2007 APS April Meeting
Volume 52, Number 3
Saturday–Tuesday, April 14–17, 2007;
Jacksonville, Florida
Session E2: Detection of Dangerous Materials
3:30 PM–5:18 PM,
Saturday, April 14, 2007
Hyatt Regency Jacksonville Riverfront
Room: Grand 1
Sponsoring
Units:
DNP FPS
Chair: Jennifer Wiseman, NASA
Abstract ID: BAPS.2007.APR.E2.1
Abstract: E2.00001 : Overview of Some New Techniques for Inspection: Using 1950's Physics to Solve Modern Problems
3:30 PM–4:06 PM
Preview Abstract
Abstract
Author:
Richard Lanza
(Massachusetts Institute of Technology)
The goal of any inspection technique is to non-intrusively
determine the
presence of such materials in a manner which is consistent with not
interrupting the normal scheme of commerce and which, at the same
time,
exhibits a high probability of detection and a low probability of
false
alarms. A great deal of work has been reported in the literature
on neutron
based techniques for the detection of explosives with by far the
largest
impetus coming from the requirements of the commercial aviation
industry for
the inspection of luggage and, to a lesser extent, cargo; for
baggage, the
major techniques are either x-ray based or are chemical trace
detection
methods which look for small traces of explosive residues.
Nuclear techniques have been proposed for the detection of
explosives and
contraband for a number of years due to their ability to
penetrate shielding
and to identify the elemental composition of materials, thus
leading to
enhanced detection probability and lower false alarm rates. Nuclear
techniques are virtually the only method which can both detect
and identify
the presence of fissile materials, either in the form of bulk
material or
assembled weapons. Some examples of current work in nuclear based
systems
currently under development will be discussed such as nuclear
resonance
radiography, nuclear resonance fluorescence, pulsed fast neutron
analysis
and pulsed photonuclear detection.
The physical basis of these techniques is well known, the physics
having
been studied in the 1950's, but there remain limitations on current
technology with respect to e.g. radiation sources and detectors
and data
acquisition methods. Accelerator-based systems often are large
and are often
not well suited for field use; radiation detectors often suffer
from limited
count rate ability, low sensitivity and poor energy resolution
and data
acquisition and analysis methods usually rely on analog
techniques which are
not always stable in field operation. Current research in basic
physics has
resulted in the development of new accelerators, radiation
detectors and
data acquisition electronics which may help to overcome these
limitations.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2007.APR.E2.1