柱芳烃综述1

柱芳烃共价有机框架1.引言1.1 概述概述：柱芳烃是一类特殊的共价有机框架化合物，由具有共轭系统的芳香碳环和连接这些环的碳链构成。

柱芳烃具有高度的结构稳定性和多功能性，具有广泛的应用前景。

引言部分将重点介绍柱芳烃的定义和特性，以及柱芳烃合成方法等。

在了解柱芳烃的特性和合成方法后，我们将进一步探讨柱芳烃的应用前景和总结。

（这部分介绍整个文章的结构，以及将要探讨的主题。

也可以简要介绍柱芳烃在科学研究和工业应用中的重要性和价值。

接下来，我们将详细介绍柱芳烃的定义和特性。

）1.2 文章结构文章结构部分的内容可以包括以下几个方面的内容：文章结构部分应该对整篇文章的框架进行说明，给读者一个整体的概览。

可以简要介绍一下本文的章节设置和各个章节的主要内容。

在本文中，文章分为引言、正文和结论三个部分。

其中，引言部分主要包含概述、文章结构和目的三个小节。

概述部分将对柱芳烃的共价有机框架进行简要介绍，以引起读者的兴趣。

文章结构部分则是本节的内容，将对整篇文章的章节设置进行说明，为读者提供一个整体的框架。

目的部分将详细说明本文的写作目的和意义。

正文部分是本文的核心部分，将包括柱芳烃的定义和特性、柱芳烃的合成方法等内容。

柱芳烃的定义和特性部分将对柱芳烃的概念和特点进行详细介绍，包括其结构、性质和应用等方面。

柱芳烃的合成方法部分将介绍柱芳烃的合成过程和常用的合成方法，包括有机合成和无机合成等方法。

结论部分是对整篇文章的总结和展望，包括柱芳烃的应用前景和本文的主要结论。

柱芳烃的应用前景部分将探讨柱芳烃在材料科学、化学工业和环境保护等领域的应用前景，展示其重要性和潜在价值。

总结部分将对本文的主要内容进行概括，重申研究的意义和价值，并指出可能的研究方向和未来的发展趋势。

综上所述，本文以柱芳烃的共价有机框架为主题，通过引言、正文和结论三个部分，全面介绍了柱芳烃的定义和特性以及合成方法，并探讨了柱芳烃的应用前景。

通过本文的阅读，读者可以对柱芳烃的共价有机框架有一个全面的了解，为相关研究和应用提供参考。

柱芳烃固有手性研究进展【摘要】柱芳烃固有手性是一种重要的研究领域，具有广泛的应用价值。

本文首先介绍了柱芳烃固有手性研究的背景和重要性，然后详细讨论了其定义、特点、研究方法、应用领域以及面临的挑战。

最新的研究进展包括新的合成方法、手性识别技术等。

未来，柱芳烃固有手性研究将在材料科学、药物研发等领域发挥更大作用。

柱芳烃固有手性研究具有重要的发展前景，应该受到更多关注和支持。

【关键词】柱芳烃, 固有手性, 研究进展, 特点, 方法, 应用领域, 挑战, 最新进展, 展望, 总结1. 引言1.1 柱芳烃固有手性研究进展的重要性柱芳烃固有手性研究是当今有机化学领域的重要研究方向之一。

