新型低聚噻吩衍生物的合成及其凝胶化性能研究

设计合成了一系列新型低聚噻吩衍生物N,N'-双十八烷基-5,5"-(2,2:5,2"-三噻吩)二酰胺[N,N'-distearyl-5,5"-(2,2:5,2"-terthiophene) dicarboxamide (DNC₁₈₃T)]、N,N'-双烷烃基-5,5"-(3,3"-双辛烷基-2,2:5,2"-三噻吩)二酰胺[N,N'-dialkyl-5,5"-(3,3"-dioctyl-2,2:5,2"-terthiophene)dicarbox-amide(DNC_nDOc3T,n=5,8,16,18)]及N,N'-双十八烷基-5,5-(3,3-双辛烷基-2,2:5,2":5",2-四噻吩)二酰胺[N,N'-distearyl-5,5-(3,3-dioctyl-2,2:5,2":5",2-tetrathiophene)-dicarboxamide(DNC₁₈DOc4T)].研究结果表明,DNC₁₈₃T和DNC₅DOc3T同有机溶剂不形成凝胶.DNC_nDOc3T(n=8,16,18)和DNC₁₈DOc4T能同几种有机溶剂形成透明、半透明或不透明的凝胶.通过测定凝胶随温度变化的红外光谱(IR)、核磁共振氢谱(¹HNMR)、紫外光谱(UV),揭示出形成有机低分子凝胶的驱动力不仅有分子间氢键,而且π-π相互作用也是一个非常重要的因素.偏光光学显微镜、扫描电子显微镜(SEM)显示出有机低分子凝胶呈三维网络结构.另外,DNC₁₈Doc3T/盐/氰基苯凝胶体系在电场作用下发生可逆的颜色.     

齐聚噻吩衍生物电致变色性质

合成了四种齐聚噻吩衍生物：5,5"-二氰基-2,2’:5’,2"-三噻吩 (DCN3T), 5,5"’-二氰基-2,2’:5’,2":5",2"’-四噻吩 (DCN4T), 5,5"’-甲氧基-2,2’:5’,2":5",2"’-四噻吩(DMO4T) 和 4,4"-二羧基-5,5"-二丙基-2,2’:5’,2"-三噻吩 (BP3T-DCOOH),研究了它们的电致变色性质,研究结果发现,这四种齐聚噻吩衍生物膜在电场作用下,可以发生可逆的颜色变化。     

低聚噻吩衍生物单体的合成及其聚合物薄膜的电致变色性能

合成了两种低聚噻吩衍生物单体:2,3':4',2'-三噻吩(I3T)和5,5'-二醛基-2,3':4',2'-三噻吩(OHC-I3T-CHO).通过电化学方法对单体I3T和OHC-I3T-CHO进行了聚合,制备了相应的聚噻吩衍生物.研究了聚噻吩衍生物薄膜的电致变色性能.当外加一定电压时,基于单体I3T的聚噻吩衍生物薄膜可以在淡黄色和淡蓝色之间发生可逆的颜色变化,基于单体OHC-I3T-CHO的聚噻吩衍生物薄膜能在红色和墨绿色间发生可逆的颜色变化.     

二噻吩衍生物的合成及其线性、非线性光谱性质

合成了一系列二噻吩衍生物类有机合物：5，5'-二（对－N，N－二甲胺基苯乙 烯基）－2，2'－二噻吩（BMSBT）与5，5'－二（对－N，N－二乙胺基苯乙烯基）- 2,2'-二噻吩（BESBT），5,5'-二（对N－环丁胺基苯乙烯基）－2,2'－二噻吩（ BBSBT），5,5－二（对－N－咔唑基苯乙烯基）2-2'－二噻吩（BCSBT），并测定了 其吸收光谱、单光子荧光光谱和双光子荧光光谱。BMSBT，BESBT和BBSBT的单光子 荧光参数存在的很强的、规则的溶剂效应，表明其激发态的分子可能有较大的极性 。在800nm fs激光下测得BMSBT与BESBT在560nm附近（与单光子荧光发射峰波长接 近的位置）有较强的上转换荧光发射，上转换荧光强度与激发能量之间较好的平方 关系表明了双光子激发的机理，这种上转换荧光被称为双光子荧光。用以光子荧光 法测得BMSBT和BESBT的双光子吸收截面分别为54*10~(-50)(cm~4·s)/photon和 102*10~(-50)(cm~4·s)/photon。     

