电化学方法固定CO2用于2-羟基-2-(4-甲氧基苯基)-丙酸甲酯的合成

在一室型电解池中, 以饱和CO₂的N,N-二甲基甲酰胺(DMF)为溶液, Mg为牺牲阳极, 不锈钢、钛、铜、镍和银为工作电极, 通过电化学方法固定CO₂, 在恒电流电解的条件下研究了对甲氧基苯乙酮的电羧化反应, 得到了重要的有机合成中间体2-羟基-2-(4-甲氧基苯基)-丙酸甲酯. 电羧化产率受支持电解质种类、电极材料、电流密度、电解电量和反应温度等影响. 经过反应条件的优化, 目标产物在恒定电流密度为5.0 mA/cm²的条件下产率达到63%. 同时, 以玻碳电极-Pt丝螺旋电极-Ag/AgI/I^-为三电极体系, 研究了对甲氧基苯乙酮的电化学行为, 根据底物在通入CO₂前后循环伏安图的变化推测了对甲氧基苯乙酮的电羧化反应机理.     

电羧化苯乙烯基苯基酮合成2,4-二苯基-4-丁酮酸

研究了常压下以CO2和苯乙烯基苯基酮为原料的电羧化反应. 在一室型电解池中, 用Mg作为辅助电极, 不锈钢、铜、镍、钛、石墨电极等作为工作电极, Ag/AgI为参比电极, 恒电位电解苯乙烯基苯基酮和CO2可得到产物2,4-二苯基-4-丁酮酸. 为提高电解产率, 优化了电解条件, 对影响该反应的溶剂、支持盐、阴极材料、电解电位、底物浓度和温度等因素作了进一步讨论. 实验结果表明, 不同的电解条件下, 苯乙烯基苯基酮的还原性能存在较大差异. 通过变化规律的研究, 找到了各个影响因素的最佳条件为: 反应温度为0 ℃, MeCN作为溶剂, 0.1 mol•L－1 四乙基四氟硼酸铵为支持盐, 不锈钢电极为工作电极, Mg棒为辅助电极, 电解电位是－1.75 V. 在此条件下恒电位电解, 2,4-二苯基-4-丁酮酸的产率可达88%. 在乙腈中还研究了苯乙烯基苯基酮的电化学行为, 推测其电羧化反应经历一个电子传递反应-化学反应-电子传递反应-化学反应(ECEC)过程.     

间接电氧化2-丁酮制备α-羟基缩酮的研究

在板框式循环电解槽中,以KOH为电解质,KI为催化剂,石墨电极分别为阳极和阴极,研究电化学间接氧化2-丁酮合成乙偶姻中间体α-羟基缩酮,讨论电流密度、极板间电解液流速、电解液中2-丁酮浓度、电解温度以及通电量等电解条件对中间体收率和电流效率的影响,经优选工艺条件为：电流密度40 mA·cm^-2,流速6.4 cm·s^-1,2-丁酮浓度1.75 mol·L^-1,电解温度30℃,通电量为1.5 F·moL^-1时,中间体收率可达78.9%,电流效率40.1%. 循环伏安测试结果表明,电解时碘离子在阳极氧化生成碘单质,甲醇在阴极还原生成甲氧基负离子,原料2-丁酮与电解产物反应,并最终生成乙偶姻中间体.     

芍药酮的溴化反应

芍药酮(Paeonol,2 羟基 4 氧基苯乙酮)是中药材牡丹皮中所含的主要活性成分,具有抑菌抗炎、解热镇痛,降压利尿,抗凝血,抑制肿瘤,抗癌,增强免疫功能等作用[1 3]。芍药酮与溴化剂反应,因溶剂和溴化剂的不同,而得到的产物不同[4,5]。无水乙醚和无水三氯化铝下,得到5 溴 4 甲氧基 2 羟基苯乙酮,产率为44 5%;在溴化铜和无水甲醇(或者氯仿与乙酸乙酯的混合液)下,得到2 羟基 4 甲氧基 ω 溴代苯乙酮,产率为63 3%(或者48 7%);在溴化铜、无水乙醇、氯仿和乙酸乙酯下,得到2 羟基 4 甲氧基 5 溴 ω 溴代苯乙酮,产率为47 5%。其合成路线如下:1.在Br…     

