Electrocarboxylation of CO_(2) with Organic Substrates:Toward Cathodic Reaction

Electrocarboxylation of carbon dioxide(CO_(2))using organic substrates has emerged as a promising method for the sustainable synthesis of value-added carboxylic acids due to its renewable energy source and mild reaction conditions.The reactivity and product selectivity of electrocarboxylation are highly dependent on the cathodic behavior,involving a sequence of electron transfers and chemical reactions.Hence,it is necessary to understand the cathodic reaction mechanisms for optimizing reaction performance and product distribution.In this work,a review of recent advancements in the electrocarboxylation of CO_(2)with organic substrates based on different cathodic reaction pathways is presented to provide a reference for the development of novel methodologies of CO_(2)electrocarboxylation.Herein,cathodic reactions are particularly classified into two categories based on the initial electron carriers(i.e.,CO_(2)radical anion and substrate radical anion).Furthermore,three cathodic pathways(ENE(N),ENED,and EDEN)of substrate radical anion-induced electrocarboxylation are discussed,which differ in their electron transfer sequence,substrate dissociation,and nucleophilic reaction,to highlight their implications on reactivity and product selectivity.

Enabling heterogeneous catalysis to achieve carbon neutrality: Directional catalytic conversion of CO_(2) into carboxylic acids

The increase in anthropogenic carbon dioxide(CO_(2))emissions has exacerbated the deterioration of the global environment,which should be controlled to achieve carbon neutrality.Central to the core goal of achieving carbon neutrality is the utilization of CO_(2) under economic and sustainable conditions.Recently,the strong need for carbon neutrality has led to a proliferation of studies on the direct conversion of CO_(2) into carboxylic acids,which can effectively alleviate CO_(2) emissions and create high-value chemicals.The purpose of this review is to present the application prospects of carboxylic acids and the basic principles of CO_(2) conversion into carboxylic acids through photo-,electric-,and thermal catalysis.Special attention is focused on the regulation strategy of the activity of abundant catalysts at the molecular level,inspiring the preparation of high-performance catalysts.In addition,theoretical calculations,advanced technologies,and numerous typical examples are introduced to elaborate on the corresponding process and influencing factors of catalytic activity.Finally,challenges and prospects are provided for the future development of this field.It is hoped that this review will contribute to a deeper understanding of the conversion of CO_(2) into carboxylic acids and inspire more innovative breakthroughs.

Carboxylation of Aromatics by CO₂under “Si/Al Based Frustrated Lewis Pairs” Catalytic System

Carboxylation of aromatics by CO2 to generate corresponding carboxylic acids is recently providing a novel approach to utilize the green gas CO2, in which the activation of CO2 is the key procedure. Among the many catalytic systems employed in the carboxylation, the concept of “Frustrated Lewis Pairs” (FLPs) was scarcely mentioned, which perform excellently in activating small molecules like CO2. The FLPs are combinations of Lewis acids and Lewis bases which failed to form adducts due to their bulky steric congestion. In this paper, we first attempted various Si/Al Based FLPs to catalyze the carboxylation of aromatics through the activation of CO2, and a good yield of 62% - 97% was obtained. The reaction mechanism was proposed, involving the activation of CO2 mainly contributed by AlCl3 in cooperation with organosilane, forming an intermediate consisting of CO2, AlCl3, and R4Si, as well as the subsequent electrophilic attack to aromatics, thus to promote the carboxylation reaction.

Electrocarboxylation of Anthrone to Anthracene-9-carboxylic Acid in the Presence of CO_2

Electrocarboxylation of anthrone in the presence of CO2 to anthrance-9-carboxylic acid directly was carried out. The electroreduction behavior of anthrone was examined by cyclic voltammetry in the absence and presence of CO2. Then the influences of the supporting electrolytes, temperature, electrode material and anthrone concentration on the carboxylation yield were investigated. Under the optimized conditions, anthrancene-9-carboxylic acid was obtained in a good yield(96.1%).

Organocatalyzed Decarboxylation of Naturally Occurring Cinnamic Acids: Potential Role in Flavoring Chemicals Production

The mechanism and the final outcome of the Knoevenagel-Doebner reaction are discussed. The condensation reaction between different hydroxy-substituted aromatic aldehydes and malonic acid is performed using piperidine as organocatalyst. The key role of the catalyst is clearly pointed out during the decarboxylation of ferulic acid, without the use of a strong decarboxylating agent, leading to a 4-vinylphenol derivative. Based on the results obtained, the studied pathway may be important in the understanding of vinylphenol production during malting and brewing of wheat and barley grains. Finally, changing the solvent of the reaction from pyridine to water in the Knoevenagel-Doebner reaction of 4-hydroxybenzaldehydes, dimerization of resulting styrene derivatives is observed. These results can be of interest also in the field of food chemistry, since cinnamic acids are frequently found in fruits and vegetables used for human consumption.

