含X-型二维液晶基元和反式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6冠醚环的液晶共聚酯的合成与表征

以4,4-′(α,ω己二酰氧)二苯甲酰氯(M1)、2,5-二(对辛氧基苯甲酰氧基)氢醌(M2)和反式4,4′-双(4羟基苯基偶氮)二苯并18冠6(M3)为单体,通过溶液共缩聚反应,合成了一系列含X型二维液晶基元和反式4,4′双(4羟基苯基偶氮)二苯并18冠6冠醚环的主链型液晶共聚酯.共聚酯的分子量不高,[η]在0.37～0.25dL g之间.单体的化学结构通过IR、UV、H NMR、MS和元素分析等方法确证.共聚酯的外观为黄色粉状固体,除CP9外,室温下不溶于CHCl3和THF溶剂.共聚酯的性质采用GPC、[η]、DSC、TG、WAXD和POM等方法进行了研究.发现所有的共聚酯加热到各自的熔融温度以上都能形成液晶态,在液晶态可以观察到近晶相的镶嵌织构或焦锥织构或破扇型织构和向列相的球粒织构或丝状织构或纹影织构.共聚酯的熔融温度(Tm)和各向同性温度(Ti)随共聚酯分子中反式4,4′双(4-羟基苯基偶氮)二苯并18冠6用量的改变呈规律性变化.WAXD研究进一步证实了共聚酯的液晶性.     

含X-型二维液晶基元和反式-4,4'-双(4-羟基苯基偶氮)二苯并-18-冠-6冠醚环的液晶共聚酯的合成与表征

以4,4＇-（α,ω-己二酰氧）二苯甲酰氯（M1）、2,5-二（对辛氧基苯甲酰氧基）氢醌（M2）和反式-4,4＇-双（4-羟基苯基偶氮）二苯并-18-冠-6（M3）为单体,通过溶液共缩聚反应,合成了一系列含X-型二维液晶基元和反式-4,4＇-双（4-羟基苯基偶氮）二苯并-18-冠-6冠醚环的主链型液晶共聚酯.共聚酯的分子量不高,[η]在0.37～0.25 dL/g之间.单体的化学结构通过IR、UV、H-NMR、MS和元素分析等方法确证.共聚酯的外观为黄色粉状固体,除CP9外,室温下不溶于CHCl3和THF溶剂.共聚酯的性质采用GPC、[η]、DSC、TG、WAXD和POM等方法进行了研究.发现所有的共聚酯加热到各自的熔融温度以上都能形成液晶态,在液晶态可以观察到近晶相的镶嵌织构或焦锥织构或破扇型织构和向列相的球粒织构或丝状织构或纹影织构.共聚酯的熔融温度（Tm）和各向同性温度（Ti）随共聚酯分子中反式-4,4＇-双（4-羟基苯基偶氮）二苯并-18-冠-6用量的改变呈规律性变化.WAXD研究进一步证实了共聚酯的液晶性.     

含X-型二维液晶基元和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6冠醚环液晶共聚酯的合成与表征

以4,4'-(α,ω-辛二酰氧)二苯甲酰氯(M1)、2,5-双[4-'(对癸氧基苯基)苯甲酰氧基]对苯二酚(M2)和顺式-4,4'-双(4-羟基苯基偶氮)二苯并-18-冠-6(M3)为单体,通过溶液共缩聚反应,合成了一系列新的含X-型二维液晶基元和顺式-4,4'-双(4-羟基苯基偶氮)二苯并-18-冠-6冠醚环的主链犁液晶共聚酯.单体1(M1)由对羟基苯甲酸和辛二酰氯,通过酯化和取代反应制备,单体2(M2)由2,5-二羟基苯醌和对癸氧基苯基苯甲酰氯通过酯化和还原反应制备,单体3(M3)由顺式-二氨基二苯并-18-冠-6和苯酚通过重氮化和偶联反应制备.共聚酯的分子量小高,[η]在0.30～0.39之间.单体的化学结构通过 IR、UV、1H-NMR、MS 和元素分析等方法确证.共聚酯的外观为黄色粉状固体,除共聚酯 CP9 外,室温下不溶于 CHCl3 和 THF 溶剂.共聚酯的性质采用 GPC、[η]、DSC、TG、WAXD 和 POM 等方法进行了研究.发现所有的共聚酯加热到各自的熔融温度以上都能形成液晶态,在液晶态可以观察到近晶相和向列相的典型织构.共聚酯的熔融温度(Tm)和各向同性温度(T1)随共聚酯分子中顺式-4,4'-双(4-羟基苯基偶氮)二苯并-18-冠-6用量的改变呈规律性变化.WAXD 研究进一步证实了共聚酯的液晶性.     

