用化学镀法制备Pd/Ag膜时膜厚和组成的控制

催化学报 , 2009, 30(12): 1227-1232.

用化学镀法制备Pd/Ag膜时膜厚和组成的控制

曾高峰 ^1, , 史蕾 ^2, , 徐恒泳 ^3,

1.中国科学院大连化学物理研究所,辽宁大连116023;中国科学院研究生院,北京100049

2.中国科学院大连化学物理研究所,辽宁大连116023;中国科学院大连化学物理研究所,辽宁大连116023

3.中国科学院大连化学物理研究所,辽宁大连116023

基金项目: 国家重点基础研究发展规划(973计划)(973计划;2005CB221401)

关键词：钯 , 银 , 复合膜 , 化学镀 , 膜厚控制 , 组成控制 , 沉积规律

Control of Thickness and Composition of Pd/Ag Membrane during Layer-by-Layer Electroless Plating

ZENG Gaofeng ^1, , SHI Lei ^2, , XU Hengyong ^3,

1.中国科学院大连化学物理研究所,辽宁大连116023;中国科学院研究生院,北京100049

2.中国科学院大连化学物理研究所,辽宁大连116023;中国科学院大连化学物理研究所,辽宁大连116023

3.中国科学院大连化学物理研究所,辽宁大连116023

Keywords： palladium , silver , composite membrane , electroless plating , control of membrane thickness , control of metal composition , deposition rule

研究了不同Pd~(2+)含量的镀液在多孔陶瓷载体上的化学沉积规律,发现当Pd沉积层厚度达到约5μm后,即使镀液中反应物的消耗比例很小,膜厚增长也明显变缓,沉积反应主要受膜层表面的催化活性位控制;当镀液中Pd~(2+)含量只能沉积形成小于4μm的Pd膜时,在323K化学镀180min后,镀液中Pd~(2+)的转化率高于90%.与之相似,当Ag镀液中的Ag~+含量等于0.5～2μm的Ag膜层所需量时,在333K化学镀120min后,Ag~+的转化率可达95%.Ag~+的高转化率与Ag颗粒的择向生长特性有关.根据Pd和Ag的化学镀沉积规律,通过调节镀液中金属离子的含量能够预先设计和精确控制超薄Pd/Ag膜的膜厚和组成.

The deposition rules of Pd were investigated during eleetroless plating in baths with different amounts of Pd~(2+).It was demonstrated that the Pd deposition rate was controlled by the auto-catalytic activity of the metal layer surface when the deposited Pd layer became thicker than 5 μm even if Pd~(2+) in the plating baths was far from being consumed.When me Pd~(2+) amount in the bath Was kept lower than that necessary for reaching the Pd layer thickness(e.g.corresponding to 1--4μm Pd),the Pd~(2+) conversion in the bath Was higher than 90% after reaction for 180 min.Furthermore,the same Was found during Ag deposition from silver plating baths with a low amount of Ag~+,i.e.Ag~+conversion was higher than 95% after plating for 120 min in baths containing Ag~+ sufficient for thick Ag layer of 0.5-2μm.It was proved by scanning electron microscopy measurements that the higher conversions of Ag~+ were related to the special growth properties of Ag particles.According to the deposition rules of Pd and Ag,the thickness and metal composition of ultra-thin Pd/Ag membranes prepared by laye-by-layer electroless plating could be pre-designed as well as accurately controlled by preparing relevant plating bath with low amounts ofmetal.

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