水溶性共轭聚电解质的制备及在有机电致变色器件中的应用

制备了聚噻吩电解质聚[3-(1'-丙氧基-3'-磺酸)噻吩](PTH-n₃-SO₃H). 以铂线和ITO玻璃作为电极, PTH-n₃-SO₃H的水溶液作为支持电解质, 分别以齐聚噻吩衍生物5,5"'-双醛基-2,2': 5',2": 5",2"'-四噻吩(4T-2CHO)和5,5"'-双氰基-2,2': 5',2": 5",2"'-四噻吩(4T-2CN)薄膜作为电致变色活性层, 组装了有机电致变色器件. 研究了4T-2CHO和4T-2CN的电致变色性能, 同时考察了PTH-n₃-SO₃H水溶液作为支持电解质在有机电致变色器件中的应用. 研究发现, 当进行电化学掺杂和去掺杂时, 4T-2CHO膜发生从黄色到蓝绿色的可逆变化, 4T-2CN膜发生从淡黄色到蓝色的可逆变化. 结果表明, PTH-n₃-SO₃H水溶液可以作为支持电解质用于有机电致变色器件.     

基于分子内旋转受限原理的线性共轭小分子的AIE性能研究

研究了6个线性共轭化合物4-丁基联苯(L1)、4,4’-二异丙基联苯(L2)、5,5’-二甲基-2,2’-联吡啶(L3)、2-([1,1’-联苯]-4-)噻吩(L4)、1,1’-联萘(L5)和5-苯基-2,2’-联噻吩(L6)的紫外-可见光谱和荧光发射光谱。结果表明,化合物L1、L2和L3均具有聚集诱导发光(AIE)性能,化合物L4、L5和L6则不具有AIE性能。该研究结果表明,二联苯(或两个简单芳杂环相连)系列化合物具有AIE性能,分子内旋转受限(RIR)是该系化合物产生AIE现象的机理。但是在二联苯的结构基础上继续增加链的长度,或者引入体积更大的芳环(萘环),化合物不再具有AIE性能。     

(—)-2,2'-(2,5-噻吩二甲酰氨基)二丙氨酸和4,4'-联吡啶构筑的铕配位聚合物的水热合成、晶体结构及性质研究

以(—)-2,2'-(2,5-噻吩二甲酰氨基)二丙氨酸(C12H14N2O6S)及4,4'-联吡啶(4,4'-bipy)为配体,在水热条件下合成了铕配位聚合物{[Eu2(C12H12N2O6S)3(4,4'-bipy)(H2O)2]· (H2O)6}n.通过X-射线单晶衍射仪测定其结构,结果表明:晶体为正交晶系,晶胞参数a=1.113992(18) nm,b=1.804 972(19) nm,c=2.933 80(3) nm,Z=4;2个Eu原子分别为九和八配位.测定发现配合物固体具有Eu3+的典型光致发光光谱,配合物中配体能有效提高稀土离子的发光效果.并通过热重分析对配合物进行了热稳定性研究.     

