.1 Standard route to 1-alkyl-3-methylimidazolium-based ionic liquids The most common reactions for synthesis of almost ionic liquids were via salt metathesis reactions. .. hydrochloride and 2-methylindole formed with about 75% conversion after hours in [BMIM]PF6 ionic liquid at 30 oC Reaction Paal-Knorr reaction for synthesis of pyrroles was performed [BMIM]PF6 ionic liquid

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