Regioselective Direct Carboxylation of 2-Naphthol with Supercritical CO₂in the Presence of K₂CO₃

A direct regioselective preparation of 2-hydroxynaphthalene-6-carboxylic acid, a useful industrial intermediate of aro-matic polyester from 2-naphthol was conducted by use of excess amount of K2CO3 (10-fold molar to 2-naphthol) under supercritical CO2 at 10 MPa and 473 K. The obtained yield under this condition was ca. 20 mol% to 2-naphthol. The further investigations may provide an alternative process to the conventional Kolbe-Schmitt reaction, because of no use of strong alkali and recoverability of K2CO3. Theoretical explanation about the regioselectivity was achieved by means of DFT calculations.

Box-Behnken experimental design for optimizing process parameters in carbonate-promoted direct thiophene carboxylation reaction with carbon dioxide

A feasible synthesis route is developed for achieving the direct carboxylation of thiophene and CO_(2) in a relatively mild solvent-free carboxylate-assisted carbonate(semi)molten state.The effects of reaction factors on the carboxylate yield are investigated in the preliminary screening experiments,and the phase behavior analysis of the reaction medium is detected through the thermal characterization analysis of insitu high temperature X-ray diffraction measurement(in-situ XRD).The application of response surface methodology(RSM)based on the Box-Behnken design(BBD)is conducted to investigate the effect of the reaction parameters,such as reaction temperatu re,carbonate proportion,CO_(2) pressure and thiophene amount,on the product yield.The regressed second-order polynomial model equation well correlates all the independent variables.The analysis of variance(ANOVA)results reveal that the quadratic effect of reaction temperature is the most effective parameter in this carboxylation reaction owing to it’s the highest contribution to the sum of square(30.18%).The optimum reaction conditions for maximum product yield are the reaction temperature of 287℃,carbonate proportion of 32.20%,CO_(2) pressure of 1.0MPa and thiophene amount of 9.35 mmol.Operating under these selected experimental conditions,a high product yield(50.98%)can be achieved.

Direct carboxylation of thiophene with CO_(2) in the solvent-free carboxylate-carbonate molten medium:Experimental and mechanistic insights

A feasible synthesis route is devised for realizing direct carboxylation of thiophene and CO_(2) in a relatively mild solvent-free carboxylate-assisted carbonate(semi)molten medium.The effects of reaction factors on product yield are investigated,and the phase behavior analysis of the reaction medium is detected through the thermal characterization techniques.Product yield varies with the alternative carboxylate co-salts,which is attributed to the difference in deprotonation capacity caused by the base effect within the system.Besides,the detailed mechanism of this carbonate-promoted carboxylation reaction is studied,including two consecutive steps of the formation of carbanion through breaking the C-H bond(s)via the carbonate and the nucleophile attacking the weak electrophile CO_(2) to form C-C bond(s).The activation energy barrier in C-H activation step is higher than the following CO_(2) insertion step whether for the formation of the mono-and/or di-carboxylate,which is in good agreement with that of kinetic isotope effect(KIE)experiments,indicating that the C-H deprotonation is slow and the forming presumed carbanion reacts rapidly with CO_(2).Both the activation energy barriers in deprotonation steps are the minimal for the cesium cluster system since there have the weak the cesium Cs-heteroatom S(thiophene)and Cs-the broken proton interactions compared to the K2CO3 system,which is likely to enhance the acidity of C-H bond,lowering the C-H activation barrier.Besides,these mechanistic insights are further assessed by investigating base and C-H substrate effects via replacing Cs2CO3 with K2CO3 and furoate(la)with thiophene monocarboxylate(1b)or benzoate(1c).

Transformation of bio-derived acids into fuel-like alkanes via ketonic decarboxylation and hydrodeoxygenation： Design of multifunctional catalyst, kinetic and mechanistic aspects

The combination of a low cost source of Biofine's levulinic acid with available way of valeric acid synthesis opens up new opportunities for valeric acid as a promising bio-derived source for synthesis of valuable compounds for transportation sector. The present review illustrates the development of different approaches to one–pot synthesis of fuel-like alkanes from lignocellulose derived carboxylic acids where particular focus is given to valeric acid consecutive decarboxylative coupling(ketonization) and ketone hydrodeoxygenation in a single reactor over one catalyst bed. The key factors that influence the catalytic performance on both ketonization and hydrodeoxygenation steps as well as their cross-influence will be clarified to provide insights for the design of more efficient catalysts for the one-pot transformation. Valeric acid is considered as a potential acid source from viewpoint of cost effectiveness and feasibility of such transformation with reasonable alkane yield. The both reaction mechanisms and kinetics will also be discussed to understand deeply how the selective C–C coupling and following C=O hydrogenation can be achieved.

