1) Pulsed Laser Ablation
脉冲激光轰击法
1.
Study on Self-assembly of sp~3 Nanocarbon Prepared in Situ and Its Polymer Composite Materials by Pulsed Laser Ablation;
脉冲激光轰击法原位制备自组装sp~3纳米碳团簇及其聚合物复合材料的研究
2) Pulsed laser ablation
脉冲激光轰击
1.
Sols of nano carbon/polystyrene in benzene was successfully prepared through pulsed laser ablation at the interface between a rotative graphite solid target and a flowing benzene solution of polystyrene.
采用脉冲激光轰击 (PLA IT/SFL)法成功制得纳米碳 /聚苯乙烯的苯溶胶并由此获得纳米碳 /聚苯乙烯杂化薄膜材料。
3) laser flash method
激光脉冲法
1.
Measuring thermal diffusivity of semi-transparent materials by laser flash method
激光脉冲法测量半透明材料的热扩散率
2.
Thermal diffusivity of electron beam-physical vapor deposition (EB-PVD) TBCs was measured using laser flash method.
采用激光脉冲法研究电子束物理气相沉积(EB-PVD)热障涂层热扩散系数的测定,对测定结果进行误差分析,研究试样热处理状况和遮挡层对热扩散系数的影响。
3.
Using laser flash method, thermophysical properties of difficult welding metals and translucent ceramics were successfully measured.
本文以 Parker模型为理论依据 ,在激光热导仪上建立了计算机数据采集、处理系统 ,并运用激光脉冲法 ,成功地测定了不易焊接的金属材料和半透明陶瓷材料的热扩散率、比热和导热系数。
4) pulsed laser deposition
脉冲激光法
1.
Epitaxial growth of colossal magnetoresistive thin films of manganese oxides of La1-xSrxMnO3, La1-xCaxMnO3 and Pr1-xSrxMnO3 have been achieved on LaAlO3 single crystal substrates by pulsed laser deposition.
利用脉冲激光法在LaAlO3衬底上外延生长了La-Ca-Mn—O、La-Sr-Mn-O等巨磁电阻薄膜。
5) laser shock
激光冲击
1.
Simulation and Analysis of laser shock forming process of sheet metal;
金属板料激光冲击成形数值模拟及工艺分析
2.
Study of the effect of laser shock processing on titanium alloy;
航空钛合金的激光冲击研究
3.
The basic principle of laser shock forming was described and the influences of some factors on the deformation results of TA2 sheet were simulated by ABAQUS.
通过数值模拟可优化激光冲击的相关参数,预测板料变形。
6) Laser shock processing
激光冲击
1.
Experiment with QT700 crankshaft by laser shock processing;
QT700球墨铸铁曲轴的激光冲击强化试验
2.
Effect of coating on titanium alloy during laser shock processing;
涂层对钛合金激光冲击效果的影响
3.
Fracture characteristic of Al_2O_3 ceramics by strong laser shock processing;
强激光冲击波作用下Al_2O_3陶瓷材料的断裂特征
补充资料:超短脉冲激光频率转换材料
超短脉冲激光频率转换材料
materials for ultrashort pulses laser frequency conversion
超短脉冲激光频率转换材料materials forultrashort Pulses laser frequeney eonversion用于脉冲宽度从微微秒直到几十毫微微秒激光的频率转换材料。超短脉冲激光具有短的脉宽,较好的模式特性以及高的峰值功率,从而具有很强的非线性性能。经频率转换后,短波的超短脉冲可产生强的光化学反应,是探索微观世界和超高速现象的极为有用的光源。此外,采用薄片倍频材料的超短脉冲倍频,可以作为超短脉冲脉宽测量的一种简便有效的方法,在技术上有实用价值。 对超短脉冲激光频率转换材料的性能主要有以下要求:①高的光损伤闭值。由于超短脉冲的高峰值功率,因而对材料的光损伤阑值提出高的要求,一般要大于GW/cmZ。②相位匹配特性。超短脉冲在空间的尺度短到毫米及几百微米量级,短脉冲波包在材料中以群速度传播。因而,除一般的相速度匹配外,还应满足群速度匹配才能获得较高的能量转换效率。对光学均匀材料,要求基频和倍频波的折射率色散小,才能获得较好的群速度匹配。对I类匹配,群速度要求稍低;对n类匹配要求太苛刻,很难应用。由于群速度失配存在,一般器件只取亚毫米的厚度。过长的光程于能量转换无补,反而引入脉宽的展宽以及能量的损耗。③透过波段。首先要求对参与频率转换的激光波长有高的透过率。对超短脉冲应用场合,材料应有更短的紫外吸收边。其原因是吸收边会增加材料的折射率色散;远离使用波长的吸收边,可使材料获得较好的群速度匹配。 钱激光超短脉冲频率转换的常用材料是磷酸二氢钾(KDP)类晶体。此外,新开发的三硼酸锉(LBO)晶体,由于其高的抗光损伤阑值、好的紫外透过率以及小的色散,也是好的超短脉冲频率转换用材料。有机晶体精氨酸磷酸盐(LAP)和氛化精氨酸磷酸盐(D一LAP)也可用作超短脉冲频率转换用材料。 (邵宗书)
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条