中文摘要：

通过一种小体积、连续性还原反应方法，制备出高浓度、大体积胶体Pd活化液，并采用SEM、TEM、XRD和XPS等手段表征其形貌、结构及元素组成特征，采用化学镀Cu及其电化学测试研究胶体的催化性能。结果表明：该方法能够制备出平均粒径低于4nlil且分布均匀的Pd胶核颗粒；在Pd含量低于25mg／L时，活化液仍具有化学镀催化性能。研究发现：Pd胶团的外壳结构对活化能力起着重要作用，胶团外壳由Sn^2＋、Sn^4＋及Cl^-等组成，可形成2种络合体结构，即[PdSn2]C16和[PdSn3]Cl8，由于[PdSn3]Cl8在解胶中不能水解，可导致胶团丧失活性。该制备方法可减少[PdSn3]Cl8胶团结构的发生，提高了Pd胶体的活化性能。

英文摘要：

The non-conductive substrate is often metallized through electroless plating method. Prior to the electroless plating, the substrate surfaces need to be firstly Pd activation pre-treated. The tradition- al ＂two-step＂ activation process, Le., sensitization-activation, has been gradually obsoleted because of poor controllability and uniformity. A ＂one-step＂ activation process using Pd colloid has been widely used in industry, especially for the microvia metallization treatment in printed circuit board （PCB） fabrication. The bottleneck problem of this technology is the preparation of the Pd colloid solution with high concen- tration and excellent catalytic activity. The aim of this work is to develop a preparation method of the Pd colloid with high concentration and high quality. Pd colloid was prepared by a continuous reduction reaction with minor content. By mean of this process, the Pd concentration of the prepared colloid can exceed 2%. The morphology, microstructure and composition of the Pd colloid were characterized by SEM, TEM, XRD and XPS, respectively. The activate ability of the Pd colloid was examined by electroless Cu and electrochemical test. It was found that the average diameter of the Pd particles was less than 4 nm. Even if the concentration of Pd was less than 25 mg/L, this Pd colloid still had good activation ability for electroless Cu. The result demonstrated that the shell structure of the Pd micelle played a key role for the activation ability. The shell of Pd micelle was consisted of Sn2＋, Sn4＋ and Cl-, and generally formed two structures, [PdSn2]CI8 and [PdSn3]CI,. For the structure of [PdSn3]CI8, the failure of the hydrolysis could lead to the loss of activation. The preparation method in this work can effectively avoid the occurrence of [PdSn3]CIs, which greatly improved the activation ability of the Pd colloid.