Experimental investigation of the impact of LWR on sub-100-nm device performance

Argon Fluoride (ArF) lithography is essential to develop a sub-100-nm device, however, line edge roughness (LER) and line width roughness (LWR) is playing a critical role due to the immaturity of photoresist and the lack of etch resistance. Researchers are trying to improve LER and LWR properties by optimizing photoresist materials and process conditions. In this paper, experiment results are presented to study the impact of LER and LWR to device performance so that the reasonable control range of LER and LWR can be defined. To implement the experiment, a 80-nm node of single negative-channel metal-oxide-semiconductor transistors were fabricated, which had various ranges of gate length, width, LER, and LWR. The amount of LER and LWR could be successfully controlled by applying different resist materials, defocus, and overetch time. Experimental results show that leakage current is significantly increased as LWR increases when the gate length is less than 85 nm. The main degradation is standard deviation of off-current (I/sub off/), and LWR is better representation to characterize a device performance.