用于相位恢复和滤波的光折变材料光学特性

采用后重氮偶合法,合成了一种新型含咔唑类聚磷腈有机光折变材料。采用氢谱核磁共振法,红外光谱法,紫外-可见吸收光谱法,热重法和差示扫描量热法对该聚合物进行表征和分析,结果表明,该聚合物具有良好的热稳定性,在230℃开始分解,450℃时基本分解完全。UV-Vis表明波长在360nm与570nm之间的宽的吸收带是由于共轭长度的增加产生的,因此可以调整参加偶合反应的重氮盐比例,来控制偶氮生色团功能组分的接入含量。在未使用外加电场及事先极化的条件下对聚合物进行了二波耦合与四波混频实验,证明了聚合物的光折变特性。得到聚合物P-2和P-3的二波耦合增益系数分别为38cm-1和53.6cm-1,聚合物P-2和P-3的四波混频衍射效率分别为2.7%和8.1%。     

咔唑类化合物的光致发光特性

聚二氯磷腈（PDCP）与N-（6-羟基己基）咔唑发生亲核取代,得到了热稳定性良好（约290 ℃）、玻璃化温度较低（约36 ℃）的光电导材料聚双（6-咔唑基己氧基）磷腈。稳态荧光光谱表明,N-（6-羟基己基）咔唑和聚双（6-咔唑基己氧基）磷腈的荧光发射最大波长分别在410 nm和393 nm,其荧光强度相比于咔唑的最大波长420 nm依次减弱并发生蓝移;瞬态荧光光谱表明聚磷腈的线型主链结构和孤立的d-p杂化轨道体系导致其空间位阻增大,破坏了原有的共轭体系,使聚双（6-咔唑基己氧基）磷腈在不同发射波长下的荧光寿命普遍减小。     

聚双(6-咔唑基己氧基)磷腈的合成

以PCl5和NH4Cl为原料采用"一步法"合成了线型聚二氯磷腈(4);4与6-咔唑基己醇发生亲核取代反应合成了聚双(6-咔唑基己氧基)磷腈(5),其结构经1H NMR,31P NMR,IR和GPC表征。热分析结果表明,5具有良好的热稳定性和较高的玻璃化温度。     

短脉冲激光打靶用溅射防护薄膜的光学性质

针对短脉冲激光打靶用溅射防护聚合物薄膜做了初步研究。研究了氟化乙丙共聚物(FEP)、全氟烷氧基共聚物和乙烯-四氟乙烯共聚物三种厚度均为25μm的聚合物薄膜的透过率,结果表明FEP薄膜在355nm处光透过率达93%,有望用于激光打靶的溅射防护。进一步对FEP聚合物薄膜的波前畸变、激光损伤阈值进行了研究,结果表明φ80mm的聚合物薄膜在632.8nm处的透射波前畸变的峰谷值(PV值)为波长的1.006倍;在采用输出波长355nm,脉冲宽度9.3ns的Nd:YAG激光为照射光源波长处,薄膜零损伤概率时的最高激光能量密度为10.35J/cm2,100%损伤概率时的最低激光能量密度为11.48J/cm2。     

低T_g双功能型光折变聚合物的合成及其光致发光特性

以不同比例的重氮盐分别与聚双(N-羟基己氧基咔唑)磷腈(P-1)进行偶合反应,得到了一组以咔唑和对硝基偶氮咔唑为官能团的双功能型光折变聚合物P-2,P-3和P-4,用31 P NMR,1 H NMR,IR,TG,DSC和UV-Vis光谱对该组聚合物进行表征和分析,以325nm的激发波长对P-1,P-2,P-3和P-4进行固体荧光稳态发射光谱的测试。结果表明,该组聚合物具有良好的热稳定性(Td≈300℃)和较低的玻璃化温度(Tg≈30～40℃),P-1具有良好的荧光活性,硝基的引入,导致P-2,P-3和P-4的荧光发生不同程度的猝灭,咔唑与对硝基偶氮咔唑的数量及其空间分布排列的都会对其荧光性能产生影响。     

Synthesis and characterization of Bi-functional photorefractive polymers with high molecular weight and low glass transition temperature

Carbazole-based bi-functional photorefractive polyacrylates were prepared via free radical polymerization and post-azo-coupling reaction. The structure of polymers was characterized by Fourier transform infrared spectroscopy(FTIR) and proton nuclear magnetic resonance(1H-NMR) spectroscopy. The differential scanning calorimetry(DSC) and the thermal gravimetric analysis(TGA) were used to characterize the thermal property of polymers. The results indicate that though the glass transition temperature(Tg) of polymers increases with increasing the ratio of NLO groups, the polymers with different ratios of NLO groups still all show low glass transition temperatures around 60 °C, and good thermal stability, which are favorable to the practical application of these polymers. The gel permeation chromatographic(GPC) result indicates that these polymers all have high-molecular-weight which is favorable to the long term stability of the material. Further, these polymers have good solubility in chloroform solvent, and the solutions can easily be fabricated into optically transparent films. Gain coefficients of 75 cm-1, 185 cm-1 and 66 cm-1 can be observed at zero external electric field without any addition agent or pre-poling for polymers P-2, P-3 and P-4 respectively. The different contents of NLO groups result in the different properties of polymers P-2, P-3 and P-4.