固有手性是指分子本身具有不对称结构或性质，而非需要外界手性引发的手性化合物。

柱芳烃是一类具有环状结构的芳香烃，其固有手性研究具有独特的意义和价值。

柱芳烃固有手性研究进展的重要性体现在多个方面。

柱芳烃作为重要的有机分子之一，其固有手性特性对于理解有机分子结构与性质之间的关系具有重要意义。

柱芳烃固有手性研究不仅有助于拓展手性化学领域的研究范畴，还可以为新型手性材料的设计与合成提供重要指导。

柱芳烃固有手性研究也在不对称合成、超分子化学等领域具有广泛的应用前景。

柱芳烃固有手性研究的重要性不仅在于对有机分子结构与性质的理解，更在于其对于手性化学领域的推动作用和在材料科学等领域的广泛应用前景。

随着研究的不断深入，柱芳烃固有手性领域将会迎来更多的突破与发展，为有机化学领域的进步贡献力量。

1.2 柱芳烃固有手性研究的背景柱芳烃是一类具有多环芳香环结构的化合物，其具有较高的稳定性和特殊的结构性质。

由于柱芳烃固有手性的存在，使得这类化合物在手性化学领域具有重要意义。

柱芳烃固有手性研究的背景可以追溯到20世纪初，当时人们对化学手性的研究逐渐兴起。

随着研究方法的不断进步和手性化学领域的快速发展，柱芳烃固有手性研究也逐渐受到关注。

在过去的几十年里，科学家们通过不断探索和创新，逐渐揭示了柱芳烃固有手性的奥秘。

柱芳烃结构
柱芳烃是一种由苯环组成的多环芳烃，具有特殊的结构和性质。

它们的分子结构中，苯环通过共用十二个碳原子相互连接形成平面结构，呈现出六边形的形态。

在柱芳烃分子中，苯环之间的连接方式不同，可以形成不同的结构类型，例如线型、V字型、U字型、S字型等。

这些不同的结构类型会影响柱芳烃的物理化学性质。

柱芳烃的分子结构具有高度对称性，使其在光电子领域中有广泛的应用。

柱芳烃可以作为有机半导体材料，用于制造有机场效应晶体管（OFET）等器件，具有优异的电荷传输性能。

同时，柱芳烃的分子结构也使其成为一种良好的光学材料，可以用于制备光电转换器件和光学元件等。

近年来，柱芳烃的研究受到了广泛关注。

通过对柱芳烃的合成、性质和应用的研究，可以为有机光电、光电化学等领域的发展提供重要的支持和推动。

- 1 -。

Pillararenes,A New Class of Macrocycles forSupramolecular ChemistryMIN XUE,†YONG YANG,‡XIAODONG CHI,†ZIBIN ZHANG,†AND FEIHE HUANG*,††Department of Chemistry,Zhejiang University,Hangzhou310027,People's Republic of China,and‡Department of Chemistry,Zhejiang Sci-Tech University,Hangzhou310018,People's Republic of ChinaRECEIVED ON DECEMBER31,2011B ecause of the importance of novel macrocycles in supramolecular science,interest in the preparation of these substances hasgrown considerably.However,the discovery of a new class of macrocycles presents challenges because of the need for routes to further functionalization of these molecules and good hostÀguest complexation.Furthermore,useful macrocylic hosts must be easily synthesized in large quantities.With these issues in mind,the recently discovered pillararenes attracted our attention.These macrocycles contain hydroquinone units linked by methylene bridges at para positions.Although the composition of pillararenes is similar to that of calixarenes,they have different structural characteristics.One conformationally stable member of this family is pillar[5]arene,which consists of five hydroquinone units.The symmetrical pillar architecture and electron-donating cavities of these macrocycles are particularly intriguing and afford them with some special and interesting physical,chemical,and hostÀguest properties.Due to these features and their easy accessibility,pillararenes,especially pillar[5]arenes,have been actively studied and rapidly developed within the last4years.In this Account,we provide a comprehensive overview of pillararene chemistry,summarizing our results along with related studies from other researchers.We describe strategies for the synthesis,isomerization,and functionalization of pillararenes.We also discuss their macrocyclic cavity sizes,their hostÀguest properties,and their self-assembly into supramolecular polymers.The hydroxyl groups of the pillararenes can be modified at all positions or selectively on one or two positions.Through a variety of functionalizations,researchers have developed many pillararene derivatives that exhibit very interesting hostÀguest properties both in organic solvents and in aqueous media.Guest molecules include electron acceptors such as viologen derivatives and (bis)imidazolium cations and alkyl chain derivatives such as n-hexane,alkanediamines,n-octyltrimethyl ammonium,and neutral bis(imidazole)derivatives.These hostÀguest studies have led to the fabrication of(pseudo)rotaxanes or poly(pseudo)rotaxanes, supramolecular dimers or polymers,artificial transmembrane proton channels,fluorescent sensors,and other functional materials.IntroductionIt is of continuing interest to design and synthesize novel macrocyclic host molecules because of their important roles in supramolecular chemistry.The successful examples include crown ethers,1À3cyclodextrins,4cucurbiturils,5 calixarenes,6À8and their structurally similar scaffolds.9À11 Currently a new class of[1n]paracyclophanes12,13is grow-ing with similar composition but different structural features compared with calixarenes.This new class of macrocyclic molecules are made up of hydroquinone units linked by methylene bridges at para positions.Their descriptive name “pillararene”was coined by Tomoki Ogoshi in2008.14Pillar[n]arenes(n=5,6,7)have some advantages compared with traditional hosts.First,they arehighly/accounts Vol.XXX,No.XX’XXXX’000–000’ACCOUNTS OF CHEMICAL RESEARCH’A 10.1021/ar2003418&XXXX American Chemical SocietyB ’ACCOUNTS OF CHEMICAL RESEARCH’000–000’XXXX’Vol.XXX,No.XXPillararenes Xue et al.symmetrical and rigid compared with crown ethers and calixarenes,and this affords their selective binding to guests.Second,they are easier to functionalize with different sub-stituents on all of the benzene rings or selectively on one or two positions than cucurbiturils,which enables tuning of their host Àguest binding properties.Third,they