Optical Setup for Investigating the Hyperpolarizability of Organic Nanostructure Materials in Solutions Using Electric Field Induced Second Harmonic Generation

IF 0.5 Q4 PHYSICS, MULTIDISCIPLINARY

Jordan Journal of Physics Pub Date : 2023-08-31 DOI:10.47011/16.3.11

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引用次数: 0

Abstract

Abstract: In this paper, an optical setup for electric field-induced second-harmonic generation (EFISH) at 1.9 μm experiment was arranged and used to investigate and determine the hyperpolarizability of some nanostructure organic components in two different solutions. First, a laser beam at 1.9 μm was generated by pumping a hydrogen Raman cell pressurized to 55 bar with 10 Hz Q-switched Nd: YAG nanosecond laser operating at λ = 1.064 μm. Next, the generated laser beam was aligned with all optical components within the assembly. The final step was to optimize the beam’s power and polarization at the center of the EFSH cell. Different nanostructure organic samples in solutions were prepared with nearly the same standard concentration of about 5 mmol/L to be investigated under the optimized system. Two solvents were used in this work, dichloromethane, or DCM (CH2Cl2), and chloroform, or trichloromethane (CHCl3). First, the harmonic order hyperpolarizability of five organic molecules in solutions with different chemical components such as quinolinium groups and organic boron complexes (supplied by the Chemistry Department at Catania University, Italy) were experimentally investigated experimentally. Only component (2-(2-[5′-(N,N-dimethylamino)-(2,2′-bithiophen)-5-yl]vinyl)-1-methyquinolin-1-ium iodide) in chloroform showed a significant difference in Maker fringes amplitude of the applied electrical field in comparison with fringes of its pure solvent. The value ofμfor this component has been calculated as 1320 x 10-48 esu. This value indicates that the component is a suitable candidate for use in second-harmonic generation imaging for biological applications. Keywords: Electric field-induced second-harmonic generation (EFISH), Harmonic light, Organic materials, hyperpolarizability. PACS: Nonlinear optics, 42.65.-k, Electric fields, instrumentation for measurement, 07.50.-e, Organic-inorganic hybrid nanostructures, 81.07.Pr, Organic materials optical materials, 42.70.Jk

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利用电场诱导二次谐波产生研究有机纳米结构材料在溶液中超极化率的光学装置

摘要:在1.9 μm的电场诱导二次谐波产生实验中，利用光学装置研究和测定了某些纳米结构有机组分在两种不同溶液中的超极化率。首先，利用λ = 1.064 μm的10 Hz调q Nd: YAG纳秒激光泵送压力为55 bar的氢拉曼电池，产生1.9 μm的激光束。接下来，生成的激光束与组件内的所有光学元件对齐。最后一步是优化EFSH细胞中心的光束功率和偏振。在5 mmol/L的标准浓度下制备不同纳米结构的有机样品，在优化后的体系下进行研究。在这项工作中使用了两种溶剂，二氯甲烷或DCM (CH2Cl2)和氯仿或三氯甲烷(CHCl3)。首先，实验研究了五种有机分子在不同化学成分(如喹啉基团和有机硼配合物)溶液中的谐波超极化率(由意大利卡塔尼亚大学化学系提供)。氯仿中只有组分(2-(2-[5 ' -(N,N-二甲氨基)-(2,2 ' -双噻吩)-5-基]乙烯基)-1-甲基喹啉-1-碘化ium)与纯溶剂相比，在外加电场的Maker条纹振幅上有显著差异。该组件的“μ”= 1320 × 10- 48esu。该值表明该组件是用于生物应用的二次谐波成像的合适候选者。关键词:电场诱导二次谐波，谐波光，有机材料，超极化率光学学报:自然科学版，42(5):481 - 481。-k，电场，测量仪器，07.50-e，有机-无机杂化纳米结构，81.07。Pr，有机材料光学材料，42.70.Jk

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来源期刊

Jordan Journal of Physics PHYSICS, MULTIDISCIPLINARY-

CiteScore

0.90

自引率

14.30%

发文量