丙氨酸晶体太赫兹振动光谱的实验和理论研究

利用太赫兹时域光谱和低频拉曼光谱仪研究了丙氨酸晶体在0.2-2.6 THz 范围内的太赫兹吸收和拉曼散射光谱. 研究表明: 在该低频范围有四个振动模式, 其中两个只具有拉曼活性, 其余两个同时具有红外和拉曼活性. 基于B3LYP杂化密度泛函的自洽场晶体轨道法对丙氨酸周期性结构进行了理论研究和光谱计算. 通过比较实验和理论结果, 指认了实验光谱特征峰所属的不可约表示. 通过理论计算得到的图形, 得出在此低频范围的振动模式主要包含分子间氢键的扭转和摇摆运动.     

含硫氨基酸的太赫兹光谱

利用太赫兹时域光谱(THz-TDS)技术研究室温条件下多晶含硫氨基酸L-蛋氨酸(Met)和L-半胱氨酸(Cys)的光谱特性, 得到相应的吸收谱和折射率谱, 表明含硫氨基酸在THz波段具有区别于其它氨基酸的显著特征. 在实验测量的有效光谱范围0.2～2.8 THz内, L-蛋氨酸的THz吸收峰分别位于1.06, 1.88和2.70 THz; L-半胱氨酸的吸收峰分别位于1.40, 1.70, 2.33和2.61 THz, 两种氨基酸的平均折射率均为1.44. 利用GAUSSIAN 03软件包中的Hartree-Fock理论计算了蛋氨酸双分子的低频振动谱, 表明了与蛋氨酸各吸收峰对应的分子微观振动模式, 并对实验光谱进行了解析讨论.     

太赫兹光谱和密度泛函理论(DFT)分析呋喃妥因和尿素共晶体

利用太赫兹时域光谱(Terahertz time-domain spectroscopy, THz-TDS)技术对呋喃妥因、尿素及其研磨和溶剂共晶体进行表征分析, 实验结果显示了呋喃妥因和尿素的研磨和溶剂共晶体位于0.85、1.23、1.60 THz的吸收峰明显区别于原料物质. 该结果表明太赫兹光谱技术可以有效鉴别呋喃妥因、尿素及其共晶体. 运用密度泛函理论(Density functional theory, DFT)对呋喃妥因和尿素共晶体的2种可能结构进行了结构优化和光谱模拟, 模拟结果显示其中的结构A在0.49、0.81、1.25、1.61 THz处具有吸收峰, 与实验结果较吻合. 推断共晶体氢键的形成位置为尿素中的氨基H6和呋喃妥因上的酰胺基O30, 该处形成第一处氢键, 而呋喃妥因的酰胺基H31和尿素上的羰基O1形成第二处氢键. 同时结合理论模拟结果对呋喃妥因和尿素共晶体分子振动模式进行归属.     

萘醌及其衍生物的太赫兹时域光谱研究

用太赫兹(THz)时域光谱技术研究了室温条件下的萘醌及其衍生物1,2-萘醌、1,2-萘醌-4-磺酸钠、甲萘醌、白花丹素、胡桃醌的光谱特征,得到了各自的吸收谱和折射率。结果表明,萘醌及其衍生物在此波段有不同的吸收特征,利用太赫兹时域光谱能够鉴别分子结构存在微小差别的化合物。在对样品的吸收谱进行比较的基础上,讨论了分子结构和分子间晶格振动与THz光谱特征吸收的关系。     

常见五元糖的太赫兹时域光谱

利用基于飞秒超快激光的太赫兹时域光谱(terahertz time domain spectroscopy, THz-TDS)对D-木糖、D-核糖、D-阿拉伯糖、D-来苏糖及相关的五元糖进行了研究, 得到了它们在0.1~2.0 THz波段的THz-TDS吸收谱图. 不同糖类化合物的吸收谱表现出明显的特征, 表明THz-TDS技术可以分辨化合物结构上的微小差异, 可以应用于物质检测与分析. 同时还研究比较了不同旋光性五元糖的THz-TDS光谱.     

