Multidiagnostic analysis of ion dynamics in ultrafast laser ablation of metals over a large fluence range

Abstract

The dynamics of ions in ultrafast laser ablation of metals is studied over fluences ranging from the ablation threshold up to approximate to 75 J/cm(2) by means of three well-established diagnostic techniques. Langmuir probe, Faraday cup, and spectrally resolved intensified charge coupled device imaging simultaneously monitored the ions produced during ultrafast laser ablation of a pure copper target with 800 nm, approximate to 50 fs, Ti: Sapphire laser pulses. The fluence dependence of ion yield is analyzed, resulting in the observance of three different regimes. The specific ion yield shows a maximum at about 4-5 J/cm(2), followed by a gradual reduction and a transition to a high-fluence regime above approximate to 50 J/cm(2). The fluence dependence of the copper ions angular distribution is also analyzed, observing a gradual increase in forward-peaking of Cu ions for fluences up to approximate to 10 J/cm(2). A broader ion component is observed at larger angles for fluences larger than approximate to 10 J/cm(2). Finally, an experimental characterization of the ionic angular distribution for several metallic targets (Mg, Al, Cr, Fe, Cu, and W) is carried out at a relatively high fluence of approximate to 66 J/cm(2). Interestingly, the ion emission from the volatile metals shows a narrow, forward-peaked distribution, and a high peak ion yield compared to the refractory metals. Moreover, the width of ionic angular distributions presents a striking correlation with the peak ion yield