What question did this study set out to answer?

The study aims to understand how particle charging dynamics vary based on particle size in EUV-induced plasma.

May 8, 2026Open Access

Particle charging in afterglow of EUV-induced plasma

Key Points

The study aims to understand how particle charging dynamics vary based on particle size in EUV-induced plasma.
Conducted 3D-particle-in-cell simulations to model particle charging in pulsed EUV plasma.
Analyzed the effects of particle size on charge dynamics, specifically between micrometer-sized and sub-micrometer particles.
Micrometer-sized particles achieve steady state charge in one pulse period (20 μs).
Sub-micrometer particles require multiple pulse periods to reach steady state.
The charge and plasma influence the forces acting on the particles, impacting their motion.

Abstract

Micro- and nanoparticle control is essential for high yield in lithography machines. Particles in modern EUV machines are exposed to a plasma, created by the interaction of the high-energetic EUV photons and the background hydrogen gas. In this paper, we explore the particle charging in this pulsed EUV-induced plasma based on 3D-particle-in-cell simulations. It is found that the particle charging dynamics strongly depends on the size of the particle. Micrometer-sized particles typically reach steady state charge in a single pulse period (20 μs), while sub-micrometer particles require multiple pulses. The charge and plasma affect the forces on a particle. Understanding this force balance is essential for controlling particle motion inside EUV scanners and preventing the yield loss that they can cause.

Particle charging in afterglow of EUV-induced plasma

Key Points

Abstract

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