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Amorphous boron nitride as an ultrathin copper diffusion barrier for advanced interconnects

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Kaya, Onurcan
Kim, Hyeongjoon
Kim, Byeongkyu
Galvani, Thomas
Colombo, Luigi
Lanza, Mario
Shin, Hyeon Jin
Cole, Ivan
Shin, Hyeon Suk
Roche, Stephan

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This study focuses on amorphous boron nitride (α-BN) as a novel diffusion barrier for advanced semiconductor technology, particularly addressing the critical challenge of copper diffusion in back-end-of-line (BEOL) interconnects. Owing to its ultralow dielectric constant and robust barrier properties, α-BN is examined as an alternative to conventional low-k dielectrics. The investigation primarily employs theoretical modelling, using a Gaussian approximation potential, to simulate and understand the atomic-level interactions. This machine-learning-based potential enables realistic simulations of amorphous α-BN structures and allows us to examine how different film morphologies affect barrier performance. Furthermore, we studied the electronic and optical properties of the films using a simple Tight-Binding model. In addition to the theoretical work, we performed copper diffusion experiments through PECVD-grown α-BN on Si substrates. Theoretical and experimental results indicate that α-BN films can suppress Cu diffusion at nanometre thicknesses. Together, molecular dynamics simulations based on a machine-learned interatomic potential and PECVD experiments support the use of α-BN as a Cu diffusion barrier for BEOL interconnects.

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