铜三氟柳配合物的合成,结构和仿生催化溴化（英文）

合成了一系列2-羟基-4-三氟甲基苯甲酸(h2tba)-铜配合物:[Cu(htba)2(pz)2](1),[Cu(htba)(2,2′-bipy)](htba)(2)和[Cu(htba)2(4,4′-bipy)](3)(h2tba=2-羟基-4-三氟甲基苯甲酸,pz=吡唑,2,2′-bipy=2,2′-联吡啶,4,4′-bipy=4,4′-联吡啶),并且通过元素分析、红外光谱、紫外光谱、粉末X射线衍射、单晶X射线衍射和热重分析方法对配合物结构进行了表征。这些配合物能够在过氧化氢和溴化物存在的条件下催化苯酚红溴化,并且展示出了较高的催化溴化活性。     

新型六[间-(β-噻吩基)苯基]苯衍生物的合成

3,3’-二溴二苯乙炔与β-噻吩频哪醇硼酸酯发生Suzuki偶联反应制得3,3’-二(2,5-二十二烷基-3-噻吩)二苯乙炔(7);Co2(CO)8催化7自身环三聚合成了新型六[间-(β-噻吩基)苯基]苯衍生物——六{3-[2’,5’-二(十二烷基)-3-噻吩]苯基}苯,产率86%,其结构经1H NMR和MS表征。     

噻唑的研究Ⅳ.4,4''''-二-氯代甲基-2,2''''-雙噻唑的化學.六烷基2,2''''-雙噻唑-4,4''''-二甲基-二銨鹽的合成

1.二硫代乙二酰胺和1,3-二-氯代丙酮在丙酮中和在沉淀碳酸钙存在时缩合得4,4'-二-氯代甲基-2,2'-双噻唑。 2.4,4'-二-氯代甲基-2,2'-双噻唑的两个氯原子反应性能和一级烷基氯相同,能被(1)碘原子:(2)CH_3COO—基团:(3)C_6H_4(CO)_2N—基团:(4)(CH_3)_2N—基团,(5)基团,(6)C_6H_5O—基团,(7)ρ-CH_3C_6H_4O-基团,(8)(C_2H_5)_2N—基团所取代。 3.2,2'-双噻唑-4,4'-二甲基异硫脲二盐酸盐和氫氧化钾溶液共沸得2,2'-双噻唑-4,4'-二甲基二硫醇。 4.其季铵盐可由二法制得:(1)4,4'-二-氯代甲基-2,2'-双噻唑和三甲胺缩合产生二氯化六甲基2,2'-双噻唑-二甲基二铵。(2)4,4'-(N-四甲基-二-氨甲基)-2,2'-双噻唑和碘代甲烷生成二碘化六甲甚2,2'-双噻唑-4,4'-二甲基二铵;相似地-4,4'-(N-四乙基-二-氦甲基)-2,2'-双噻唑和碘代乙烷生成二碘化六乙基2,2'-双噻唑-4,4'-二甲基二铵。     

Synthesis and mesogenic properties of a novel family of oligothiophene derivatives

With the aim of developing new oligothiophene-based liquid crystals involving hydrogen bonding, new terthiophene derivatives containing an alkylamide group, N,N'-distearyl-2,2' : 5',2"-terthiophene-5,5"-dicarboxamide (DNC₁₈3T) and N,N'-dialkyl-5,5"-dibromo-2,2' : 5',2"-terthiophene-4,4"-dicarboxamides (DNC_nDBr3T, n = 5, 8, 16, 18), were designed and synthesized, and their thermal behaviour examined. While DNC₁₈3T did not exhibit liquid crystallinity, DNC_nDBr3T compounds with n = 8, 16, 18 were found to form smectic A phases. In addition to liquid crystal behaviour, crystal polymorphism was also observed for DNC₁₆DBr3T. It is shown that both the position of the amido group and the alkyl chain length greatly affect liquid crystal phase formation. The absence of liquid crystallinity in the corresponding ester derivatives suggests that intermolecular hydrogen bonding also plays a role in the formation of liquid crystal phases in the DNC_nDBr3T system.     