are easily soluble in organic solvents,which makes them good and necessary supplements to water-soluble cucurbiturils and cyclodextrins with similar cavity sizes.These features and their rigid electron-rich cavity make them good candidates as host molecules for various electron-deficient guests or other neutral molecules such as viologen derivatives,(bis)-imidazolium cations,n -hexane,alkanediamines,n -octyl-trimethyl ammonium,and neutral bis(imidazole)deriva-tives.Pillararenes with good host Àguest properties can further self-assemble and be applied in the fabrication of (pseudo)rotaxanes or poly(pseudo)rotaxanes,supramole-cular dimers or polymers,artificial transmembrane proton channels,fluorescent sensors,or other functional materials.Therefore,soon after their invention,this new type of host has attracted great attention and been reviewed recently.15Now mainly based on our own work on pillararenes,as well as the work from other groups,we provide an Account of the growth of pillararene-based chemistry,which will highlight recent advances in the synthetic strategies,conformational characteristics,host Àguest binding properties,and self-assembly of pillararenes.SynthesisFor the synthesis of pillararenes,three strategies have thus far been employed (Scheme 1).The first is the Lewis acid catalyzed condensation of 1,4-dialkoxybenzene and paraformaldehyde.The second is the condensation of 1,4-dialkoxy-2,5-bis(alkoxymethyl)benzene catalyzed by p -toluenesulfonic acid.The third is cyclooligomerization of 2,5-dialkoxybenzyl alcohols or 2,5-dialkoxybenzyl bro-mides with an appropriate Lewis acid as the catalyst.With these methodologies,pillar[5]arenes,pillar[6]arenes and pillar[7]arenes can be obtained.In the word “pillar[n ]arene ”,the letter “n ”means the number of the hydroquinone units.For example,pillar[5]arene means a cyclopentamer with five hydroquinone units.SCHEME 1.Three SyntheticStrategies for PillararenesSCHEME 2.Synthesis of DMpillar[5]arene (2)and Pillar[5]arene (1)Pillararenes Xue et al.The synthesis of pillar[5]arene,1,was reported by Ogoshi et al.in2008.14By condensation of1,4-dimethoxybenzene with paraformaldehyde and an appropriate Lewis acid as a catalyst,the symmetrical1,4-dimethoxypillar[5]arene (DMpillar[5]arene),2,was selectively obtained(Scheme2). Various Lewis acids were used for this reaction,and with BF33O(C2H5)2,the cyclic pentamer was selectively obtained in22%yield.Then pillar[5]arene,1,was obtained by depro-tection of the methoxy groups of DMpillar[5]arene with a total yield of7%.Subsequently,to reveal the conformational characteristics of pillar[5]arene,the same research group synthesized a series of pillar[5]arene derivatives3À9with different alkyl groups and found that long alkyl substituents tended to suppress the cyclization reaction(Scheme3).16,17 Recently,our group invested effort in synthesis of copillar[5]arenes containing different repeating units.By using the above reaction conditions,three copillar[5]arenes 10À12were successfully prepared by co-oligomerization of different monomers(Scheme4).18From a mixture of4equiv of1,4-dimethoxybenzene(DMB)per equiv of1,4-dibutoxy-benzene(DBB),copillar[5]arene10was obtained in16%yield.By changing the ratio or the composition of the two comonomers,other copillar[5]arenes11and12were isolated.By co-oligomerization of4equiv of DMB and1equiv of 1-methoxy-4-(octyloxy)benzene,copillar[5]arene13was obtained in9%yield(Scheme5).19This macrocycle was designed as a monomer for the fabrication of supramole-cular ter,for the investigation of self-assembly behavior of pillararenes,copillar[5]arenes14and15were also designed and synthesized.20During this time period,a similar synthetic approach was conceived to prepare copillar[5]arene16,which was substituted with an azide group and functionalized through copper-catalyzed azideÀalkyne cycloaddition(CuAAC;Scheme6).21À23More recently,more copillar[5]arenes were synthesized in high yields by Cao et al.via strategy1in Scheme1using FeCl3as the catalyst.24Recently Ogoshi et al.improved the preparation of DMpillar-[5]arene2by using excess paraformaldehyde(3equiv of paraformaldehyde per equiv of1,4-dimethoxybenzene).As a result,they successfully obtained DMpillar[5]arene,2,in aSCHEME3.Synthesis of Alkyl-Substituted Pillar[5]arenesSCHEME4.Preparation of Copillar[5]arenes by Oligomerization of Different HydroquinoneDiethersVol.XXX,No.XX’XXXX’000–000’ACCOUNTS OF CHEMICAL RESEARCH’CD ’ACCOUNTS OF CHEMICAL RESEARCH’000–000’XXXX’Vol.XXX,No.XXPillararenes Xue et al.short time (3min)and in high yield (71%)and pillar[5]arene,1,almost in quantitative yield.25Via this improved prepara-tion method,pillar[5]arenes carrying chiral substituents at both rims were synthesized to investigate their molecular chirality.26On the other hand,Cao et al.changed the synthetic methodology and found a surprising