含X-型二维液晶基元和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4冠醚环液晶共聚酯的合成与表征

以4,4′-(α,ω-辛二酰氧)二苯甲酰氯(M1)、2,5-二(对十二烷氧基苯甲酰氧基)对苯二酚(M2)和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4(M3)为单体,通过溶液共缩聚反应,合成了一系列含X-型二维液晶基元和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4冠醚环的主链型液晶共聚酯.单体1(M1)由对羟基苯甲酸和辛二酰氯,通过酯化和取代反应制备,单体2(M2)由2,5-二羟基苯醌和对十二烷氧基苯甲酰氯通过酯化和还原反应制备,单体3(M3)由顺式-二氨基二苯并-14-冠-4和苯酚通过重氮化和偶联反应制备.共聚酯的分子量不高,[η]在0·35~0·25dL/g之间.单体的化学结构通过IR、UV、1H-NMR、MS和元素分析等方法确证.共聚酯的外观为黄色粉状固体,除CP9外,室温下不溶于CHCl3和THF溶剂.共聚酯的性质采用GPC、[η]、DSC、TG、WAXD和POM等方法进行了研究.发现所有的共聚酯加热到各自的熔融温度以上都能形成液晶态,在液晶态可以观察到向列相的丝状织构或纹影织构.共聚酯的熔融温度(Tm)和各向同性温度(Ti)随共聚酯分子中顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4用量的改变呈规律性变化.WAXD研究进一步证实了共聚酯的液晶性.     

含X-型二维液晶基元和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4冠醚环液晶共聚酯的合成与表征

以4,4′-(α,ω-辛二酰氧)二苯甲酰氯(M1)、2,5-二(对十二烷氧基苯甲酰氧基)对苯二酚(M2)和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4(M3)为单体,通过溶液共缩聚反应,合成了一系列含X-型二维液晶基元和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4冠醚环的主链型液晶共聚酯.单体1(M1)由对羟基苯甲酸和辛二酰氯,通过酯化和取代反应制备,单体2(M2)由2,5-二羟基苯醌和对十二烷氧基苯甲酰氯通过酯化和还原反应制备,单体3(M3)由顺式-二氨基二苯并-14-冠-4和苯酚通过重氮化和偶联反应制备.共聚酯的分子量不高,[η]在0·35~0·25dL/g之间.单体的化学结构通过IR、UV、1H-NMR、MS和元素分析等方法确证.共聚酯的外观为黄色粉状固体,除CP9外,室温下不溶于CHCl3和THF溶剂.共聚酯的性质采用GPC、[η]、DSC、TG、WAXD和POM等方法进行了研究.发现所有的共聚酯加热到各自的熔融温度以上都能形成液晶态,在液晶态可以观察到向列相的丝状织构或纹影织构.共聚酯的熔融温度(Tm)和各向同性温度(Ti)随共聚酯分子中顺式-4,4′-双(4-羟基苯基偶氮)二苯并-14-冠-4用量的改变呈规律性变化.WAXD研究进一步证实了共聚酯的液晶性.     

含X-型二维液晶基元和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6冠醚环液晶共聚酯的合成与表征

以4,4-′(α,ω-辛二酰氧)二苯甲酰氯(M1)、2,5-双[4-′(对癸氧基苯基)苯甲酰氧基]对苯二酚(M2)和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6(M3)为单体,通过溶液共缩聚反应,合成了一系列新的含X-型二维液晶基元和顺式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6冠醚环的主链型液晶共聚酯.单体1(M1)由对羟基苯甲酸和辛二酰氯,通过酯化和取代反应制备,单体2(M2)由2,5-二羟基苯醌和对癸氧基苯基苯甲酰氯通过酯化和还原反应制备,单体3(M3)由顺式-二氨基二苯并-18-冠-6和苯酚通过重氮化和偶联反应制备.共聚酯的分子量不高,[η]在0.30~0.39之间.单体的化学结构通过IR、UV1、H-NMR、MS和元素分析等方法确证.共聚酯的外观为黄色粉状固体,除共聚酯CP9外,室温下不溶于CHCl3和THF溶剂.共聚酯的性质采用GPC、[η]、DSC、TG、WAXD和POM等方法进行了研究,发现所有的共聚酯加热到各自的熔融温度以上都能形成液晶态,在液晶态可以观察到近晶相和向列相的典型织构.共聚酯的熔融温度(Tm)和各向同性温度(Ti)随共聚酯分子中顺式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6用量的改变呈规律性变化.WAXD研究进一步证实了共聚酯的液晶性.     

