N-(4-羟基苯基)马来酰亚胺的合成及其光谱分析

利用对氨基酚和马来酸酐反应制取N-(4-羟基苯基)马来酰亚胺(HPM),并采用红外光谱及核磁光谱对其结构进行了表征.研究了HPM在甲醇、四氢呋喃及二氯甲烷3种溶剂中的紫外光谱.结果发现,在这3种溶剂中,HPM在210～250 nm范围内的吸收峰对溶剂极性及溶液浓度敏感;而275 nm左右的吸收峰在各种极性不同溶剂中位置...     

有机化合物的光物理研究——Ⅸ.三苯胺在不同极性溶剂中的时间分辨瞬态光谱

本文研究了三苯胺(TPA)在不同溶剂中的时间分辨瞬态吸收光谱,测定了三苯胺在不同溶剂中的荧光寿命。讨论了瞬态吸收峰的归属。在正已烷和乙醇中,观察到了三苯胺的三重态瞬态吸收峰(λ_(max)=430nm)和三重态激基缔合物的瞬态吸收峰(λ_(max)=625nm)。在乙腈中,除观察TPA三重态和三重态激基缔合物的瞬态吸收外,还观测到TPA~+的瞬态吸收峰。根据实验结果,提出了TPA在不同极性溶剂中的光物理瞬态过程及其与溶剂相互作用的反应机理。     

溶剂效应和取代基效应对2-(2-氨基苯基)苯并噻唑光谱性质及激发态分子内质子转移的影响

合成了多种2-(2-氨基苯基)苯并噻唑(APBT)氨基氢原子被供电子及吸电子基团取代的衍生物, 并用紫外光谱﹑荧光光谱等方法和密度泛函理论(DFT)计算研究了溶剂效应和取代基效应对衍生物的光谱性质及激发态分子内质子转移(ESIPT)的影响规律. 结果表明, 相比于非极性溶剂环己烷, 随溶剂极性的增加及APBT-溶剂分子间氢键的形成, APBT的紫外-可见最大吸收峰和荧光最大发射峰均发生了一定程度的红移, 并对APBT的ESIPT产生了影响. 在APBT分子的氨基氮原子上引入不同的吸电子或斥电子取代基, 对氮原子的电荷性质有较大的影响. 在环己烷溶剂中, 甲基取代后的APBT仅有单重荧光发射峰, 体系未发生ESIPT过程; 而COCH₂Cl等吸电子基团能促进APBT的ESIPT, 其荧光发射光谱出现了明显的双重峰, 表明体系发生了激发态分子内质子转移反应. 量子化学的理论计算较好地验证了光谱实验结果.     

一个解决溶剂峰分离的新手段

在凝胶色谱的测试中,由于样品和溶剂的原因,经常会出现溶剂峰.目前,普遍认为,溶剂峰的出现是有两个原因造成的,一是样品中未反应的单体、合成过程中加入的低分子添加剂等小分子的物质,或者一些容易吸潮的样品,吸收了空气中的水份.另外一个原因是凝胶色谱仪器用的流动相的溶剂和溶解样品的溶剂不是同一批号.例如,新出厂的四氢呋喃(THF)试剂,为了防止试剂的氧化,一般都加入一些抗氧化剂.溶剂峰出现的干扰了我们的数据处理的结果.     

水与受质子溶剂氢键作用的IR研究

一般认为,水与受质子溶剂通过氢键作用形成1:1和1:2缔合物: H_2O+S?H_2O.S (1) H_2O.S+S?H_2O._2S (2)文献报道了通过NMR和IR光谱等方法求得的各种有机溶剂与水作用的K_(11)和K_(12)值.S.O.Paul等观察了水在受质子溶剂中的IR谱图,将OH伸缩振动区域的吸收峰分解为四个峰并分别指定为1:1和对称1:2缔合物中水的吸收峰.对于二氧六环,四个峰位置分别为:Ⅰ.3653cm~(-1);Ⅱ.3622cm~(-1);Ⅲ.3580cm~(-1);Ⅳ.3509cm~(-1),指定峰Ⅰ、Ⅳ分别为1:1缔合物的非氢键合和氢键合OH伸缩振动吸收,峰Ⅱ、Ⅲ分别为对称1:2缔合物的反对称和     