reaction involving 1,4-diethoxy-2,5-bis(benzyloxymethyl)benzene with cataly-tic amounts of p -toluenesulfonic acid.27,28The yields of pillar[5]arenes were improved to 75%À95%.Furthermore,pillar[6]arenes 21and 22were prepared in 8%À11%(Scheme 7).Most recently,another facile and efficient preparation of pillar[n ]arenes (n =5or 6)was achieved in our group via cyclooligomerization of 2,5-dialkoxybenzyl alcohols or 2,5-dialkoxybenzyl bromides with an appropriate Lewis acid as the catalyst at room temperature (Scheme 8).29The mechanism for this cyclooligomerization is presumed to be a Friedel ÀCrafts alkylation.30Using this method,pillar-[n ]arenes (n =5,6)having different alkoxy substituents were prepared successfully.FunctionalizationFunctionalized pillararenes are necessary for molecular re-cognition and self-assembly.Pillararenes containing func-tional groups,such as alkyl-substituted pillar[5]arenes 16,17SCHEME 6.Synthesis of Copillar[5]arenes 16À20SCHEME 5.Synthesis of Copillar[5]arene 13and Chemical Structures of Copillar[5]arenes 14and15Vol.XXX,No.XX’XXXX’000–000’ACCOUNTS OF CHEMICAL RESEARCH ’EPillararenes Xue et al.and copillar[5]arenes,18À24were synthesized directly from reactants with various substituents.In fact,the other method for the construction of functionalized pillararenes is based on chemical modification of the parent macrocyclic rings.31À38Take copillar[5]arene 16,for example (Scheme 6),the bromo group is reactive for chemical manipulations and was sub-stituted with an azide group to obtain compound 17and then functionalized through CuAAC to get copillar[5]arenes 18À20.For parent macrocyclic pillar[n ]arenes,reactive and trans-formable hydroxyl groups,which provide a unique platform for further chemical modification and functionalization,ex-ist.Ogoshi et al.synthesized a new fluorescent pillar[5]arene 26modified with phenylethynyl groups (Scheme 9),which showed temperature-and solvent-responsive blue-green emission.31By introduction of carboxylate anions at both rims,pillar-arenes can be made soluble in aqueous media.32By hydro-lysis of ethoxycarbonyl-substituted pillar[5]arene 27under basic conditions and neutralization to the ammounium salt,water-soluble pillar[5]arene 29was obtained (Scheme 10);its interesting host Àguest properties in aqueous media will be described in the following section.Other water-soluble pillar[5]arenes were investi-gated by the Hou group 33and our group.34An amine-substituted pillar[5]arene 33and a trimethylammonium-substituted pillar[5]arene 34have been synthesized through modification of pillar[5]arene 31,which was afforded by derivation from ethoxycarbonyl-substituted pillar[5]arene 27through several steps,or simply by con-densation of 1,4-dialkoxybenzene and paraformalde-hyde (Scheme 11).SCHEME 7.Synthesis ofPillar[5]arenes andPillar[6]arenes from 1,4-Diethoxy-2,5-bis(alkoxymethyl)benzeneSCHEME 8.Synthesis of Pillar[n ]arenes from the Condensation of 2,5-Dialkoxybenzyl AlcoholsSCHEME 9.Synthesis of DPhEpillar[5]arene,26F ’ACCOUNTS OF CHEMICAL RESEARCH’000–000’XXXX’Vol.XXX,No.XXPillararenes Xue et al.Functionalization of pillar[5]arene using “click ”chemistry provides an extremely simple method to prepare various functional group-modified pillar[5]arenes.21À23,35To attach functional groups via the click reaction,an intermediate alkynylated pillar[5]arene 35was prepared by etherification (Scheme 12).Then the coupling reactions between 35and azide compounds were examined to obtain the target products 36À38.In addition to the mono-macrocyclic pillararene mole-cules,functionalization can also afford a pillararene dimer,which is composed of two pillararene units linked by a chain.36À38For this purpose,we have successfully synthe-sized pillar[5]arene dimer 39linked by a single aliphatic chain (Scheme 13).36It is a necessary supplement to the pillararene family and opens a way for studies of pillararene dimers.With a different methodology,other pillar[5]arene dimers were synthesized by linking monodeprotected pillar-[5]arene 39,40with different dihalide derivatives.37,38Besides the functionalization of pillararenes,other reac-tions of pillararenes have been examined,for example,theSCHEME12.Synthesis of Pillar[5]arenes 36À38by Click ReactionsSCHEME 10.Synthesis of Water-Soluble Pillar[5]arene 29SCHEME 11.Synthesis of Water-Soluble Pillar[5]arenes 33and 34Vol.XXX,No.XX’XXXX’000–000’ACCOUNTS OF CHEMICAL RESEARCH ’GPillararenes Xue et al.oxidation of pillar[5]arene 4.27When compound 4was treated with (NH 4)2[Ce(NO 3)6],the pillarquinone was pro-duced,representing the first cyclooligomeric quinone.41Another example is the reaction of DMpillar[5]arene,2,with N -bromosuccinimide (NBS)in acetone to afford bis(4-bromo-2,5-dimethoxyphenyl)-methane.Nitration of 2with nitric acid gave bis(4-nitro-2,5-dimethoxyphenyl)methane.42StructuresInvestigation of