Biomimetic Decarboxylation of Carboxylic Acids with PhI(OAc)_2 Catalyzed by Manganese Porphyrin [Mn(TPP)OAc]

Manganese(Ⅲ) meso-tetraphenylporphyrin acetate [Mn(TPP)OAc] served as an effective catalyst for the oxidative decarboxylation of carboxylic acids with (diacetoxyiodo)benzene [PhI(OAc)2] in CH2Cl2-H2O(95:5,volume ratio). The aryl substituted acetic acids are more reactive than the less electron rich linear carboxylic acids in the presence of catalyst Mn(TPP)OAc. In the former case,the formation of carbonyl products was complete within just a few minutes with >97% selectivities,and no further oxidation of the produced aldehydes was achieved under these catalytic conditions. This method provides a benign procedure owing to the utilization of low toxic(diacetoxyiodo) benzene,biologically relevant manganese porphyrins,and carboxylic acids.

How Effective Is the Single-point Energy Calculation in Investigating the Reaction Mechanisms?New Decarboxylation Mechanism of Pyrrole-2-carboxylic Acid by Full Optimization with CPCM Solvation Model

The decarboxylation of pyrrole-2-carboxylic acid in acid solutions was elucidated by full optimization with the CPCM solvation model at the B3LYP/6-311++G(d,p)level.Compared with the single-point energy calculation,CPCM full optimization is better to model solvent environments to gain reasonable reaction mechanisms.Theπinteractions play a significant role in the decarboxylation of pyrrole-2-carboxylic acid(R).Firstly,theαhydrogen is protonated,but all of the carbonyl hydration pathways bear relatively higher energy barriers.The carbonyl group can rove over the pyrrole ring,but it does not lead to the speciation of pyrrole and protonated carbon dioxide for the latter is an energy-rich species.The decarboxylation mechanism proposed here is that,the protonated pyrrole-2-carboxylic acid(RH^+)decarboxylates via direct C-C bond cleavage with the aid of a water molecule to accommodate the proton on the carbonyl group.

氯球嫁接L-脯氨酸绿色催化合成香豆素-3-羧酸酯

将L-脯氨酸嫁接在树脂氯球上,催化水杨醛及其衍生物和丙二酸酯直接合成香豆素-3-羧酸酯类物质,反应具有选择性强、产率高、成本低、三废少、后处理简单、催化剂可以多次重复使用等优点,符合绿色催化的特性。实验表明:反应在100℃下,醛和酯的摩尔比为1:1.2,催化剂的用量1 g,10 mL DMF中反应5h,反应的选择性≥98%,产率高达92%;催化剂循环使用6次反应的产率仍在85%以上。在此优化的反应条件下,高效合成了一系列其他香豆素-3-羧酸酯类物质,产品的结构和纯度通过了NMR、IR和熔点等手段进行了鉴定。

烷基水杨酸盐清净剂合成工艺研究进展

近年来,随着节约能源和保护环境的要求逐渐提高,发动机设计日益向小型化,大功率和高速度方向发展,因此对内燃机油的高温清净性能提出了越来越苛刻的要求,低硫低磷及低灰分型内燃机油将是未来发展的方向。烷基水杨酸盐具有优异的清净作用及酸中和性能,且具备一定的抗氧化和抗腐蚀能力,是内燃机油的主要添加剂之一,可满足内燃机油低硫低磷及低灰分的要求。对烷基水杨酸盐的传统及改进的合成工艺进行了综述。传统合成工艺严重制约了烷基水杨酸盐的应用和发展,探索新的合成工艺是烷基水杨酸盐发展的主要方向。

