Your search keyword '"Ma, Zichao"' showing total 2 results

1. Air-Gap Technology With a Large Void-Fraction for Global Interconnect Delay Reduction.

Author

Prawoto, Clarissa, Ma, Zichao, Xiao, Ying, Raju, Salahuddin, and Chan, Mansun

Subjects

*AIR gap (Engineering), *YOUNG'S modulus, *SURFACE topography, *CARBON nanofibers

Abstract

With a goal of delay and power reduction in global buses, an air-gap technology for upper-layer interconnect is introduced. The fabrication process is discussed, utilizing ${h}$ -BN as an air-gap capping layer to enable large voids. The suitability of an air-gap technology for integration into the upper-layer back-end-of-line (BEOL) interconnect is evaluated in terms of the void ratio to the adjacent-line spacing. Electrical measurements show that adjacent-line capacitance is reduced by 50%. Mechanical reliability is ensured by Young’s modulus above BEOL requirement. Moisture uptake into air gaps is prevented using a hydrophobic capping layer. The integration of air gaps in global buses results in a 41% and 60% reduction in delay and crosstalk in the worst case switching scenario, based on parameters in the 14-nm technology node. It allows a 72% reduction in the energy-delay product with optimally designed repeaters. For the same delay, power consumption in an air-gapped global bus is reduced by requiring $4\times $ fewer repeaters. [ABSTRACT FROM AUTHOR]

Published

2021

2. Ultralow-k Dielectric With Structured Pores for Interconnect Delay Reduction.

Author

Xiao, Ying, Ma, Zichao, Prawoto, Clarissa, Zhou, Changjian, and Chan, Mansun

Subjects

*DIELECTRICS, *PERMITTIVITY, *POROUS materials, *DIELECTRIC measurements, *POROSITY

Abstract

An ultralow-k dielectric using structured pores to reduce interconnect propagation delay is demonstrated. By using a carbon nanotube (CNT) template, porous oxide with vertical cylindrical pores is formed on the Si3N4 etch-stop layer and successfully integrated with the copper damascene process. The resulting dielectric is anisotropic with an interlayer dielectric constant of k = 1.97 and an intralayer dielectric constant of k = 1.75 at a porosity of 65%. Compared with the conventional porous material with randomly arranged spherical pores, a much higher elastic modulus of 15.7 GPa is achieved to allow the chemical mechanical polish process at a porosity of 65%. [ABSTRACT FROM AUTHOR]

Published

2020