High-Temperature Atomic Layer Deposition of Rutile TiO<sub>2</sub> Films on RuO<sub>2</sub> Substrates: Interfacial Reactions and Dielectric Performance
Jihoon Jeon, Taikyu Kim, Myoungsu Jang, Hong Keun Chung, Sung‐Chul Kim, Sung‐Chul Kim, Sung Ok Won, Yongjoo Park, Byung Joon Choi, Yoon Jang Chung, Seong Keun Kim, Seong Keun Kim
Abstract
Capacitor structures utilized in modern dynamic random access memory (DRAM) cells require the conformal growth of high- k films on electrode materials. In this context, the atomic layer deposition (ALD) of rutile-phase TiO 2 on nearly lattice-matched substrates such as RuO 2 has been extensively explored. It is typically desired to grow such insulating films at high temperatures to ensure low defect concentrations and high crystallinity. However, with increasing growth temperature, it is also crucial to consider the aggravated effect of interface reactions that could potentially hinder final device performance. Here, we report the high-temperature ALD growth of TiO 2 on RuO 2 substrates using the heteroleptic precursor trimethoxy(pentamethylcyclopentadienyl)titanium ((CpMe 5 )Ti(OMe) 3 ) and O 3 . High-quality, rutile-phase TiO 2 films with large dielectric constants of ∼100 could be grown at temperatures exceeding 300 °C. When the growth temperature reaches 330 °C, we find that an anomalous RuO 2 reduction reaction occurs due to interactions between the substrate and Ti precursor. The reduced Ru is transformed into volatile RuO 4 during the subsequent O 3 injection steps, resulting in partial etching of the substrate. Simple RuO 2 /TiO 2 /RuO 2 capacitor devices fabricated from optimized films demonstrate excellent dielectric performance with an equivalent oxide thickness (EOT) of 0.5 nm at leakage current densities of less than 10 –7 A/cm 2 . A further reduction of EOT to 0.4 nm could be achieved by implementing a single cycle of Al doping to the TiO 2 films, surpassing the benchmark values proposed for next-generation DRAM capacitors by a safe margin. Our findings clearly showcase the benefits of high-temperature ALD in the semiconductor technology, as well as providing guidelines for the interpretation of the convoluted interface reactions tied to its implementation.