[1].荣红英,黄文华*。非经典Wittig反应的最新进展。《化学与生物工程》2015,32(10), doi: 10.3969/j.issn.1672-5425.2015.10.001.[2].Wenhua Huang* and Jie Xu. In situ generation of formaldehyde and triphenylphosphine from (hydroxymethyl)triphenylphosphonium and its application in Wittig olefination. Syn. Commun.2015,45, 1777-1782.[3].Wenhua Huang,* Hong-Ying Rong, and Jie Xu. Cyclica-alkoxyphosphonium salts from (2-(diphenylphosphino)phenyl)methanol and aldehydes and their application in synthesis of vinyl ethers and ketones via Wittig olefination.J. Org. Chem.2015,80, 6628-6638.[4].Wenhua Huang,* Shuang-Hong Zhao and Ning Xu. Aryltriolborates as air- and water-stable bases for Wittig olefination.Synthesis2015, 359-366.[5].Mei-Li Xu and Wenhua Huang*. Syntheses of 9-triptycylisothiocyanate, (10-amino-9-triptycyl)carboxylic acid and their derivatives.Synth. Commun.2014,44, 3435-3440.[6].Wenhua Huang,* Shuang-Hong Zhao and Guang-Ping Dong. Wittig olefination using phosphonium tetraphenylborate in the absence of additional base.Phosphorus, Sulfur, and Silicon and the Related Elements.2014,189, 1802-1810.[7].Mei-Li Xu and Wenhua Huang*. Metal-free carbon-carbon cross-couplings between the ion pairs in sulfonium tetraphenylborates.Tetrahedron Lett.2014, 55, 4230-4232.[8].沙文彬,黄文华。N-(3-甲酰基苯基)甘氨酸衍生物的合成。化学试剂,2013,35(11),963-966.[9].沙文彬,黄文华。硼化合物催化的直接酰胺化反应研究进展。化学与生物工程,2013,30(6),11-16.[10]. Wenhua Huang* and Wen-Bin Sha. Direct amide formation fromN-arylglycine ethyl ester and carboxylic acids catalyzed by phenylboronic acid.J. Chem. Res.2013, 460-463.[11]. Wenhua Huang* and Lai-Ling Wang. One-pot synthesis of cyclopropane derivatives with a controlledcis:transstereoselectivity by Wittig olefination-sulfur ylide cyclopropanation sequence.J. Chem. Res.2013, 380-384.[12]. Wenhua Huang* and Mei-Li Xu. Synthesis of imides and benzoylureas by direct oxidation ofN-methylenes of amides and benzylureas.J. Chem. Res.2013, 77-79.[13]. Wenhua Huang,* Guangping Dong and Zumureti Mijiti. One-pot synthesis of 2,4,5-trisubstituted oxazoles from N-acyl amino acids by a combination of cyclodehydration with N,N0-diisopropylcarbodiimide and Wittig olefination.Tetrahedron2012,68, 977-981.[14]. Hong Yue, Hongmei Zhang, Meiling Wang and Wenhua Huang*. Novel route toN-acyl-N’-formyl aminal.Syn. Commun.2009, 39, 484-491.[15]. Wenhua Huang,* Meiling Wang and Hong Yue. Conversion ofN-acyl amino acids to imides via oxidative decarboxylation induced by Ag+/Cu2+/S2O82- in water.Synthesis2008, 1342-1344.[16]. Wenhua Huang,* Jingyi Li and Lihua Ou. A facile synthesis of isoquinolines,β-carbolines, and 3-deazapurines.Syn. Commun.2007, 37, 2137-2143.[17]. Wenhua Huang* and Li’e Zhang. A facile synthesis of N-formylbenzamides by oxidative decarboxylation of N-aroylglycine induced by Ag+/S2O82-.J. Chem. Res. (S) 2006, 738-739.[18]. Wenhua Huang and James P. Ferris. One-step, regioselective synthesis of up to 50-mers of RNA oligomers by montmorillonite catalysis.J. Am. Chem. Soc.2006,128, 8914-8919[19]. Michael F. Aldersley, James P. Ferris, Wenhua Huang, Prakash C. Joshi & Dmitri Zagorevski. Oligonucleotides from montmorillonite catalysis; Analysis and modeling.Origins of Life and Evolution of the Biosphere2006,36, 289-291.[20]. James P. Ferris, Prakash C. Joshi, Kong-Jiang Wang, Shin Miyakawa and Wenhua Huang. Catalysis in prebiotic chemistry: application to RNA synthesis.Advances in Space Research2004,33, 100-105.[21]. Wenhua Huang and James P. Ferris. Synthesis of 30-40 mers of RNAs from unblocked monomers. A simple approach to the RNA world.Chem. Comm.2003, 1458-1459.[22]. David Crich and Wenhua Huang. Dynamics of alkene radical cation/phosphate anion pair formation from nucleotide C4' radicals. The DNA/RNA paradox revisited.J. Am. Chem. Soc.2001,123, 9239-9245.[23]. Wen-Hua Huang, Yao-Zeng Huang and Li-Xin Dai. Tellurium-zinc exchange between organotelluronium salts and diethylzinc-reaction of the in situ generated mixed diorganozinc with carbonyl compounds.Tetrahedron Lett.1998, 39, 6953-6956.[24]. 黄文华,潘光明。改良法合成两个含硅芳香二酸酐。化学试剂1998,20, 54-55. |