2-(1H-唑基)-1-(2,3,4-三甲氧基)苯乙酮衍生物的合成与结构表征

首先以2－溴－1－（2，3，4－三甲氧基）苯乙酮，四丁基铵－1H－1，2，4－三唑或咪唑为原料，分别合成了2－（1H－1，2，4－三唑－1－基）－1－（2，3，4－三甲氧基）苯乙酮（Ia)和2－（1H－咪唑0－1－基）－1－（2，3，4－三甲氧基）苯乙酮（Ib)与盐酸羟胺反应生成2－（1H－1，2，4－三唑－1－基）－1－（2，3，4－三甲氧基）苯乙酮肟和1－（1H－咪唑－1－基）－1－（2，3，4三甲氧基）苯乙酮肟，产率为63％－72％，并经元素分析，IR和1H NMR进行了表征。     

超声法合成3,4-二甲氧基-4'-羟基查尔酮

以3,4-二甲氧基-苯甲醛和对羟基苯乙酮为原料,无水乙醇为溶剂,HCl气体为催化剂,在超声作用下,经Claisen-Schmidt缩合反应合成了3,4-二甲氧基-4′-羟基查尔酮。 产物结构经IR和1H NMR进行了表征,在2种原料摩尔比1∶1投料比条件下,优化的合成条件为超声输出功率240 W,反应温度30 ℃,反应时间20 min,产率达到92.1%,比传统方法反应时间短、操作简便、产率高。     

E-、Z-2-(1-咪唑基)-O-（α-甲基对卤苄基）-2′，4′-二氯苯乙 酮肟硝酸盐的合成与结构表征

首先以2,4-二氯氯代苯乙酮、咪唑、羟胺和对卤苯乙酮为原料,分别合成E-、Z-2-（1-咪唑基）-2′,4′-二氯苯乙酮肟(ⅠE、ⅠZ)和对卤-α-氯乙苯（ⅡA和ⅡB）,ⅠE和ⅠZ分别与ⅡA和ⅡB反应,生成E-、Z-2-（1-咪唑基）-O-（α-甲基对卤苄基）-2′,4′-二氯苯乙酮肟硝酸盐四个新化合物,产率为52.0%～60.0%,并经元素分析、IR和1HNMR进行了表征。     

以Zn-PTFE复合电极电合成频那醇

研究以自制的Zn PTFE复合电极为阴极电合成频那醇 (2 ,3 二甲基 2 ,3 丁二醇 )。探讨了复合电极中PTFE含量、阴极电流密度、电解液温度、电解电量对频那醇产率的影响。实验结果表明 ,以Zn PTFE(PTFE 6 2 5 (wt) % )复合电极为阴极 ,当阴极电流密度为 2 5A·dm-2 、电解液温度为 1 5℃、电解至理论电量的 1 4 0 %时 ,电合成频那醇的产率可达 5 3 6% ,产品的红外谱图与标准谱图相符。     

并发合成香草乙酮和异香草乙酮

愈创木酚与溴代正丙烷经丙基化反应得1-正丙氧基-2-甲氧基苯(1);1与醋酐经傅-克乙酰基化反应得3-甲氧基-4-正丙氧基苯乙酮(2)和3-丙氧基-4-甲氧基苯乙酮(3)的混合物;以无水三氯化铝对2和3进行选择性脱丙基反应合成了香草乙酮和异香草乙酮,其结构经1H NMR,13C NMR和HR-ESI-MS确证。     

(±)-Malaysianone A和(±)-Tanariflavanones B的全合成

以取代苯乙酮和5-醛基-8-甲氧甲氧基-2-甲基-2-(4'-甲基-3'-戊烯基)-二氢-1-苯并吡喃为原料,经羟醛缩合反应制得两个中间体——7,2',4'-三甲氧甲氧基-6'-羟基-2-甲基-2-(4'-甲基-3'-戊烯基)-二氢-1-苯并吡喃查尔酮(3a)和7,2',4'-三甲氧甲氧基-5'-异戊烯基-6'-羟基-2-甲基-2-(4'-甲基-3'-戊烯基)-二氢-1-苯并吡喃查尔酮(3b);3a经环合和脱保护基反应合成了(±)-Malaysianone A(4a),产率12.9%;3b经脱保护基和环合反应合成了(±)-Tanariflavanones B(4b),产率5.2%。4a和4b的结构经1H NMR,13C NMR和HR-ESI-MS确证。     