Synthesis and mesogenic properties of a novel family of oligothiophene derivatives

With the aim of developing new oligothiophene-based liquid crystals involving hydrogen bonding, new terthiophene derivatives containing an alkylamide group, N,N'-distearyl-2,2' : 5',2"-terthiophene-5,5"-dicarboxamide (DNC₁₈3T) and N,N'-dialkyl-5,5"-dibromo-2,2' : 5',2"-terthiophene-4,4"-dicarboxamides (DNC_nDBr3T, n = 5, 8, 16, 18), were designed and synthesized, and their thermal behaviour examined. While DNC₁₈3T did not exhibit liquid crystallinity, DNC_nDBr3T compounds with n = 8, 16, 18 were found to form smectic A phases. In addition to liquid crystal behaviour, crystal polymorphism was also observed for DNC₁₆DBr3T. It is shown that both the position of the amido group and the alkyl chain length greatly affect liquid crystal phase formation. The absence of liquid crystallinity in the corresponding ester derivatives suggests that intermolecular hydrogen bonding also plays a role in the formation of liquid crystal phases in the DNC_nDBr3T system.     

Synthesis and liquid crystal properties of a novel family of oligothiophene derivatives

In order to develop novel oligothiophene-based liquid crystals capable of hydrogen bonding, new terthiophene derivatives containing an alkylamide group, N,N′-dialkyl-5,5″-dichloro-2,2′:5′,2″-terthiophene-4,4″-dicarboxamide (DNC_nDCl3T, n=8, 18), N,N′-dialkyl-5,5″-dibromo-2,2′:5′,2″-terthiophene-4,4″-dicarboxamide (DNC_nDBr3T, n=5, 8, 16, 18), or N,N′-dialkyl-5,5″-diiodo-2,2′:5′,2″-terthiophene-4,4″-dica-rboxamide (DNC_nDI3T, n=8, 18), were designed and synthesized, and their thermal behaviour was examined. It was found that DNC₁₈DCl3T, DNC₁₈DI3T and DNC_nDBr3T (n=8, 16, 18) form a smectic A phase and that the alkyl chain length greatly affects liquid crystal phase formation. The absence of liquid crystallinity in the corresponding ester derivatives suggests that intermolecular hydrogen bonding also plays a role in the formation of a liquid crystal phases in the DNC_nDBr3T system.     

Creation of Functional Organic Gels Based on Oligothiophenes

Polymer gels have received a great deal of attention not only from scientific interest but also for their practical applications. Recently, low molecular-weight organic gels have also been receiving growing attention. However, their have been few studies of low molecular-weight organic gels in contrast to extensive studies of polymer gels. In order to develop a novel class of low-molecular-weight organic gels and to gain an insight into the relationship between molecular structures of gel-form…     

Synthesis and Mesogenic Properties of Novel Terthiophene Derivatives

To develop novel oligothiophene‐based liquid crystals involving hydrogen bonding, new terthiophene derivatives containing a stearylamide group, N,N′‐distearyl‐5,5″‐dicyano‐2,2′∶5′,2″‐terthiophene‐4,4″‐dicarboxamide (DNC₁₈DCN 3T) and N,N′‐distearyl‐5,5′‐dipropyl‐2,2′∶5′,2′‐terthiophene‐4,4″‐dicarboxamide (DNC₁₈ DP3T), were designed and synthesized, and their thermal behavior examined. Although DNC₁₈DP3T did not exhibit liquid crystallinity, DNC₁₈DCN3T was found to form smectic A phase.     

Nuclear magnetic resonance studies for the chiral recognition of the novel chiral stationary phase derived from 18-crown-6 tetracarboxylic acid

Enantioselectivities observed in high-performance liquid chromatography (HPLC) with the novel chiral stationary phase (CSP-18C6I) derived from (+)-18-crown-6 tetracarboxylic acid (18C6H₄) were investigated by using nuclear magnetic resonance (NMR) spectrometry. The elution orders in CSP-18C6I, that is, the S-enantiomer of 1-(1-naphthyl)ethylamine (1-NEA) and the

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-enantiomer (S-form) of alanine-β-naphthylamide (Ala-β-NA) eluted prior to each corresponding enantiomer, were successfully explained on the basis of the apparent binding constants (K_a) of the enantiomers to the CSP moiety which were calculated from ¹H-NMR experiments. Detailed HPLC and NMR studies for the chiral recognition of racemic amino compounds with 18C6H₄ hosts showed that ¹H-NMR spectrometry is a useful technique for the investigation of the chiral recognition mechanism in HPLC. Additionally, it was found 18C6H₄ can be recommended as a useful chiral shift reagent for the enantiomeric excess determination by ¹H-NMR.     

