Jet-REMPI for the Detection of Explosives
Molecular Physics Laboratory, SRI International
David R. Crosley, P. I.
A short time after a landmine is buried, explosives (such
as trinitrotoluene, TNT) or major explosive contaminants (such
as dinitrobenzene, DNB), begin to leak into the surrounding
soil. These leach toward the surface, usually undergoing chemical
or biological transformation into other explosive related
compounds (ERCs). Above the landmine, these can be present
as vapors; the important compounds to look for are thought
to be DNB, dinitrotoluene, and amino-nitroaromatics. Laser
photoionization techniques such as Jet-REMPI are being developed
at SRI to detect these ERCs in the gas phase.
Jet-REMPI is a method comprising a supersonic nozzle inlet,
a tunable laser, and a time-of-flight mass spectrometer. REMPI
stands for Resonantly Enhanced Multiphoton Ionization. The
inlet cools the molecules to some 20K, much simplifying their
laser absorption spectrum. The laser is tuned to a resonance
transition which is excited by one laser photon; absorption
of a second photon produces the parent ion. This is then detected
by the mass spectrometer.
Jet-REMPI offers a high degree of both sensitivity and selectivity
in a relative short period of analysis time. Although it is
not a universal detector, only applicable to molecules that
absorb in the ultraviolet region of the spectrum, it is particularly
suitable for compounds containing an aromatic ring, which
is the case for ERCs related to TNT.
Progress to date has concentrated on the use of a noncooling
inlet and photofragmentation REMPI to evaluate NO detection
as a suitable measurement approach. Many ERCs absorb the photons
from a laser with a few ns pulse length in such a manner as
to fragment, first to NO2, then to NO. The NO can then be
readily detected using REMPI. This has previously been studied
elsewhere using both REMPI and laser induced fluorescence
of NO, but interferences and limits of detection have not
been assessed. We excite a hot band of NO to avoid atmospheric
NO, which could be present in concentrations as much as a
part per million in a polluted region. However another natural
atmospheric constituent, CH3NO3, shows the same absorption
spectrum as do the ERCs. This is likely true for peroxyacetylnitrate,
present at tens of parts per billion in the ambient atmosphere.
These signals will be much stronger than those from the ERCs
in a field environment, the latter present at a part per billion
at most. Furthermore, detection limits have been established
using this method for ERCs at about a part per billion, barely
sensitive enough. Therefore, detection via photofragmentation
and NO REMPI does not appear a viable method for ERC diagnostics.
Measurements have been made using our versatile but large
laboratory Jet-REMPI apparatus, shown in the first photograph.
Such a system is crucial to testing diagnostics, but is unsuitable
for field work. We have recently constructed a much smaller
system on a different grant; it is shown in the second photograph.
Although less sensitive and less versatile than the lab instrument,
it is what is needed for field work using currently available
laser and mass spectrometer components. As time goes on, such
a device will become even smaller and more usable in the field./p>
Personnel
David R. Crosley
P. I. Senior Staff Scientist
650-859-2395
david.crosley@sri.com
Harald Oser
Physical Chemist
SRI International
650-859-3311
harald.oser@sri.com
Bethany Pond
Postdoctoral fellow-Stanford Univ. visiting at SRI
650-859-3302
bethany.pond@sri.com