Synthesis of Halogenated α,β‐Unsaturated γ‐Butyrolactone Derivatives by Triphenylphosphine‐Catalyzed Cyclization of α‐Halogeno Ketones with Dialkyl Acetylenedicarboxylates (=Dialkyl But‐2‐ynedioates)

A Ph₃P‐catalyzed cyclization of α‐halogeno ketones 2 with dialkyl acetylenedicarboxylates (=dialkyl but‐2‐ynedioates) 3 produced halogenated α,β‐unsaturated γ‐butyrolactone derivatives 4 in good yields (Scheme 1, Table). The presence of electron‐withdrawing groups such as halogen atoms at the α‐position of the ketones was necessary in this reaction. Cyclization of α‐chloro ketones resulted in higher yields than that of the corresponding α‐bromo ketones. Dihalogeno ketones similarly afforded the expected γ‐butyrolactone derivatives in high yields.     

Green Biginelli‐type Reaction: Solvent‐free Synthesis of 5‐unsubstituted 3,4‐dihydropyrimdin‐2(1H)‐ones

The Biginelli‐type compounds, 5‐unsubstituted 3,4‐dihydropyrimdin‐2(1H)‐ones were synthesized by a one‐pot three‐component condensation of aromatic aldehydes, aromatic ketones and urea in the presence of SnCl₄ · 5H₂O under solvent‐free conditions. The advantages of this method are short reaction time (4–10 min), excellent yields (74–97%), inexpensive catalyst and solvent‐free conditions. A plausible mechanism was proposed.     

Benzylamine as Hydrogen Transfer Agent: Cobalt‐Catalyzed Chemoselective C=C Bond Reduction of β‐Trifluoromethylated α,β‐Unsaturated Ketones via 1,5‐Hydrogen Transfer

An efficient cobalt‐catalyzed chemoselective reduction of β‐CF₃‐α,β‐unsaturated ketones using benzylamine as hydrogen transfer agent involving intramolecular 1,5‐hydrogen transfer is reported. The reaction proceeded smoothly with a relatively wide range of substrates including those bearing aromatic heterocycles such as a furyl ring system in high yields (74–92 %). This provides an efficient method for the synthesis of β‐CF₃ saturated ketones in one‐pot. This methodology was also applied to the selective C=C reduction of other enone substrates bearing no β‐CF₃‐substituent, of which β‐substituted or β,β‐disubstituted enones are tolerated, giving the desired products in good yields (72–75 %). Mechanistic studies indicate that the reaction involves 1,5‐hydrogen transfer.     

CuBr2‐Promoted Multicomponent Aerobic Reaction for the Synthesis of 1,2,3‐Triaroylindolizines

An efficient synthesis of 1,2,3‐triaroylindolizines has been developed via CuBr₂‐promoted reaction of three molecules of aromatic methyl ketones and one molecule of pyridine derivative. A wide range of methyl aryl ketones and methyl heteroaryl ketones took part in the reaction and generate 1,2,3‐triaroylindolizines in good yields. This protocol also features such advantages as mild reaction conditions and high atom economy and step economy.     

端位炔酮与有机锌试剂的自缩合反应

端位炔酮与有机锌试剂CF3CO2ZnEt作用发生自缩合反应,得到较高产率的β取代的Morita-Bayllis-Hillman产物,提供了三取代烯烃化合物的合成方法;而与有机锌试剂CF3CO2ZnCH2I作用时,烷基炔酮不发生反应,只有活性较高的芳基炔酮才能进行反应,得到中等产率的2,5-二氢呋喃衍生物。     

Chemoselectivity in the Reaction of 2‐Diazo‐3‐oxo‐3‐phenylpropanal with Aldehydes and Ketones

The chemoselectivity in the reaction of 2‐diazo‐3‐oxo‐3‐phenylpropanal ( 1 ) with aldehydes and ketones in the presence of Et₃N was investigated. The results indicate that 1 reacts with aromatic aldehydes with weak electron‐donating substituents and cyclic ketones under formation of 6‐phenyl‐4H‐1,3‐dioxin‐4‐one derivatives. However, it reacts with aromatic aldehydes with electron‐withdrawing substituents to yield 1,3‐diaryl‐3‐hydroxypropan‐1‐ones, accompanied by chalcone derivatives in some cases. It did not react with linear ketones, aliphatic aldehydes, and aromatic aldehydes with strong electron‐donating substituents. A mechanism for the formation of 1,3‐diaryl‐3‐hydroxypropan‐1‐ones and chalcone derivatives is proposed. We also tried to react 1 with other unsaturated compounds, including various olefins and nitriles, and cumulated unsaturated compounds, such as N,N′‐dialkylcarbodiimines, phenyl isocyanate, isothiocyanate, and CS₂. Only with N,N′‐dialkylcarbodiimines, the expected cycloaddition took place.     