Hydrogen-bonded extended arrays of the [Re6(mu3-Se)8]2+ core-containing clusters

Site-differentiated solvated clusters of the general formula [Re(6)(mu(3)-Se)(8)(PEt(3))(n)(MeCN)(6)(-)(n)](SbF(6))(2) (n = 4, cis and trans; n = 5) undergo ligand substitution reaction with isonicotinamide to afford the corresponding amide derivatives, [Re(6)(mu(3)-Se)(8)(PEt(3))(n)(isonicotinamide)(6)(-)(n)](2+) [1 (n = 5); 2 (n = 4, trans); 3 (n = 4, cis)]. Retention of stereochemistry in each case was confirmed by (1)H and (31)P NMR. The solid-state structures of all three compounds were established crystallographically, which revealed self-complementary hydrogen-bonding interactions between adjacent cluster units. While complex 1 exists as hydrogen-bonded dimers in the solid state, compounds 2 and 3 form one-dimensional chains of clusters bridged by paired hydrogen bonds. It is the rigid stereochemistry of the cluster, combined with the classic crystal engineering motif of complementary N-H.O amide hydrogen bonding, that affords the predictable solid-state structures and dimensionality.     

Synthesis and Crystal Structure of 1,4-Bis(2-hydroxymethylphenyl)-1,4-dioxabutane

1 INTRODUCTION Macrocyclic ligands and their metal complexes have received much attention due to their applications in ion transport, ion separation and as models in biomimic researches[1~7]. The synthetic methods of macrocyclic ligands and their metal complexes are mainly divided into three kinds[8]. The first one is synthesizing free ligand, then forming the metal complexes; the second is template synthesis; and the third is synthesizing the end-off or side-off precursor ligand, then c…     

Engineering the structure and magnetic properties of crystalline solids via the metal-directed self-assembly of a versatile molecular building unit

We report the supramolecular chemistry of several metal complexes of N-(4-pyridyl)benzamide (NPBA) with the general formula [Ma(NPBA)2AbSc], where M = Co2+, Ni2+, Zn2+, Mn2+, Cu2+, Ag+; A = NO3-, OAc-; S = MeOH, H2O; a = 0, 1, 2; b = 0, 1, 2, 4; and c = 0, 2. NPBA contains structural features that can engage in three modes of intermolecular interactions: (1) metal-ligand coordination, (2) hydrogen bonding, and (3) pi-pi stacking. NPBA forms one-dimensional (1-D) chains governed by hydrogen bonding, but when reacted with metal ions, it generates a wide variety of supramolecular scaffolds that control the arrangement of periodic nanostructures and form 1- (2-4), 2- (5), or 3-D (6-10) solid-state networks of hydrogen bonding and pi-pi stacking interactions in the crystal. Isostructural 7-9 exhibit a 2-D hydrogen bonding network that promotes topotaxial growth of single crystals of their isostructural family and generates crystal composites with two (11) and three (12) different components. Furthermore, 7-9 can also form crystalline solid solutions (M,M')(NPBA)2(NO3)2(MeOH)2 (M, M' = Co2+, Ni2+, or Zn2+, 13-16), where mixtures of Co2+, Ni2+, and Zn2+ share the same crystal lattice in different proportions to allow the formation of materials with modulated magnetic moments. Finally, we report the effects that multidimensional noncovalent networks exert on the magnetic moments between 2 and 300 K of 1-D (4), 2-D (5), and 3-D (7, 8, 10, and 13-16) paramagnetic networks.