Abstract
Target conditioning is a crucial ingredient of high-power extreme ultraviolet (EUV) source operation in state-of-the-art nanolithography. It involves deforming tin microdroplets into tens of nanometer-thin sheets, sheets which are subsequently irradiated by intense CO2 laser radiation to form a hot, EUV-emitting plasma. Recent experiments have found that a substantial fraction of the initial droplet mass is lost in the deformation phase through fragmentation. The goal of the present study is to investigate, using radiation-hydrodynamic modeling, how variations in the sheet mass affect EUV source power and the laser-to-in-band conversion efficiency (CE). It is found that high-mass sheets can “feed” the plasma with sufficient mass to sustain the production of in-band-emitting charge states over the course of laser irradiation. Low-mass sheets, on the contrary, cannot supply enough mass to sustain this production over the pulse, thus leading to a reduction in in-band power and CE. The dependence of CE on laser energy and target thickness is quantified, and a rather weak reduction of CE with increasing laser energy for high-mass sheets is identified.
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