the structural features of novel hosts is extremely important because their structural features influence their host Àguest binding properties.Being differ-ent from the basket-shaped structures of the meta -bridgedcalixarenes,pillar[5]arenes have unique,symmetrical archi-tectures.43X-ray crystal structure of 1,4-dipropoxypillar-[5]arene (DPpillar[5]arene)40confirmed that 40was a pentagon from the upper view and a pillar structure from the side view (Figure 1).44The average angle between the two bridging carbon Àcarbon bonds is 108°,which is very close to the normal bond angle of the sp 3carbon atom,109°280.Therefore,DPpillar[5]arene is conformationally stable.The diameter of the internal cavity of DPpillar-[5]arene was ∼4.7Å(Table 1),which is closeSCHEME 13.Synthesis ofPillar[5]areneDimer39FIGURE 1.Crystal structures of P5(a,b)and P6(c,d)and the minimized energy structure of P7(e,f).Hydrogens were omitted for clarity.TABLE 1.Calculated Structural Parameters for 40,41,and 42Based on van der Waals Radii of the AtomsA c (Å)B c (Å)H (Å)d V (Å3)e P5(40)a 4.713.57.8152P6(41)a 6.715.27.8302P7(42)b8.716.97.8493aBased on X-ray crystal structures reported here.b Based on the minimized energy model of P7.c Based on the diameter of the inscribed circle or the circumcircle of the regular pentagon,the regular hexagon,or the regular heptagon.d Based on the distance between the two oxygen atoms on the same benzene ring.e Based on the volume of the regular pentagonal pillar,hexagonal pillar,or heptagonal pillar.Pillararenes Xue et al.to that of cucurbit[6]uril(∼5.8Å)45and R-cyclodextrin(∼4.7Å).46As shown by the crystal structure of DPpillar[6]arene41 reported by our group,44it has a hexagon-like cyclic struc-ture and the diameter of its internal cavity is∼6.7Å, analogous to cucurbit[7]uril(∼7.3Å)45andβ-cyclodextrin (∼6.0Å).46We also obtained the DPpillar[7]arene42.44With the minimized energy structure of42,it is found that DPpillar[7]arene has a heptagonal pillar structure and the diameter of its internal cavity is∼8.7Å,analogous to cucurbit[8]uril(∼8.8Å)45andγ-cyclodextrin(∼7.5Å).46 Cucurbiturils and cyclodextrins are usually insoluble in or-ganic solvents.Thus the organic solvent soluble pillararenes are good and necessary supplements to the corresponding cucurbiturils and cyclodextrins with similar cavity sizes.Calixarenes have separable conformers due to the rota-tion of the phenolic unit.For pillararenes,which are also made up of phenolic units,conformational freedom still remains in their cavity.Up to now,all of the symmetric pillar[5]arenes have two equivalent most stable conforma-tions(pS and pR)in their crystal structures(Figure2).If they are conformationally fixed,the two conformers should be enantiomers.Therefore,investigation of the factors that affect the rotation of phenolic unit is not only helpful for understanding the interconversion between pS and pR forms26but also affords the route to control the rotational motion and subsequently obtain the isolation of the enantiomers.47On the other hand,if the hydroquinone unit was etherified with two different substituents,the pillarar-ene should not only have conformational isomers but also constitutional isomers.This is another aspect to investigate.The rotational behavior of pillar[5]arenes largely de-pends on the intramolecular H-bonding interactions,substit-uents,temperature,solvent,and addition of the guest.Being different from the conformation of DMpillar[5]arene2,14 the flipping of two phenolic units in pillar[5]arene1was observed both in the solid state and in solution at low temperatures due to the intramolecular hydrogen bonds between OH groups and other interactions(Figure3).25,48A similar phenomenon involving intramolecular hydrogen bond effects on the conformational characteristics is ob-served in cyclodextrins.49Furthermore,when pillar[5]arene,1,interacted with dioc-tylviologen salt and formed the hostÀguest complex,the rotational movement was slow on the NMR time scale under À30°C and almost prohibited underÀ60°C.48In other words,the dioctylviologen salt acted as a“braking agent”for the rotation.Modification of pillar[5]arene can also affect the con-formations.The conformational characteristics of the pillar[5]arene derivatives with alkyl groups of different lengths were investigated by variable-temperature1H NMR measurements.17As their length increased,the alkyl substituents packed at the upper and lower rims and thus lowered the conformational freedom of the pillar[5]arenes.17,18,32,35As stated above,there may exist constitutional isomers if the pillar[5]arenes have different substituents at the two rims.It was demonstrated by us that the four constitu-tional isomers43À46of an non-symmetric pillar[5]arene (BMpillar[5]arene)can be prepared and successfully sepa-rated by column chromatography(Scheme14).28,50HostÀGuest Binding