小麦叶片和冠层尺度气体交换模型关键参数的季节变化特征

本文从叶片和冠层尺度入手,采用手持式光合仪和涡动相关法,分析确定C3作物春小麦和冬小麦气体交换模型关键参数随季节变化的特征。结果表明:春小麦叶片尺度最大羧化速率和最大电子传递速率在生育末期快速减小,其他阶段差异不显著,但二者之比随发育期变化相对稳定,均值为2.2;春小麦生长季叶片气孔导度模型斜率在9~11间变动,均值为9.7。冬小麦冠层尺度最大羧化速率和最大电子传递速率随发育期呈抛物线变化,但二者之比相对稳定,均值为1.43;冬小麦冠层导度模型斜率在不同年份不同季节变化无明显规律,整个生育期围绕均值12波动。本研究论证了表征作物光合能力的参数随生育期变化以及气孔导度模型斜率相对稳定的特征。可为陆气相互作用过程分析以及生态系统碳—水循环模拟提供参数化依据。

亚低温对新生儿缺氧缺血性脑病患儿血清泛素羧基末端水解酶-L1、低氧诱导因子-1α表达水平及神经发育结局的影响

目的探讨亚低温对新生儿缺氧缺血性脑病(hypoxic-ischemic encephalopathy,HIE)患儿血清泛素羧基末端水解酶-L1(ubiquitin carboxy-terminal hydrolase-L1,UCH-L1)、低氧诱导因子-1a(hypoxiainducible factor-1α,HIF-1α)表达水平及预后的影响。方法选取2015年8月至2022年8月邯郸市妇幼保健院新生儿重症监护病房(neonatal intensive care unit,NICU)收治的110例中重度HIE患儿作为研究对象。根据家属是否同意患儿接受亚低温治疗,将患儿分为亚低温治疗组(n=70)和传统治疗组(n=40);亚低温治疗组患儿除常规治疗外,于出生后0~6 h实施选择性头部亚低温治疗。传统治疗组患儿给予常规治疗;治疗前和治疗后第3天,采用酶联免疫吸附实验双抗夹心法检测UCH-L1、HIF-1α表达水平。随访患儿出生后12~15个月神经发育结局。统计学方法采用独立样本t检验、配对t检验、χ^(2)检验或Fisher确切概率法。结果亚低温治疗组与传统治疗组治疗后血清UCH-L1[(1.9±0.4)与(3.1±0.3)μg/L,t=16.495,P<0.001]、HIF-1α表达水平[(1.40±0.22)与(2.75±0.19)μg/L,t=32.486,P<0.001]比较,亚低温治疗组明显低于传统治疗组;亚低温治疗组患儿治疗后血清UCH-L1表达水平低于治疗前[(1.9±0.4)与(3.3±0.5)μg/L,t'=18.293,P<0.01]。亚低温治疗组和传统治疗组在治疗3 d后,虽然两组血清中HIF-1α表达水平均出现高于治疗前[(1.40±0.22)与(1.23±0.29)μg/L,t'=3.907,P<0.001;(2.75±0.19)与(1.27±0.35)μg/L,t'=23.504,P<0.001],但是,亚低温抑制血清HIF-1α表达水平升高的效果明显优于传统治疗组。随访结果显示,亚低温治疗组患儿神经发育正常的比例高于传统治疗组[68.6%(48/70)与32.5%(13/40),χ^(2)=13.408,P<0.001];亚低温治疗组神经发育迟缓的比例低于传统治疗组[11.4%(8/70)与37.5%(15/40),χ^(2)=10.462,P<0.001]。结论亚低温治疗可以明显降低中重度HIE患儿血清UCHL1表达水平,抑制血清HIF-1a表达水平升高的作用明显优于传统治疗,这可能是低温治疗的神经保护机制之一。

羧基化改性海带渣对结晶紫的吸附性能研究

采用丁二酸酐(SA)对海带渣(LJR)进行羧基化修饰。利用红外光谱、扫描电镜、能量色散光谱对LJR和改性海带渣(CLJR)进行表征,对比改性前后LJR对结晶紫(CV)的吸附性能,并确定CLJR的最优吸附条件。结果发现:CLJR在1728 cm^(-1)处出现羧基的特征峰,孔隙结构明显增多,羧基化改性增强了LJR对CV的吸附性能。CLJR的最优吸附条件为初始质量浓度100 mg/L、吸附剂投加量0.8 g/L、初始pH 5~11;升高温度对LJR和CLJR的吸附过程有利。