太赫兹时域光谱技术在化学领域中应用的新进展

随着超快激光技术的发展及其人们对太赫兹(THz)电磁波波段及与脉冲光源认识的进一步深入,太赫兹时域光谱(THz-TDS)技术作为一种新的、快速发展的光谱分析方法在许多领域备受关注。尤其在化学领域,THz-TDS技术已得到了广泛的应用,并显示出了广阔的应用前景。本文介绍了THz技术的特点、THz辐射的产生、探测及其信号处理;讨论了该技术在化学及其相关领域中的应用;初步探讨了该技术在化学领域应用中一些亟待解决的问题及今后发展的方向。     

腺嘌呤与富马酸共晶体的太赫兹光谱分析

利用太赫兹时域光谱(THz-TDS)技术在室温下对腺嘌呤、富马酸及两者的共晶体进行测量, 实验结果显示腺嘌呤与富马酸共晶体在0.92、1.24、1.52 THz处有明显的吸收峰, 与腺嘌呤和富马酸不同, 表明共晶体物相结构不同于原料. 根据腺嘌呤分子氢键供体与受体的结构特点, 使用密度泛函理论(DFT)对腺嘌呤与富马酸三种可能的共晶体结构进行模拟. 结果显示其中一种可能的共晶体结构在0.89、1.16、1.41 THz处存在特征吸收峰, 与实验结果较好吻合. 由此判断腺嘌呤与富马酸共晶体氢键形成位置为腺嘌呤的氨基与富马酸其中一个羧酸的碳氧双键形成氢键, 而此羧酸的羟基与腺嘌呤六元环上的邻位氮原子形成第二处氢键. 本文还结合理论模拟的结果对腺嘌呤与富马酸共晶体的特征吸收峰对应的相关振动模式进行了归属.     

乐果分子的太赫兹时域光谱研究

研究了有机磷农药乐果在0.2~2.5 THz波段的光谱特性。应用密度泛函理论的Becke-3-Lee-Yang-Parr(B3LYP)方法计算了乐果分子在THz波段的振动吸收谱,同时利用THz时域光谱系统(THz-TDS)测得了乐果在此波段的吸收谱和折射率谱。根据理论计算结果,借助于Gaussian View软件对乐果的THz吸收谱进行了指认,并给出了与光谱特征吸收对应的分子振动构象。研究表明:乐果分子在THz波段存在吸收峰,理论计算与实验结果符合较好,且乐果分子在THz波段的吸收是由分子内和分子间振动共同引起。本研究证明了将THz-TDS技术用于乐果分子探测和识别的可行性,为THz时域光谱技术在其它农药分子识别和残留检测中的应用提供了有益的借鉴。     

谷胱甘肽的宽频太赫兹光谱研究

谷胱甘肽(Glutathione)的构型构象对其发挥生物学功能具有重要意义。本研究利用空气等离子体太赫兹时域光谱(THz-TDS)获得了还原型谷胱甘肽(GSH)和氧化型谷胱甘肽(GSSG)在0.5～12.0 THz波段的吸收光谱,结果表明,GSH在太赫兹波段有丰富的特征吸收峰,而GSSG呈现单调无特征的吸收曲线。粉末X射线衍射(PXRD)结果表明,GSH具有一定的晶型结构而GSSG为无定形态,提示太赫兹光谱对物质晶体结构有敏感响应。利用密度泛函理论(DFT)对GSH晶胞结构进行计算和太赫兹振动光谱分析,结果表明,GSH分子能形成丰富的氢键,这些氢键网络有助于约束柔性肽分子并使分子有序地堆叠形成晶体。晶格和氢键与太赫兹波作用产生共振吸收,GSH的太赫兹光谱中不同吸收峰对应分子不同集体振动或局域振动,并且与氢键的振动密切相关。本研究结果有助于加深GSH分子构型构象和分子弱相互作用的认识。     

基于多特征算法选择的太赫兹时域光谱用于水稻种子掺假研究

该文提出了一种基于太赫兹时域光谱的水稻种子模式识别方法。实验以10种不同品牌混合掺假的水稻种子为样本,基于采集的样本太赫兹时域光谱数据,通过建立Relief、随机森林（RF）、支持向量机递归特征消除（SVM-RFE）和最大相关最小冗余（mRMR）模型分别对样本光谱波长进行特征选择,最后设计分类器对4种特征选择方法处理后的样本进行分类识别。结果表明,基于布谷鸟算法（CS）优化的极限学习机模型对经RF特征选择算法提取后的样本光谱数据具有最佳识别效果,其准确率可达100%,实验对于法庭科学领域内种子的掺假鉴定具有一定的借鉴意义。     

Crystal Structure,Thermal Analysis and Spectroscopic Study of Sodium 3,4-Diaminobenzoate

The structure and infrared spectrum of sodium 3,4-diaminobenzoate have been studied. The sodium salt crystallizes in the orthorhombic system, space group Pcab with a = 6.1940(10), b = 14.285(3), c = 21.348(4) Å, and Z = 8. The compound is polymeric in which Na ions are coordinated to six oxygen atoms, with Na-O distances ranging from 2.3380(14)-2.5856(18) Å. The compound dehydrates at 340 K and is decomposed at 485 K. IR spectra of the salt are discussed.     