PropertiesPillar[n]arenes(n=5,6,7)have some advantages compared with traditional hosts.First,they are highly symmetrical and rigid compared with crown ethers and calixarenes,and this affords their selective binding to guests.Second,they are easier to functionalize with different substituents on the benzene rings than cucurbiturils,which enables tuning of their hostÀguest binding properties.Pillar[5]arene,1,without any modifications is composed of the electron-donor hydroquinone and has ionophores at both ends.Thus,it exhibits interesting hostÀguest propertiesFIGURE2.The pS-and pR-conformations of pillar[n]arenes.FIGURE3.Conformations of DMpillar[5]arene,2,and pillar[5]arene,1, in the crystalline state.Blue dashed lines denote the intramolecularOÀH333O hydrogenbonds.H’ACCOUNTS OF CHEMICAL RESEARCH’000–000’XXXX’Vol.XXX,No.XXVol.XXX,No.XX’XXXX’000–000’ACCOUNTS OF CHEMICAL RESEARCH’IPillararenes Xue et al.with electron-accepting molecules such as viologen and pyridinium derivatives,14,51,52imidazolium cations,53and bis(imidazolium)dications 54in organic media (Figure 4).The Ogoshi and Li groups have presented the binding behavior of paraquats and bis(pyridinium)derivatives by pillar[5]arene 1.14,51Li et al.have investigated the bind-ing modes and complexation stoichiometry for the two types of guests in detail and found that pillar[5]arene,1,formed 2:1external host Àguest complexes with N ,N 0-dialkyl-4,40-bipyridiniums,while it forms 1:1pseudorotaxane-type inclusion complexes with methylene [À(CH 2)n À]-linked bis(pyridinium)derivatives possessing appropriate chain lengths.Some alkyl-substituted pillar[5]arenes exhibit host Àguest properties similar to pillar[5]arene,1.Take BMpillar[5]arene,for example;four constitutional isomers of BMpillar[5]arene 43À46were prepared by our group.50It is interesting that although the four isomers have the same equilateral penta-gonal pillar cavity,they have different arrangements of substituents,which determine their different binding abilities with n -octyltrimethyl ammonium hexafluoro-phosphate to form a [2]pseudorotaxane.Ogoshi et ed the similar trimethyl ammonium moiety to prepare the monofunctionalized pillar[5]arene 47,which formed aself-inclusion complex in CDCl 3,whereas in acetone-d 6dethreading of the guest moiety took place (Figure 5).39Along with charge transfer interactions occurring be-tween the electron-rich cavities of the pillar[5]arenes and the encircled electron-deficient guest molecules,C ÀH 333πinteractions provide main driving forces for the formation of inclusion complexes,as confirmed by us during theFIGURE 4.Structures of pillar[5]arene,1,and guest molecules.FIGURE 5.Solvent-dependent supramolecular structural change of 47.SCHEME 14.Synthesis of Four Constitutional Isomers 43À46of BMpillar[5]areneJ ’ACCOUNTS OF CHEMICAL RESEARCH’000–000’XXXX’Vol.XXX,No.XXPillararenes Xue et al.preparation of copillar[5]arenes.18We found interestingly that an n -hexane molecule was symmetrically included in the cavity of homopillar[5]arene 6or the copillar[5]arene 12to form a pseudorotaxane,driven by multiple C ÀH 333πinteractions (Figure 6).Mainly based on C ÀH 333πinteractions,uncharged ali-phatic amines were encapsulated in the cavity of DMpillar-[5]arene 2recently.This binding motif was further explored in the preparation of a [2]rotaxane (Figure 7).21Furthermore,utilizing multiple C ÀH 333πinteractions and C ÀH 333O(N)hydrogen bonds,simple alkyl-substituted pillar[5]arenesalso form stable interpenetrated complexes with neutral bis(imidazole)guests (Figure 8).55All of the above host Àguest complexes are formed in organic media,which results from the poor solubility of pillar[5]arene in aqueous media and limits the develop-ment of host Àguest chemistry of pillar[5]arene.In order to solve this problem,water-soluble pillar[5]arenes were prepared.32À34,56In 2010,Ogoshi et al.synthesized the water-soluble pillar[5]arene 29containing 10negatively charged carboxylate groups,which binds cationic viologen salts in water.Subsequently,the water-soluble pillar[5]arene 33containing neutral amino groups was prepared by Hou et al.;it encapsulates linear diacids in neutral,alkaline,and acidic conditions.Recently a cationic pillar[5]arene 34bearing trimethy-lammonium groups on both two rims has been synthesized by us and revealed to bind sodium 1-octanesulfonate in aqueous media,forming a [2]pseudorataxane mainly driven by hydrophobic and electrostatic interactions (Figure 9).34With the negatively charged carboxylatopillar[5]arene 28,the binding behavior of substituted 1,4-bis(pyridinium)-butane derivatives has been investigated in aqueous phos-phate buffer solution,and in some cases [2]pseudoro-taxanes with large association constants (>105M À1)were formed.56The association constants,K a (M À1),of pillar[5]arene derivatives and their typical guests are listed in