高选择性氟离子识别受体的设计与识别机理

将酰胺识别基团耦合至基态具有分子内电荷转移特征的对硝基苯基偶氮苯胺分子中,设计合成了受体分子N-苯甲酰基4-(4'-硝基苯基偶氮基)苯胺(3),对氟离子表现出极高的识别选择性.乙腈中该受体3的最大吸收峰位于380 nm,加入氟离子后,该吸收峰强度逐渐减弱,同时在530 nm处出现新的吸收峰,后者为受体分子与氟离子形成的1:1配合物的吸收峰.溶剂极性效应实验表明,该吸收峰具有电荷转移特征.引入氟离子后受体3溶液的颜色由浅黄色转变为紫红色,可实现氟离子的裸眼检测.质子溶剂效应,1H NMR滴定为受体分子3与阴离子间的氢键作用本质提供了直接证据.     

混合溶剂作淋洗剂的体积排除色谱谱图中溶剂化高分子峰和溶剂峰之间内在关系的理论分析

根据体积排除色谱(SEC)研究高分子溶质优先溶剂化的基本原理,证明在SEC色谱图中被束缚溶剂产生的面积与自由溶剂产生的面积大小相等方向相反,在研究优先溶剂化时从高分子峰入手和从自由溶剂峰入手在理论上具有等价性.分析表明,通过对溶剂化高分子峰的研究,还可以得到另一个重要物理参数——恒化学位时高分子溶液的折光指数增量.     

1,8-萘酰亚胺类衍生物的结构及紫外-可见吸收光谱

用密度泛函方法(DFT)优化了一系列1,8-萘酰亚胺衍生物, 用含时密度泛函(TDDFT)和导体极化连续模型(CPCM)计算了它们在气相、环己烷和二氯甲烷溶剂条件下的紫外可见吸收光谱. 计算结果表明, 优化的几何结构和X射线晶体结构数据吻合较好. 萘环4和5位胺基上取代基团(氢基、甲基、苯基和萘基)的变化使得它与萘酰亚胺部分的连接键长(N—C)变长、电荷转移增强、带隙降低. 溶剂化显色效应和前线轨道电子云一致表明此类物质的最大吸收峰对应π-π*跃迁. 异构体A中的分子内电荷转移增大和带隙的降低是它的紫外吸收光谱最大吸收峰比异构体B的发生红移的主要原因.     

菁染料溶剂效应的光谱研究

本文研究了16种菁染料在18种溶剂中的吸收光谱与激光荧光发射光谱的溶剂效应。发现吸收峰的位移⊿σ_A以及吸收峰与荧光发射峰的能量差(σ_A-ν_F)不仅与溶剂的折射率有关, 而且与其介电常数有关。因而用新函数f(n, e)=((n~2-1)/(2n~2+1))+α((e-1)/(e+2))与F(n, e)=((e-1)/(2e+1))-((n~2-1)/(2n~2+1))代替Bayliss函数f(n)=((n~2-1)/(2n~2+1))可改善结果的线性。还观察到溶剂伋性对染料分子荧光峰位置与强度以及对~1(n, π)及~1(π, π°)能级顺序的影响, 并进行了讨论。     

8′-取代吲哚螺噁嗪光致变色化合物的合成及光谱性质

通过在螺噁嗪结构中的萘环8′-位上引入不同的取代基,合成了三种螺噁嗪光致变色化合物;对三种产物的光谱性质进行了对比研究,并考察了其光照褪色速率和抗疲劳性能.结果表明:改变8′-位取代基,合成化合物的闭环吸收峰的位置几乎不受影响,但开环吸收峰发生显著变化,随着取代基极性增加明显红移.增加溶剂的极性,可使同一化合物的开环吸收峰红移.     