Crystal Structure and Spectroscopic Investigations of POF3

Phosphoryl fluoride was characterized by Raman spectroscopy and X‐ray diffraction analysis. The X‐ray structure was obtained by in‐situ crystallization. Phosphoryl fluoride crystallizes in the trigonal space group P$\bar{3}$ m1 with two formula units in the unit cell. In the crystal structure zigzag chains are observed which are formed by intermolecular P–O contacts. The Raman spectra of neat and matrix isolated POF₃ display an extra line, which indicates intermolecular interaction in the solid state. Therefore quantum chemically calculation of a POF₃ oligomer was performed. The theoretical calculation indicates that the extra Raman line is caused by side splitting of the P–O valence vibration.     

Terahertz Spectroscopic Analysis of Lactose in Infant Formula: Implications for Detection and Quantification

Lactose plays a significant role in daily lives as a constituent of various food and pharmaceutical products. Yet, lactose intolerance conditions demand low-lactose and lactose-free products in the market. These increasing nutritional claims and labels on food products entail simple and reliable methods of analysis that can be used for meeting quality standards, nutritional claims and legal requirements. In this study, terahertz time–domain spectroscopy (THz-TDS) was employed to analyse α-lactose monohydrate qualitatively and quantitatively in food products. Both absorption spectra and absorption coefficient spectra were investigated for their prediction performance. Regression models for lactose quantification using peak area and height of the absorption peaks 0.53 and 1.37 THz were developed and assessed in infant formula samples. Satisfactory prediction results were achieved in ideal conditions with pure standards, but not in all predictions of infant formula samples. Reasons and further implications are discussed.     

奥美沙坦与苯甲酸共晶的太赫兹光谱与密度泛函理论分析

利用太赫兹时域光谱技术(THz-TDS)与密度泛函理论(DFT)确定奥美沙坦与苯甲酸共晶的分子结构.THz-TDS实验结果显示,奥美沙坦在0.53,0.98和1.09 THz处存在吸收峰,苯甲酸在0.65,0.89和1.10THz处存在吸收峰,而奥美沙坦与苯甲酸共晶则在0.64和1.33 THz处存在吸收峰,表明共晶体物相结构不同于原料物质.根据奥美沙坦分子的结构特点,采用DFT方法对奥美沙坦及奥美沙坦与苯甲酸共晶的3种可能共晶体结构进行模拟.奥美沙坦模拟结果显示其理论光谱在0.76,1.05和1.27 THz处存在吸收峰,与实验相吻合;而对奥美沙坦与苯甲酸所形成的共晶体,模拟结果显示共晶理论晶型Ⅰ与共晶理论晶型Ⅱ及Ⅲ相比更吻合实验结果,由此判断奥美沙坦与苯甲酸共晶结构应为共晶理论晶型Ⅰ.在此共晶体中苯甲酸中羧酸的羰基与奥美沙坦的氨基形成一个氢键,而此羧酸的羟基与奥美沙坦的五元环上的氮原子形成第2个氢键.结合理论模拟的结果对奥美沙坦、奥美沙坦与苯甲酸共晶的吸收峰进行振动模式归属.     

Synthesis, Crystal Structure, and IR Spectroscopic Characterization of 1,6-Hexanediammonium Dihydrogendecavanadate

Summary.  Anhydrous 1,6-hexanediammonium dihydrogendecavanadate ((HdaH₂)₂H₂V₁₀O₂₈, 1) was prepared by reaction of V₂O₅ with 1,6-hexanediamine in aqueous solution. The crystal structure of 1 was determined, and the proton positions in the H₂V₁₀O₂₈ ⁴⁻ anion were calculated by the bond length/bond number method. The protons are bound to the centrosymmetrically oriented μ–OV₃ groups of the decavanadate anion. Based on the analysis of IR spectra of 1 prepared from H₂O and D₂O, the absorption band at 871 cm⁻¹ can be attributed to δ(V–O_b–H) vibrations. Received August 3, 2001. Accepted (revised) October 8, 2001     

