等离子体沉积碳氟聚合物薄膜的纳米摩擦性能研究

利用原子力显微镜研究了感应等离子体刻蚀加工过程中单晶硅表面形成的不同厚度的碳氟聚合物薄膜的纳米摩擦特性，并针对几种不同的摩擦模式探讨了原子力显微镜探针在不同厚度的碳氟聚合物薄膜表面的摩擦行为．结果表明，同硅基体相比，聚合物薄膜的摩擦力信号明显较弱，薄膜的纳米摩擦特性同其厚度密切相关；碳氟聚合物薄膜在同Si3N4针尖接触过程中可向针尖表面转移，从而对针尖起修饰作用，以减轻微观摩擦磨损．

Atomic Force Microscopic Study of the Nanofriction Behavior of Fluorocarbon Films on Silicon Substrate Deposited by Inductively Coupled Plasma

Atomic force microscopy (AFM) was used to investigate the nanofriction behavior of fluorocarbon films deposited on a single crystal Si substrate by surface technology systems' inductively coupled system (STS ICP). Thus the modification of the films with different thickness on the surface of the Si_3N_4 tip and its effect on the nanofriction behavior of the films were examined by scanning the original Si surface and the films using an original new tip or the film-modified tip. It was found that the films had much smaller friction forces than the Si substrate. The nanofriction behaviors of the films were closely related to the thickness, while they were liable to transfer onto the tip surface and hence to modify the tip surface during the scanning, which contributed to decrease the nanofriction and wear of the film.