posted on 2013-05-07, 00:00authored byPo-Chun Chu, Bruno Yue Cai, Yeuk Ki Tsoi, Ronald Yuen, Kelvin
S.Y. Leung, Nai-Ho Cheung
We demonstrated a minimally destructive
two-tier approach for multielement
forensic analysis of laser-printed ink. The printed document was first
screened using a portable-X-ray fluorescence (XRF) probe. If the results
were not conclusive, a laser microprobe was then deployed. The laser
probe was based on a two-pulse scheme: the first laser pulse ablated
a thin layer of the printed ink; the second laser pulse at 193 nm
induced multianalytes in the desorbed ink to fluoresce. We analyzed
four brands of black toners. The toners were printed on paper in the
form of patches or letters or overprinted on another ink. The XRF
probe could sort the four brands if the printed letters were larger
than font 20. It could not tell the printing sequence in the case
of overprints. The laser probe was more discriminatory; it could sort
the toner brands and reveal the overprint sequence regardless of font
size while the sampled area was not visibly different from neighboring
areas even under the microscope. In terms of general analytical performance,
the laser probe featured tens of micrometer lateral resolution and
tens to hundreds of nm depth resolution and atto-mole mass detection
limits. It could handle samples of arbitrary size and shape and was
air compatible, and no sample pretreatment was necessary. It will
prove useful whenever high-resolution and high sensitivity 3D elemental
mapping is required.