T. Gotz et M. Stuke, SHORT-PULSE UV LASER-ABLATION OF SOLID AND LIQUID-METALS - INDIUM, Applied physics A: Materials science & processing, 64(6), 1997, pp. 539-543
Laser-ablation experiments on solid (T = 300 K) and liquid (T = 600 K)
indium are reported. The ablation was performed under high vacuum con
ditions with UV laser pulses at 248 nm and pulse durations of 15 ns an
d 0.5 ps. The ablated neutral indium atoms were resonantly ionized wit
h a second laser pulse 28 mm above the sample surface and detected in
a time-of-flight mass spectrometer. The ablation threshold fluence for
solid indium decreases by a factor of 40 from 100 mJ/cm(2) to 2.5 mJ/
cm(2) when a 0.5 ps pulse is used instead of a 15 ns laser pulse. Meas
urements on liquid indium show a different behavior. With 15 ns laser
pulses the threshold fluence is lowered by a factor of similar to 3 fr
om 100 mJ/cm(2) for solid indium to 30 mJ/cm(2) for liquid indium. In
contrast, measurements with 0.5 ps laser pulses do not show any change
in the ablation threshold and are independent of the phase of the met
al at 2.5 mJ/cm(2). This behavior could be explained by thermal diffus
ion and heat conduction during the laser pulse and demonstrates in an
independent way the energy lost into the material when long laser puls
es are applied. Time-of-flight measurements to investigate the underly
ing ablation mechanism show thermal behavior of the ablated indium ato
ms for both ps and ns ablation and can be fitted to Maxwell-Boltzmann
distributions.