What question did this study set out to answer?

The aim is to improve silicon thinning processes in High Bandwidth Memory (HBM) packaging by reducing edge breakage and increasing yield.

April 8, 2026Open Access

Nonuniform Silicon Backside Edge‐to‐Center Plasma Thinning Process Using Low Global Warming Potential Gas for High Bandwidth Memory (HBM)

Key Points

The aim is to improve silicon thinning processes in High Bandwidth Memory (HBM) packaging by reducing edge breakage and increasing yield.
Developed a multi-step strategy utilizing ClF3, IF7, and C4F6 gases.
Applied localized magnetic fields to modulate wafer edge profiles precisely.
Conducted plasma diagnostics to understand the effects of IF7 on plasma reactivity.
ClF3 enabled effective thinning while maintaining profile integrity.
Combining ClF3, IF7, and C4F6 minimized surface damage and enhanced yield.
The proposed low-GWP method successfully meets mechanical and environmental standards for next-generation HBM.

Abstract

ABSTRACT Conventional SF 6 based etching in HBM packaging faces low yield and edge breakage due to poor profile control and high GWP. To address this, a multi‐step strategy using ClF 3 , IF 7 , and C 4 F 6 is proposed. While ClF 3 enables efficient thinning, a combination of ClF 3 /IF 7 /C 4 F 6 with a localized magnetic field precisely modulates the wafer edge profile. Plasma diagnostics show that IF 7 induces electron scavenging, reducing plasma reactivity via iodine species to prevent over‐etching at the periphery. This approach ensures high yield, minimal surface damage, and tailored silicon profiles. Ultimately, this low‐GWP chemistry provides a high‐performance, sustainable alternative to SF 6 , meeting the stringent mechanical and environmental requirements for next‐generation HBM integration.

Nonuniform Silicon Backside Edge‐to‐Center Plasma Thinning Process Using Low Global Warming Potential Gas for High Bandwidth Memory (HBM)

Key Points

Abstract

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