An Efficient One-pot Synthesis of β-Amino/β-Acetamido Carbonyl Compounds via ZrCl4-catalyzed Mannich-type Reaction

Zirconium(IV) chloride catalyzed efficient one-pot synthesis of β-amino/β-acetamido carbonyl compounds at room temperature is described. In the presence of ZrCl4, the three-component Mannich-type reaction via a variety of in situ generated aldimines, with various ketones, aromatic aldehydes and aromatic amines in ethanol, led to the formation of β-amino carbonyl compounds and the four-component Mannich-type reaction of aromatic aldehydes with various ketones, acetonitrile and acetyl chloride resulted in the corresponding β-acetamido carbonyl compounds in high to excellent yields. This methodology has also been applied towards the synthesis of dimeric β-amino/β-acetamido carbonyl compounds.     

Rhodium‐Catalyzed 1,4‐Addition of Lithium 2‐Furyltriolborates to Unsaturated Ketones and Esters for Enantioselective Synthesis of γ‐Oxo‐Carboxylic Acids By Oxidation of the Furyl Ring with Ozone

Rhodium‐catalyzed 1,4‐addition of lithium 5‐methyl‐2‐furyltriolborate ([ArB(OCH₂)₃CCH₃]Li, Ar=5‐methyl‐2‐furyl) to unsaturated ketones to give β‐furyl ketones was followed by ozonolysis of the furyl ring for enantioselective synthesis of γ‐oxo‐carboxylic acids. [Rh(nbd)₂]BF₄ (nbd=2,5‐norbornadiene) chelated with 2,2′‐bis(diphenylphosphino)‐1,1′‐binaphthyl (binap) or 2,3‐bis(diphenylphosphino)butane (chiraphos) gave high yields and high selectivities in a range of 91–99 % ee at 30 °C in a basic dioxane/water solution. The corresponding reaction of unsaturated esters, such as methyl crotonate, had strong resistance under analogous conditions, but the 1,4‐adduct was obtained in 70 % yield and with 94 % ee when more electron‐deficient phenyl crotonate was used as the substrate.     

Rhodium‐Catalyzed Annelation of Benzoic Acids with α,β‐Unsaturated Ketones with Cleavage of C−H,CO−OH,and C−C Bonds

In the presence of a [Cp*RhCl₂]₂ catalyst, the Lewis acid In(OTf)₃, and the mild base Na₂CO₃, aromatic carboxylates and α,β‐unsaturated ketones undergo a unique hydroarylation/Claisen/retro‐Claisen process to give the corresponding indanones. In this carboxylate‐directed ortho‐C?H annelation, the C?COR bond of the ketone and the CO?OH group of the aromatic carboxylate are cleaved, and the hydroxy group is transferred from the aromatic to the aliphatic acyl residue. This reactivity is synthetically useful, particularly when starting from cyclic ketones, which are converted into indanones bearing aliphatic carboxylate side chains, thus greatly increasing the molecular complexity of aromatic carboxylates in a single step.     

Electrocarboxylation of Carbon Dioxide with Polycyclic Aromatic Hydrocarbons Using Ni as the Cathode

Using Ni cathode and Al sacrificial anode, the electrocarboxylation of polycyclic aromatic hydrocarbons (naphthalene, 5‐methylnaphthalene, anthracene, phenanthrene and 1H‐indene) with carbon dioxide (4 MPa) could be successfully performed in an undivided cell containing n‐Bu₄NBr‐DMF supporting electrolyte with a constant current at room temperature, affording the corresponding trans‐dicarboxylic acids in good to excellent yields (62% –90%). Among the examined cathode materials (Ni, Pt, Ag, Cu and Zn), Ni and Pt cathodes exhibited a good catalytic activity for the electrocarboxylations. In addition, the experimental results indicated that electrolytic conditions (conducting salts, electricity, CO₂ pressure and temperature) could also affect the result of the electrocarboxylation. According to the results of the electrocarboxylations and CV (cyclic voltammetry), a possible electrochemical reaction mechanism was also proposed.