含二苯并-18-冠-6冠醚环的主链型液晶共聚酯的设计与合成(英文)

以4,4′-(α,ω-亚烷基二酰氧)二联苯甲酰氯(M1)、顺式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6(M2)、反式-4,4′-双(4-羟基苯基偶氮)二苯并-18-冠-6(M3)和1,10-癸二醇(M4)为单体,通过溶液共缩聚反应,合成了两个系列新的含联苯型液晶基元和偶氮型冠醚环的主链型液晶共聚酯.共聚酯的[η]在0·25～0·35和0·27～0·38之间.单体的化学结构通过IR、UV-Vis、1H-NMR、MS和元素分析等方法确证.共聚酯的性质采用[η]、DSC、TGA、WAXD和POM等方法进行了研究.发现所有的共聚酯加热到各自熔融温度以上都能形成向列相液晶态,可以观察到向列相的丝状织构或纹影织构或球粒织构.共聚酯的熔融温度(Tm)和各向同性温度(Ti)随共聚酯分子中柔性间隔基长度的增加而有规律地降低,含反式冠醚环的共聚酯的Tm和Ti均高于相应含顺式冠醚环的共聚酯的Tm和Ti.     

偶氮型液晶冠醚的合成与表征

以4'-正烷氧基联苯-4-甲酸和顺(反)-4,4'-双(4-羟基苯基偶氮)二苯并-14-冠-4为中间体, 通过溶液缩合反应, 合成了一系列偶氮型液晶冠醚. 并用元素分析、核磁共振、紫外可见分光光度计、红外光谱、基质辅助激光解析电离飞行时间质谱、示差扫描量热法和偏光显微镜对其进行了表征. 随分子末端烷氧基碳原子数增加, 化合物4I和4II的熔点(T_m)和液晶态的清亮点(T_i)逐渐降低, 液晶态温度范围较宽.     

含氧化偶氮苯介晶基元共聚醚的合成与液晶行为

以1,6-二溴己烷(A)和1,10-二溴癸烷(B)为共缩聚单体,按不同摩尔配比与4,4'-二羟基氧化偶氮苯经相转移催化共聚醚化反应,合成了一系列主链上含有氧化偶氮苯介晶基元的共聚醚,它们均有好的液晶性,其取向膜观察到条带织构,当A/B的摩尔比为1时液晶态范围最宽。     

侧基含羟基的主链偶氮苯液晶共聚酯的合成及其光响应行为

以4,4’-双(6-羟基己氧基)联苯(BHHBP)、4,4’-双(6-羟基己氧基)偶氮苯(BHHAB)为液晶基元,利用苹果酸二乙酯(DM)和苯基丁二酸(PSA)采用无规共聚,合成了侧基含羟基的偶氮苯液晶共聚酯(Az-LCP).先在液晶态下拉伸取向,然后用六亚甲基二异氰酸酯(HDI)交联制备单畴取向偶氮苯液晶交联网络.通过核磁共振氢谱(1H-NMR)、凝胶渗透色谱(GPC)测试,对合成的Az-LCP进行结构表征,通过示差扫描量热分析(DSC)、X射线衍射(XRD)、偏光光学显微镜(POM)等对其液晶相变行为进行表征,研究了偶氮苯含量、交联密度、薄膜厚度对其光致弯曲行为的影响.结果表明,偶氮苯含量10%,交联12 h的Az-LCP1具有最佳的光致弯曲回复行为.     

SYNTHESIS OF MAIN CHAIN LIQUID CRYSTALLINE COPOLYESTERS WITH X-SHAPED TWO-DIMENSIONAL MESOGENIC UNIT AND CROWN ETHER CYCLE