Resonance Raman and density functional study of the excited state structural dynamics of 3-amino-2-cyclohexen-1-one in water and acetonitrile solvents

FT-Raman and/or FT-IR spectra of 3-amino-2-cyclohexen-1-one (ACyO) in solid state and/or in solvents of water and acetonitrile were obtained. Density functional theory calculations were done to help elucidate the vibrational band assignments. The A-band resonance Raman spectra of ACyO were acquired in water and acetonitrile solvents to examine the excited state structural dynamics and the state-mixing or curve-crossing tuned by solvents. A preliminary resonance Raman intensity analysis using the time-dependent wave-packet theory and simple model was done for ACyO in acetonitrile solvent. Resonance Raman spectroscopic probing of the excited state curve-crossing or state-mixing was proposed.     

Solvatochromism and preferential solvation of 1,4-dihydroxy-2,3-dimethyl-9,10-anthraquinone by UV-vis absorption and laser-induced fluorescence measurements

Solvation characteristics of 1,4-dihydroxy-2,3-dimethyl-9,10-anthraquinone (1) in pure and binary solvent mixtures have been studied by UV-vis absorption spectroscopy and laser-induced fluorescence techniques. The binary solvent mixtures used as CCl(4) (tetrachloromethane)-DMF (N,N-dimethylformamide), AN (acetonitrile)-DMSO (dimethylsulfoxide), CHCl(3) (chloroform)-DMSO, CHCl(3)-MeOH (methanol), and MeOH-DMSO. The longest wavelength band of 1 has been studied in pure solvents as well as in binary solvent mixtures as a function of the bulk mole fraction. The Vis absorption band maxima show an unusual blue shift with increasing solvent polarity. The emission maxima of 1 show changes with varying the pure solvents and the composition in the case of binary solvent mixtures. Non-ideal solvation characteristics are observed in all binary solvent mixtures. It has been observed that the quantity [nu (12)-(X(1)nu (1)+X(2)nu (2))] serves as a measure of the extent of preferential solvation, where nu and X are the position of band maximum in wavenumbers (cm(-1)) and the bulk mole fraction values, respectively. The preferential solvation parameters local mole fraction (X(2)(L)), solvation index (delta(s2)), and exchange constant (k(12)) are evaluated.     

Composition-Controlled Synthesis of Hybrid Perovskite Nanoparticles by Ionic Metathesis: Bandgap Engineering Studies from Experiments and Theoretical Calculations

Herein a newly discovered non-polar solvent based synthesis of MAPbX₃ hybrid perovskite nanoparticles (NPs) is presented, where MA=Methylammonium and X=I, Br and Cl, as well as their mixed halide counterparts. The methodology proposed is simple and uses low-cost commercial precursors. The conventional method of hybrid perovskite preparation requires methylammonium halide precursors and highly polar solvents. Mandatory use of polar solvents and a particular perovskite precursor makes an intermediate compound which then requires a non-polar solvent to recover the NPs. In contrast here, a whole range of mixed halide perovskite NPs is fabricated without using a methylammonium halide precursor and a polar solvent. In this method, a non-polar solvent is used, which provides a better platform for the particle recovery. Organic cations on the nanoparticle surface prevent degradation from water, due to their hydrophobic nature, and hence offer a stable colloidal suspension in toluene for more than three months. Ab-initio calculations within density functional theory (DFT) predict lower formation energies compared to previously reported values, confirming better chemical stability for this synthesis pathway. Through the halide compositional tuning, these NPs exhibit a variety of emission and absorption starting from ultraviolet to near infrared (IR). The absorption spectra of various halide perovskite show a sharp band edge over the visible wavelength with high absorption coefficient. High oscillator strengths due to high excitonic binding energies combined with the simulated finite dipole transition probabilities point towards the observed high absorption. The emission spectra of mixed halide perovskites vary from 400 to 750 nm, which covers the whole range of visible spectra with sharp full-width at half maxima. Different halide perovskite exhibit average recombination lifetime from 5 to 227 ns. Ambient synthesis, chemical robustness and tunability of emission with varying halide compositions make MAPbX₃ (X=I, Br and Cl) NPs appealing for the optoelectronic applications.     

