Abstract
Interfacial oxide (IL) /high-k (HK) gate dielectric stack is widely used in 45nm logic technology and beyond nodes. Interfacial oxide, which is buffer layer between silicon substrate and HK dielectric, is a crucial factor to control Silicon/IL, IL/high-k interface charge and high-k film quality. In this work, atom layer deposition (ALD) Hf based HK film is deposited on two classes of IL by thermal oxidation (process A or B) and chemical oxidation (process C or D), respectively. XPS is used to characterize the film bonding energy, while non contact CV and spectroscopic ellipsometry (SE) are used to characterize the interface trap. The electric properties of the film stacks are characterized by C-V and I-V curves. The results reveal that interface trap of chemical oxide film has positive surface voltage and less dense SiOx, as compared with that of thermal oxide. With the same interfacial oxide thickness and HK deposition process, the chemical oxide/HK stack got 3.4A thick EOT, which is about two orders lower leakage than that of thermal oxide/HfO2. It can be explained by the fact that chemical oxide had plenty of O-H bonds, which is good for ALD Hf based HK film nucleation and growth and resulted in good film quality. However, due to the high Si/chemical oxide interfacial charge, the chemical oxide/HfO2 dielectric stack has a disadvantage of the larger C-V hysteresis.
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