甲基双酚类单体共聚-溴化-羧化法制备羧基化聚醚醚酮

针对2,5-二羟基甲苯、对苯二酚和4,4’-二氟二苯甲酮共聚反应进行研究。结果表明,随着固含量、反应温度以及碱金属碳酸盐中碳酸钾比例的增加,产物含甲基的聚醚醚酮(PEEK-CH_(3))的分子量分布先降低后增加,其最佳反应条件:固含量为25%,缩聚温度为200℃,碱金属碳酸盐与双酚单体物质的量比为1.05:1,碱金属碳酸盐中碳酸钠与碳酸钾的物质的量比为19:1,反应时间为3.5 h。PEEK-CH_(3)溴化反应中二溴取代产物(PEEK-CHBr_(2))最为重要,在液溴用量为—CH_(3)摩尔当量的20倍、反应温度为160℃、365 nm长波紫外线光照下反应2 h后,PEEK-CHBr_(2)占比达到95.8%。最后,通过次氯酸钠氧化PEEK-CHBr_(2),成功制备了数均分子量为4.6×10^(4)、特性黏度为1.5 dL/g的羧基化聚醚醚酮,其水接触角从未改性的PEEK的133.9°降至29.9°。

一个新的三维超分子配位聚合物[Ni(pyridine-2-carboxylate)2]n·2nH2O的水热合成及晶体结构

采用水热法合成了一个新的金属-有机配位聚合物[Ni(pyridine-2-carboxylate)2]n.2nH2O,对其进行元素分析、红外光谱和X射线单晶衍射测定.结构分析表明:该晶体属于三斜晶系,P-1空间群,晶胞参数a=5.1284(6)nm,b=7.6346(9)nm,c=9.2295(11)nm,α=74.902(2)°,β=84.347(2)°,γ=71.442(2)°,V=330.70(7)nm3,化学式为C12H12NiN2O6,Mr=338.95,Dc=1.702g/cm3,μ(Mo,Kα)=1.497mm-1,F(000)=174,Z=1,R=0.0333,wR=0.0384((I>2σ(I)).并且该配合物通过O—H…O和C—H…O氢键形成了三维超分子网状结构.

多阳离子位点季铵盐与AEC复配体系的应用性能研究

将含多阳离子位点双子季铵盐表面活性剂(TC-GS)与脂肪醇聚氧乙烯醚羧酸钠(AE_(9)C)以不同比例复配,并测试了不同复配比例下混合体系的浸润、去污、乳化、抗静电和活性炭分散性能。结果表明,不同复配比例下的TCGS/AE_(9)C体系都为均一透明溶液,表现出优异的复配稳定性。复配体系对帆布片的浸润能力优于单一表面活性剂,其中α_(TC-GS)为0.4时浸润性能最好。复配体系在乳化液体石蜡的过程中表现出协同增效作用。AE_(9)C溶液对炭黑污布和油脂污布都具有较好的去污能力,但与TC-GS复配后去污性能有所下降,可能由于TC-GS在污布表面的吸附阻碍了污渍的洗涤剥离。TC-GS溶液和复配体系溶液均表现出较好的抗静电性能,能够将聚酯织物表面电阻降低至≤10^(10)Ω。最后,大部分复配比例下的TC-GS/AE_(9)C体系溶液都具有良好的分散活性炭的能力;但当复配比与理论等电摩尔比一致时,复配溶液对活性炭的分散稳定性能较差。

NHC-Ag修饰的钐配合物催化CO_(2)与端炔的羧化反应

将1,3-二(4-羧基苯甲基)-苯并咪唑氯化物(H_(2)BCBI)与Sm(NO_(3))3•6H_(2)O在水热条件下进行反应,得到了二维配位聚合物[Sm(BCBI)(NO_(3))2•H_(2)O]n(Sm-BCBI),将其与乙酸银(AgOAc)作用引入氮杂环卡宾(NHC)-Ag(Ⅰ)催化位点,制备了氮杂环卡宾-银功能化的钐配合物[NHC-Ag(Ⅰ)@Sm-BCBI]。通过单晶X射线衍射仪、PXRD、TGA、XPS、电感耦合等离子发射光谱仪、SEM和EDS对Sm-BCBI和NHC-Ag(Ⅰ)@Sm-BCBI进行了表征,考察了NHC-Ag(Ⅰ)@Sm-BCBI催化CO_(2)(0.1MPa)与苯乙炔(1.0mmol)羧化反应的最佳条件,考察了底物的拓展性。结果表明,Sm-BCBI为二维层状结构;NHC-Ag(Ⅰ)@Sm-BCBI具有良好的热稳定性,且其中的银以+1价形式存在。在反应温度为50℃、以Cs2CO_(3)(1.5 mmol)为碱、N,N-二甲基甲酰胺为溶剂,NHC-Ag(Ⅰ)@Sm-BCB用量70 mg、反应时间为16h的最佳条件下,苯丙炔酸分离产率可达80%。催化剂易回收,循环使用5次后,苯丙炔酸分离产率仍能达到57%。