Comparison of electron injection dynamics from re-bipyridyl complexes to TiO2 nanocrystalline thin films in different solvent environments

Factors that control photoinduced interfacial electron transfer (ET) between molecular adsorbates and semiconductor nanoparticles have been intensely investigated in recent years. In this work, the solvent dependence of interfacial ET was studied by comparing ET rates in dye sensitized TiO2 nanocrystalline films in different solvent environments. Photoinduced ET rates from Re(LA)(CO)3Cl [LA=dcbpy=4,4'-dicarboxy-2,2'-bipyridine] (ReC1A) to TiO2 nanocrystalline thin films in air, pH buffer, MeOH, EtOH, and DMF were measured by femtosecond transient IR spectroscopy. The ET rates in these solvent environments were noticeably different. However, differences between the rates in pH buffer and nonaqueous solvents (MeOH, EtOH, and DMF) were much smaller than the values expected from much more negative TiO2 conduction band-edge positions in the latter solvents under anhydrous conditions. It was suggested that the presence of adsorbed water, which was evident in FTIR spectra, lowered the band edge of TiO2 in these solvents and reduced the rate differences. The important effect of adsorbed water was verified by comparing two samples of Re(LP)(CO)3Cl [LP=2,2'-bipyridine-4,4'-bis-CH2PO(OH)2] sensitized TiO2 in DMF, in which the presence of a trace amount of water was found to significantly increase the injection rate.     

Effects of organic and aqueous solvents on the electronic absorption and fluorescence of chloroaluminum (III) tetrasulphonated naphthalocyanine

The effects of various solvents on the ground and excited states of chloroaluminum (III) tetrasulphonated naphthalocyanine (AlNcS(4)) were studied. Both the absorbance and fluorescence spectra were found to be influenced by the hydrogen bond donating ability of various solvents. As the hydrogen bond donating ability of the solvent increased, hypsochromic and bathochromic shifts in the absorbance and fluorescence spectra were observed in protic and aprotic solvents respectively. Plots of the absorbance and fluorescence maxima versus the E(T)(30) solvent parameter showed linear relationships in binary mixtures of protic-protic (methanol-H(2)O) and aprotic-protic (DMSO-H(2)O) solvents. Aggregation was indicated by a broad band in the ground state absorption spectra and a low quantum efficiency 0.04 relative to the efficiency observed in organic solvents. A face-to-face conformation of the monomeric subunits of the dimer is suggested due to the red-shifted absorbance band. The acid-base properties of the dye were studied and were indicative of a multi-step process. In acidic conditions (pH 1), protonation of the bridging nitrogen atoms was identified by a broad band appearing red-shifted to those obtained at higher pH values. Under slightly acidic conditions a pKa value of 6.7 was determined for one of the meso-nitrogen. In alkaline conditions a pKa of 11.5 was determined for another meso-nitrogen and a second fluorescence band emerged at 804 nm, red-shifted to the emission maxima.     

光异构化反应的研究——水杨醛缩芳胺席夫碱的吸收光谱与分子结构的关系

<正> 具有光致变色现象的席夫碱在过去几十年里一直为人们所感兴趣。一般认为,水杨醛上的邻羟基是这类席夫碱发生光致变色的必要条件。光致变色的过程就是邻羟基的质子转移到亚氨基的氮原子上,随后发生分子内的几何异构,但对此机理仍存在争执。本文主要报道一些席夫碱的电子吸收光谱与分子结构的关系,以及溶剂对电子吸收光谱的影响。     