Table 2.It is shown that the K a values of the pillar[5]arene hosts and the surveyed guests changed from 102to 106L/mol.Different driving forces between pillar[5]arenes and different guests such as charge transfer interactions,C ÀH 333πinteractions,hydrogen bonding interactions,and hydrophobic andFIGURE 6.Views of the crystal structures of 6⊃n -C 6H 14(a,c),and 12⊃n -C 6H 14(b,d).Hydrogens on 6and 12were omitted for clarity;6and 12are red,oxygen atoms are green,and n -hexane molecules are blue.The purple dotted lines indicate C ÀH 333πinteractions.FIGURE 7.Formation of a [2]rotaxane with DMpillar[5]arene 2as the ringcomponent.Vol.XXX,No.XX’XXXX’000–000’ACCOUNTS OF CHEMICAL RESEARCH ’KPillararenes Xue et al.electrostatic interactions,affect the association affinity.In addition,the K a values are also dependent on solvent,experimental method,and substituent groups on host or guest molecules.On the other hand,host Àguest complexes with lower K a values might not limit their potential applications.57For example,the supramolecular polymer and mirror image cyclic dimer can be self-assembled driven by C ÀH 333πinteractions,which will be described in the following section.Although many guest molecules have been investigated for pillar[5]arenes,the host Àguest chemistry of pillar-[6]arenes and pillar[7]arenes has rarely been explored.We investigated the complexing properties of DIBpillar-[6]arene 43and DPpillar[6]arene 44with n -octyltrimethylam-monium hexafluorophosphate and found that both formed 1:1complexes in chloroform,while DIBpillar[5]arene,DPpillar[5]arene,and DPpillar[7]arene showed no or weakcomplexation with the same guest due to their smaller or bigger cavity sizes.Self-AssemblyThe host Àguest chemistry of pillar[5]arene with n -hexane can be used in the preparation of supramolecular poly-mers.19We designed and constructed linear supramolecu-lar polymers based on easily available copillararene mono-mers 13,driven by quadruple C ÀH 333πinteractions (Figure 10).It was demonstrated by a combination of various techniques that the formation of the supramole-cular polymer is highly dependent on the temperature and monomer concentration.After this work,two new copillar-[5]arenes,14and 15,were prepared.We found that 14forms a mirror image cyclic dimer in the solid state,while 15forms linear supramolecular structures,pS and pR separated arrays,in the solid state (Figure 11).This researchFIGURE 8.Representation of interpenetrated complexes between pillar[5]arenes and neutral guests.FIGURE 9.The formation of a host Àguest complex from pillar[5]arene 34and sodium 1-octanesulfonate inwater.L ’ACCOUNTS OF CHEMICAL RESEARCH’000–000’XXXX’Vol.XXX,No.XXPillararenes Xue et al.provides a facile approach to control the self-assembly mode of self-complementary copillar[5]arene monomers between cyclic dimers and linear supramolecular poly-mers.In addition,a self-complexing copillar[5]arene 20was reported recently.23Based on the interactions between pillar[5]arene,1,and viologen units,new polypseudorotaxanes and poly-rotaxanes composed of pillar[5]arene,1,and viologen polymer were successfully prepared with extremely high yields by capping the chain ends with adamantyl moieties (Figure 12).58,59Besides its electron-donating property,pillar[5]arene 1also possesses reducing abil-ity,which was used to fabricate polyaniline-based poly-pseudorotaxanes.60A new type of organic nanotubes has been assembled from pillar[5]arenes 1and 27in the solid state.61The water in the nanotubes of 27offer selective proton conductance.Subsequently,a new class of artificial transmembrane pro-ton channels from mono-and dimeric pillar[5]arene deriva-tives 27and 48have been developed by Hou and co-workers.62The new channels conduct protons through water in the pillar[5]arene backbones,the first examples of synthetic water-wire-based proton channels (Figure 13).Recently,based on monofunctionalized pillar[5]arene 19,a polymacrocycle that can self-assemble into a dy-namic,smart clicked surface was prepared.22This assem-bly can switch between vesicles and solid particles through exposure to visible and UV light.This meansTABLE 2.Association Constants (K a )for 1:1Inclusion Complexation of Pillar[5]arenes with Guests G1ÀG8host Àguest K a (M À1)solventmethod1ÀG151(4.5(0.4)Â102DMSOUV/vis experiments 1ÀG254(3.1(0.5)Â1031:1(CD 3)2CO/CDCl 31H NMR experiments 2ÀG32170(10CDCl 31H NMR titration2ÀG321(3.6(0.3)Â1041:1MeCN/H 2O fluorescence experiments 4ÀG455(2.0(0.4)Â104CDCl 31H NMR experiments 43ÀG550(6.3(0.3)Â103CDCl 31H NMR titration29ÀG632(8.2(1.7)Â104H 2O fluorescence experiments 33ÀG733 1.5Â104D 2O 1H NMR titration 34ÀG834(1.3(0.9)Â104D 2O1H NMR titration28ÀG156(1.1(0.2)Â106aqueous phosphate buffer solutionfluorescence experimentsFIGURE 10.Structure of copillar[5]arene 13and two views of the linear supramolecular polymers in the solidstate.。

