Michael T. Andreas

High Velocity Aerosol Cleaning with Organic Solvents: Particle Removal and Substrate Damage

High velocity aerosol cleaning using ultrapure water or dilute aqueous solutions (e.g. dilute ammonia) is common in semiconductor IC fabrication [1]. This process combines droplet impact forces with continuous liquid flow for improved cleaning efficiency of sub-100nm particles. As with any physically enhanced cleaning process, improved particle removal can be accompanied by increased substrate damage, especially to smaller (<80nm) features [2]. Solvents such as N-methylpyrrolidone (NMP) and tetrahydrofurfuryl alcohol (THFA) are used for resist strip applications [3]. It is possible, and sometimes useful, to deliver these solvents through the same spray nozzle normally used for aqueous spray cleaning. In this presentation we explore the particle removal and substrate damage performance of 2-ethoxyethanol (EGEE), NMP and THFA as used in a conventional aerosol spray cleaning system

Particle Removal Efficiency and Damage Analysis on Silicon Wafers after Megasonic Cleaning in Solvents

The increasing complexity of semiconductor devices imposes challenging requirements on particle contamination and surface damage. To meet these requirements novel surface-cleaning processes are evaluated, which combine physical energy with organic solvents. In this work, the performance of megasonic cleaning with deionized water (DIW) and N-methylpyrrolidone (NMP) was evaluated in terms of particle removal efficiency (PRE) and damage analysis. The goal was to define an optimum process window where the PRE was maximum and the damage was minimum. Particle removal and damage analysis were performed on unpatterned silicon wafers and with patterned polysilicon lines, respectively, under identical sonic power and process parameters. A comparison between these two solvents reveals that at low sonic power the particle-cleaning performances in DIW and NMP are similar. At high sonic power, in both solvents a detailed analysis of the PRE and damage indicates a non-homogeneous trend over the surface of the wafer. More particularly, in DIW higher PRE and damage are noticed towards the edge of the wafer. In NMP, the opposite trend was observed. However, an equivalent performance was obtained at a lower sonic power in case of NMP compared to DIW. Further understanding of megasonic cleaning in solvents, and an optimization of the process parameters are the key to improve the performance of megasonic cleaning in organic solvents like NMP.

Damage Cluster Analysis of Patterned Wafers during Solvent Spray Cleaning

As device structures become smaller they also become more fragile. With the incorporation of metal-high-k layers and shallower implants galvanic corrosion and substrate loss requirements are becoming an important issue. Aqueous chemistries are ceasing to be an option and new solvent cleans are continuously being experimented with. Physical force assisted solvent cleans are increasingly being considered for the removal of particles and resist residues. Whenever a physical force assisted clean is used damage becomes a major concern. In this work the effect of different solvents spray cleans on defect densities over the wafer will be discussed. The damage sites were further analyzed for clusters. The number of defects per cluster for the different solvents was also analyzed. Finally, the cluster size distribution was evaluated for the different solvents.