Observation of ion acceleration in nanosecond laser generated plasma on a nickel thin film under forward ablation geometry

TL;DR

This study observes ion acceleration in nanosecond laser ablation of nickel thin films, revealing complex plasma dynamics, electric field effects, and spectral asymmetries indicating ongoing ion acceleration over time and space.

Contribution

It provides detailed experimental insights into ion acceleration mechanisms and electric field effects in laser-produced plasma from nickel thin films under forward ablation geometry.

Findings

Ion acceleration observed in plasma via TOF spectra.

Spectral asymmetry and broadening indicate micro electric fields.

Electric fields and ion acceleration persist over time and distance.

Abstract

In this article we report acceleration observed for ions in a forward ablation geometry of 50 nm thick nickel film coated on a glass plate under nanosecond laser ablation. A detailed study with varying background pressure and laser energy of time of flight (TOF) spectra of ionic and other neutral transitions from plasma is undertaken. The results indicate that TOF spectra recorded for different neutral transitions exhibit different dynamical behavior (the slower peak of the neutral emission becomes faster with background pressure). Similar observation is seen for the ionic species as well. These observations have similarity to some of the reported double-layer concepts. However, the calculated electric fields from the acceleration appear to be anomalously higher. Along with the acceleration observed for the ionic and neutral lines, significant asymmetry in spectral shape is observed for neutral nickel line (712.2 nm) along with spectral broadening as the background pressure increases. This large asymmetry is indicative of micro electric fields present inside the laser produced plasma plume which may result in a continuous acceleration of ions. Interestingly, the asymmetry in spectral broadening exhibits temporal and spatial dependence which indicates that electric field is present in the plasma plume even for longer duration and also over a significant distance.