A novel series of main chain liquid crystalline copolyesters with X-shaped two-dimensional mesogenic unit and crown ether cycle of cis-4,4′-bis(4-hydroxyphenylazo) dibenzo-18-crown-6 was prepared via solution condensation polymerization from 4,4′-(α,ω-hexanedioyloxy) dibenzoyl dichloride (M1), 2,5-bis(p-octyloxybenzoyloxy) hydro-quinone (M2) and cis-4,4′-bis(4-hydroxyphenylazo) dibenzo-18-crown-6 (M3). Monomer M1 was synthesized by esterification and substitution of adipoyl chloride with p-hydroxybenzoic acid, monomer M2 was synthesized by esterfication and reduction reaction of 2,5-dihydroxybenzoquinone and p-octanoxybenzoyl chloride and monomer M3 was synthesized by diazotization and coupling reaction of cis-diaminodibenzo-18-crown-6 with phenol. The molecular weights of copolyesters are not high,and the intrinsic viscosity [η] of copolyesters ranges from 0.25-0.35. The monomers' structures were identified by using elemental analysis, IR, UV, 1H-NMR, MS, etc. All the copolyesters are yellowish powders and insoluble in THF and CHCl3 at room temperature except CP9. The properties of copolyesters were investigated by using GPC, [η] , DSC, TG,WAXD and POM. It was found that all the copolyesters entered into liquid crystal phase when they were heated to above their melting temperature (Tm). The typical smectic and nematic phase texture can be observed on POM. Their mesophase transition temperature and thermal stability change regularly with varying the content of cis-4,4′-bis(4-hydroxyphenylazo)dibenzo-18-crown-6 unit in the copolyesters.     

SYNTHESIS OF LIQUID CRYSTALLINE COPOLYESTERS WITH T-SHAPED TWO-DIMENSIONAL MESOGENIC UNIT AND CROWN ETHER CYCLE

A novel series of liquid crystalline copolyesters with T-shaped two-dimensional mesogenic unit and crown ether cycle of cis-4,4′-bis(4-hydroxyphenylazo)dibenzo-18-crown-6 was prepared via solution condensation polymerization from 4,4′-(α,ω-hexanedioyloxy)dibenzoyl dichloride(M_1),2-(4′-ethoxyphenyl)hydroquinone(M_2)and cis-4,4′-bis(4- hydroxyphenylazo)dibenzo-18-crown-6(M_3).The molecular weights of copolyesters are not high,and the intrinsic viscosity [η]of copolyesters ranges from 0.29-0.43.The monomer...     

Synthesis and characterization of trans-di(nitrobenzo)- and di(aminobenzo)-18-crown-6 derivatives with high selectivity

The dibenzo-18-crown-6 derivatives such as di(nitrobenzo)-18-crown-6 and di(aminobenzo)-18-crown-6 were synthesized by nitration reaction and catalytic hydrogenation with high selectivity. The chemical structures were determined by FTIR, ¹H NMR, ¹³C NMR, and UV. Regarding the mixture of Ac₂O and HNO₃ as nitrating agent, the reaction exhibited commendable trans-isomer selectivity. Effects of nitrating agent ratio, reaction temperature and reaction time on yield of trans-di(nitrobenzo)-18-crown-6 were investigated. The yield of trans-di(nitrobenzo)-18-crown-6 was 62.9% for nitrating agent ratio of 1/1, reaction temperature of 50?°C and reaction time of 5?h. Moreover, effect of reaction time on trans-di(aminobenzo)-18-crown-6 was also studied.     

Layer structures. VI. Chiral sanidic polyesters derived from 2,5-bis (dodecyloxy) terephthalic acids and 4,4′-dihydroxybiphenyl

Copolycondensations of (S,S)-2,5-bis(2-methylbutyloxy) terephthaloylchloride with 2,5-bis(dodecyloxy)terephthaloylchloride and with 4,4′-bistrimethylsiloxybiphenyl yielded a series of novel chiral thermotropic copolyesters. These polyesters were characterized by elemental analyses, inherent viscosities, ¹H-NMR spectroscopy, optical rotations, optical microscopy, DSC measurements, and WAXS powder patterns recorded with synchrotron radiation under variation of the temperature. All homo- and copolyesters formed a solid sanidic layer structure with melting temperatures (T_m) ≥ 200°C. A broad enantiotropic nematic or cholesteric phase is formed above T_m with isotropization temperatures (T_is) in the range of 275–325°C. Yet, the T_m of the chiral homopolyester is so high (378°C) that the melting process is immediately followed by rapid degradation. The cholesteric phases of the copolyesters displayed unusual mobile schlieren textures, but a stable Grandjean texture was never obtained. Cholesteric domains consisting of loose bundles of more or less helical main chains are discussed as supramolecular order responsible for the observed textures and their pronounced temperature dependence. © 1997 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 35: 947–957, 1997     

Adventitious isolation of a pseudorotaxane complex of a trans-bis(Hydroxymethylbenzo)-27-crown-9 pyridyl cryptand and a viologen

ABSTRACT

The adventitious isolation and crystal structure of a pseudorotaxane complex of a trans-substituted dibenzo-27-crown-9-based pyridyl cryptand (6) and N,N’-dimethyl-4,4?-bipyridinium bis(hexafluorophosphate) (5) are reported.