·目录目录 (2)摘要 (3)ABSTRACT (4)前言 (5)1.1柱芳烃类化合物的发展 (5)1.2柱芳烃的应用 (6)1.2.1主客体包合与分子识别 (6)1.2.2自组装体系和智能材料 (7)1.2.3柱芳烃的合成和修饰 (7)2. 实验部分 (7)2.1仪器与试剂 (7)2.2 合成路线 (8)2.3 合成步骤 (8)3. 结果分析及讨论 (8)3.1物料摩尔比对反应的影响 (8)3.2 温度对反应的影响 (9)4. 实验注意事项 (10)参考文献 (10)致谢 (12)附图 (13)·摘要柱芳烃是通过对二酚醚与亚甲基桥形成的、结构对称的“柱”型大环超分子主体化合物。

目前，已经合成和研究的柱芳烃化合物主要是五元和六元结构。

柱芳烃类化合物由于其具有非常独特的空间结构和理化性质，综合了多种已有主体化合物的特色和优势，近年，在主客体键合与分子识别、自组装体系的构筑和智能材料等领域得到有效应用，所以自2008年首次报道柱芳烃以来，它倍受化学家的青睐。

1,4-二甲氧基柱[5]芳烃是最早合成出的一个柱芳烃，也是最简单的一个柱芳烃，它可以通过衍生得到其他类型柱芳烃。

我们根据文献合成了。

关键词：柱芳烃，超分子，柱芳烃类化合物，应用，合成The synthesis of 1,4-dimethoxypillar[5]arene ·AbstractColumn is an aromatic structure symmetry " pillar " macrocyclic compounds bit supramolecular host bridge formed by phenol . Currently, aromatic compounds have been synthesized and column studies are mainly five- and six-membered structure. Column aromatic compounds due to its very unique spatial structure and physicochemical properties , a combination of features and advantages of various compounds have been the subject of recent years , host-guest inclusion in molecular recognition , self- assembly system to build the field of smart materials and been effectively applied , so the first report since 2008 column aromatics, its much chemist of all ages. Synthetic column aromatic compounds there are two main synthetic organic chemistry strategies , namely, " a ring after the first modification" and "After the first modified into the ring ." The column with the function of the structure of the parent aromatic modification can obtain a variety of novel derivatives of the body , in order that it has wider applications and higher practical value. After inspection of the large number of documents , and the experimental group on the basis of our work, we designed and synthesized five columns aromatic compounds , the discussion of the five-membered aromatic compounds synthesized column , the development of better prospects aromatic compounds column prospectsKey words The column aromatics; supramolecular; columns aromatic compounds;application; synthesis··1前言·1.1柱芳烃类化合物的发展内容要前后对应，文献要对照超分子化学是研究分子间通过非共价键相互作用形成的复杂有序且具有特定功能的分子聚集体的一门新兴交叉学科[1~3]。

柱芳烃固有手性研究进展作者：王海英赵红霞来源：《当代化工》2020年第02期摘 ; ; ;要：柱[5]芳烃是通过亚甲基桥在五个对苯二酚苯环对位连接而成的一类高度对称的大环分子。

该分子为五棱柱形，这种空间排列和由此产生的非平面构象赋予了柱[5]芳烃固有手性。

综述了手性柱[5]芳烃的合成及拆分方法，并重点介绍了手性转换及其在金属有机骨架（MOF）和不对称合成中的应用。

关 ;键 ;词：柱[5]芳烃;固有手性;手性转换;金属有机骨架;不对称合成中图分类号：TQ 460.1 ; ; ; 文献标识码： A ; ; ; 文章编号：1671-0460（2020）02-0384-05Abstract： Pillar[5]arenes， a class of highly-symmetric macrocycles that resemble pentagonal prisms， consist of five hydroquinone units linked by methylene bridges on para-positions. On account of this spatial arrangement and the resulting non-planar conformations， pillar[5]arenes are inherently chiral. In this paper， the syntheses and resolution of chiral pillar[5]arenes were summarized. Their chiral switching behavior， as well as applications in metal-organic framework （MOF） and asymmetric synthesis， was also highlighted.Key words： Pillar[5]arenes; Inherent chirality; Chiral switch; Metal-organic framework; Asymmetric synthesis柱芳烴[1，2]是由对苯二酚或对苯二酚醚通过亚甲基桥在苯环的对位连接而成的类似柱状的大环主体分子。

片段偶联法制备柱芳烃
片段偶联法制备柱芳烃的过程如下：
1. 合成片段：首先，通过化学反应合成柱芳烃的各个片段，包括芳基、连接基团和烷基等。

这些片段可以单独合成，也可以通过适当的保护和脱保护步骤进行分离和纯化。

2. 偶联反应：将各个片段进行偶联反应，即将它们连接在一起形成完整的柱芳烃分子。

偶联反应可以使用不同的方法，如化学偶联、自组装等。

在偶联反应中，需要控制反应条件，如温度、pH值、反应时间等，以确保偶联反应的顺利进行。

3. 分离和纯化：偶联反应完成后，需要对产物进行分离和纯化。

这一步骤可以通过各种方法进行，如结晶、萃取、色谱分离等，以去除未反应的片段和副产物，获得高纯度的柱芳烃产物。

4. 结构表征：最后，使用各种谱学方法对柱芳烃的结构进行表征，如核磁共振、质谱、红外光谱等，以确认产物的结构和纯度。

通过以上步骤，可以使用片段偶联法制备柱芳烃。

这种制备方法具有操作简便、产物纯度高、可重复性好等优点，是制备柱芳烃的一种常用方法。