Features of absorption and fluorescence spectra of prodan

Some important and essential features of absorption and fluorescence spectra of prodan in homogeneous and binary mixes are studied. According to results obtained from experimental and quantum-chemical researches we show that the absorption spectrum of prodan in nonpolar solvent within 25,000-50,000 cm(-1) is formed by eight electronic transitions. Quantum-chemical calculations are performed in the geometry of both the ground and exited states of prodan. The rate constants of photoprocesses and the quantum yield of fluorescence are determined for the prodan and its complexes with water. A dramatic shift of the fluorescence band at changing from nonpolar solvent to isopropyl alcohol and water is explained. The roles of general solvent effects and specific interactions are separated. According to values of molecular electrostatic potential and charges on atoms the centers of possible interaction of prodan with a solvent are obtained. Possible models of prodan complexes in water are offered. The results of quantum-chemical calculation for offered complexes of prodan in water are compared with those for the free prodan molecule. The presence of the second band (about 24,000 cm(-1)) in fluorescence spectra of prodan in isopropyl (ethyl) alcohol-water solvents is explained.     

Studies of the spectra of copper dimethyl-glyoxime, nickel dimethylglyoxime and nickel ethylmethylglyoxime in various solvents

The ultraviolet and visible spectra of copper dimethyl-glyoxime exhibit significant shifts as the solvent medium is varied; no such changes were observed for nickel dimethylglyoxime and nickel ethylmethylglyoxime. The observed variations in the metal-to-ligand charge transfer bands for copper dimethylglyoxime are attributed to slight changes in the nature of the Cu-N bonds; the absence of such changes in the corresponding band in nickel dimethylglyoxime is taken to indicate an insignificant variation in the Ni-N bonds of the two chelates of nickel in different solvents. The presence of small amounts of n-butylamine changed the spectra of copper dimethylglyoxime very significantly while 100-fold excesses of n-butylamine did not alter the spectra of the chelates of nickel. These changes in the spectra of copper dimethylglyoxime were used to establish the assignment of the metal-to-ligand charge transfer band. Finally, in agreement with other investigators, it is concluded that the difference in solubility between copper dimethylglyoxime and nickel dimethylglyoxime in polar solvents is due to the greater tendency of copper dimethylglyoxime to complex with solvent molecules. The higher solubility of nickel ethylmethyl-glyoxime in organic solvents is attributed to stronger crystal forces in both nickel dimethylglyoxime and copper dimethylglyoxime. The stronger forces in copper dimethylglyoxime are due to the well-established Cu-O bonds, and the stronger forces in nickel dimethylglyoxime are attributed to Ni-Ni interactions.     

Peculiar properties of water as solute

Water has been investigated for a long time as the most important solvent; the peculiar behavior of water as solute has been studied in binary mixtures with organic solvents, mainly exploring the whole phase diagram. In this Article, we studied the behavior of water in binary mixtures with propylene carbonate in the phase diagram region where water acts as a solute as a function of the water molar fraction X(water). Surface tension measurements, differential scanning calorimetry (DSC), and Fourier transform infrared spectroscopy (FTIR) have been used to investigate the state of water molecules and hydrogen bonds when water is to be considered a solute instead of a solvent, and peculiar and interesting properties were discovered. The interaction of water molecules among themselves and between water and propylene carbonate has been shown to be dependent on the water concentration in the mixtures. All of the measured properties showed a break at X(water) approximately 0.15-0.20 similar to the break due to the critical micellar concentration in surfactant solutions. In particular, from the FTIR spectra, it was possible to deduce that at this concentration water has a transition from pure solute ("multimers" solvated by PC) to cosolvent ("intermediate" and "network" water).     

Solvatochromic behavior of a nanotubular metal-organic framework for sensing small molecules

A nanotubular metal-organic framework (MOF), {[(WS(4)Cu(4))I(2)(dptz)(3)]·DMF}(n) (dptz = 3,6-di(pyridin-4-yl)-1,2,4,5-tetrazine, DMF = N,N-dimethylformamide) for sensing small solvent molecules is presented. When accommodating different solvent molecules as guests, the resulting inclusion compounds exhibit different colors depending on the solvent guests, and more interestingly, the band gaps of these solvent-included complexes are in linear correlation with the polarity of the guest solvents. The solvent molecules can be sensed by the changes of UV-vis spectra of the corresponding inclusion compounds, showing a new way of signal transduction as a new kind of sensor. The sensing by such a MOF occurs within the channel-containing material rather than on the external surface.