Abstract
We study the behavior of poly(methyl methacrylate) (PMMA) exposed to femtosecond pulses of extreme ultraviolet and X-ray laser radiation in the single-shot damage regime. The employed microscopic simulation traces induced electron cascades, the thermal energy exchange of electrons with atoms, nonthermal modification of the interatomic potential, and a triggered atomic response. We identify that the nonthermal hydrogen decoupling triggers ultrafast fragmentation of PMMA strains at the absorbed threshold dose of ~0.07 eV/atom. At higher doses, more hydrogen atoms detach from their parental molecules, which, at the dose of ~0.5 eV/atom, leads to a complete separation of hydrogens from carbon and oxygen atoms and fragmentation of MMA molecules. At the dose of ~0.7 eV/atom, the band gap completely collapses indicating that a metallic liquid is formed with complete atomic disorder. An estimated single-shot ablation threshold and a crater depth as functions of fluence agree well with the experimental data collected.
Highlights
IntroductionWe study the behavior of poly(methyl methacrylate) (PMMA) exposed to femtosecond pulses of extreme ultraviolet and X-ray laser radiation in the single-shot damage regime
Poly(methyl methacrylate) (PMMA) is a polymer that is widely used in the freeelectron laser experiments for pulse characterization via ablation [1] and desorption imprints [2]
We study the electronic and atomic behavior of irradiated poly(methyl methacrylate) (PMMA) targets to identify the nature of the damage
Summary
We study the behavior of poly(methyl methacrylate) (PMMA) exposed to femtosecond pulses of extreme ultraviolet and X-ray laser radiation in the single-shot damage regime. We identify that the nonthermal hydrogen decoupling triggers ultrafast fragmentation of PMMA strains at the absorbed threshold dose of ~0.07 eV/atom. Poly(methyl methacrylate) (PMMA) is a polymer that is widely used in the freeelectron laser experiments for pulse characterization via ablation [1] and desorption imprints [2]. A lack of understanding of the microscopic details of damage hinders further development of the techniques employing PMMA. They provide femtosecond high-intensity extreme ultraviolet (XUV) and Xray pulses capable of single-shot material ablation, the nature of which remains an open question
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