Synthesis, Crystal Structure, and IR Spectroscopic Characterization of 1,6-Hexanediammonium Dihydrogendecavanadate

 Anhydrous 1,6-hexanediammonium dihydrogendecavanadate ((HdaH₂)₂H₂V₁₀O₂₈, 1) was prepared by reaction of V₂O₅ with 1,6-hexanediamine in aqueous solution. The crystal structure of 1 was determined, and the proton positions in the H₂V₁₀O₂₈ ⁴⁻ anion were calculated by the bond length/bond number method. The protons are bound to the centrosymmetrically oriented μ–OV₃ groups of the decavanadate anion. Based on the analysis of IR spectra of 1 prepared from H₂O and D₂O, the absorption band at 871 cm⁻¹ can be attributed to δ(V–O_b–H) vibrations.     

Crystal Effects on Mesobilirubin: A Combined NMR Spectroscopic and Density Functional Theory Study

We report solid‐state NMR investigations of crystal effects in powdered mesobilirubin‐IXα, an open‐chain tetrapyrrole that is structurally related to bilirubin‐IXα but hydrogenated at the 3‐ and 18‐vinyl groups. ¹³C and ¹⁵N cross‐polarization magic‐angle spinning (CP/MAS) NMR experiments were performed on the compound at natural abundance. To facilitate the spectral analysis, density functional calculations were carried out at the B3LYP/6‐311G(d,p) level of theory, using an enneameric cluster to simulate the solid. The ¹H, ¹³C and ¹⁵N chemical shift data calculated for the enneamer are in a good agreement with those observed in the experimental spectra, and the relative order of the calculated resonances was thus used to confirm the tentative assignments obtained mainly from the heteronuclear correlation spectra. The observed signal splittings of a small subset of the ¹³C resonances in the peripheral regions of the two terminal rings provide evidence for microcrystalline heterogeneity of the powdered compound.     

Spectroscopic and Crystal Structure of Europium(III) Picrate Complexes with Novel BINOL Derivatives

Two novel ligands N‐Benzyl‐2‐{2′‐[(benzyl‐phenyl‐carbamoyl)‐methoxy]‐[1,1′]binaphthalenyl‐2‐yloxy}‐N‐phenyl‐acetamide (L1) and N‐Methyl‐2‐{2′‐[(methyl‐phenyl‐carbamoyl)‐methoxy]‐[1,1′]binaphthalenyl‐2‐yloxy}‐N‐phenyl‐acetamide (L2), and their europium(III) complexes with picrate, [Eu(pic)₃(L1)] and [Eu(pic)₃(L2)], were synthesized and characterized by elemental analysis, IR, UV‐Vis and fluorescence spectroscopy. The crystal structure of [Eu(pic)₃(L1)]·2CHCl₃ was determined by single crystal X‐ray diffraction. The europium atom is coordinated by nine oxygen atoms of four from the L1 and five from two bidentate and one unidentate picrates. The fluorescent intensity of [Eu(pic)₃(L2)] is about 2.6 times that of [Eu(pic)₃(L1)] in solid states. But in CHCl₃ solution, the fluorescent intensity of [Eu(pic)₃(L1)] is stronger slightly than [Eu(pic)₃(L2)].     

Synthesis,Crystal Structure and Spectroscopic Properties of Zn(II) with N-carbamylglutamate Ligand

Zn C6H8N2O5.H2O(NCGZn) has been synthesized, and its functional groups present in the title compound were confirmed by elemental analysis, TG and IR spectral studies. Meanwhile, the crystal of NCGZn was obtained by slow evaporation of a saturated aqueous solution at room temperature and confirmed by single-crystal X-ray diffraction analysis. It crystallizes in triclinic, space group P21 with a = 5.03220(1), b = 13.3747(4), c = 12.9944(4), β = 92.987(2)°, V = 873.39(4)3, Z = 2, C12H20N4O12Zn2, Mr = 543.10, Dc = 2.065 g/cm3, F(000) = 552, μ(Mo Ka) = 2.826 mm-1, R= 0.0422 and w R = 0.1142. In NCGZn, Zn1 and the symmetry formed Zn1 ions are connected by five atoms from four NCG-2H anions and a water molecule. A NCG ligand has two carboxylate groups, one connecting a Zn ion, and the other bridgiong two Zn ions. The NCG ligand bridges four Zn ions through the amino group and two carboxylate groups with a water molecule to yield a 3D coordination polymer structure with hydrogen bonds.