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| United States Patent Application |
20060032289
|
| Kind Code
|
A1
|
|
Pinnaduwage; Lal Ariyaratna
; et al.
|
February 16, 2006
|
Non-optical explosive sensor based on two-track piezoresistive
microcantilever
Abstract
A two-track piezoresistive cantilever detects explosives in ambient air by
measuring resistance changes in the cantilever when one piezoresistive
track is pulse heated to cause deflagration of explosive adhered to the
surface of the cantilever. The resistance measurement is through the
second piezoresistive track, which is located at the most
resistance-sensitive area. The resistance change of this track is caused
by the temperature change of the cantilever as well as the bending of the
cantilever due to bi-material thermal expansion. The detecting method
using this novel cantilever avoids the use of any optical components such
as a laser and position sensing detector (PSD), which are necessary in
traditional detecting systems using cantilevers. Therefore, it can
extremely reduce the complexity of the detecting system and make a
portable chemical detection system possible that is small, less
expensive, and able to be mass produced and is particularly useful for
the detection of explosives.
| Inventors: |
Pinnaduwage; Lal Ariyaratna; (Knoxville, TN)
; Yi; Dechang; (Oak Ridge, TN)
; Thundat; Thomas George; (Knoxville, TN)
; Hawk; John Eric; (Germantown, TN)
|
| Correspondence Name and Address:
|
UT-Battelle, LLC;Office of Intellectual Property
One Bethal Valley Road
4500N, MS-6258
Oak Ridge
TN
37831
US
|
| Serial No.:
|
052556 |
| Series Code:
|
11
|
| Filed:
|
February 7, 2005 |
| U.S. Current Class: |
73/25.05; 73/31.02 |
| U.S. Class at Publication: |
073/025.05; 073/031.02 |
| Intern'l Class: |
G01N 27/14 20060101 G01N027/14 |
Goverment Interests
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH
[0002] This invention was made with United States Government support under
Contract No. DE-AC05-00OR22725 between the United States Department of
Energy and U.T. Battelle, LLC. The United States Government has certain
rights in this invention.
Claims
1. A cantilever detector for airborne chemicals comprising: a) at least
one uncoated cantilever having at least two separate piezoresistive
tracks; b) means to pulse heat into at least one piezoresistive track; c)
means to detect resistive changes in at least one piezoresistive track;
and d) means to display sensed changes in resistance of at least one
piezoresistive track.
2. A cantilever detector according to claim 1 wherein the airborne
chemical detected is one which undergoes an exothermic reaction on
heating.
3. A cantilever detector according to claim 2 wherein the airborne
chemical is an explosive.
4. A cantilever detector according to claim 3 wherein said explosive is
selected from the group consisting of trinitrotoluene, pentaerythritol
tetranitrate, nitroglycerine and hexahydro-1,3,5-triazine.
5. A cantilever detector according to claim 4 wherein said means to detect
further comprises a detection limit of approximately 70 picograms or less
of trinitrotoluene.
6. A cantilever detector according to claim 1 wherein the airborne
chemical detected is one which undergoes an endothermic reaction when
heated.
7. A cantilever detector according to claim 1 wherein one of said
piezoresistive tracks is disposed substantially at the periphery of said
cantilever.
8. A cantilever detector according to claim 7 wherein said piezoresistive
track disposed substantially at the periphery is pulse heated.
9. A method for detecting an airborne chemical in ambient air comprising:
providing an uncoated cantilever having two piezoresistive tracks
disposed therein; pulsing a current through one of said piezoresistive
tracks to heat said cantilever; detecting the deflection of said
cantilever by monitoring the resistive change in the unpulsed
piezoresistive track.
10. A method according to claim 9 wherein the airborne chemical detected
is one which undergoes an exothermic reaction on heating.
11. A method according to claim 10 wherein the airborne chemical is an
explosive.
12. A method according to claim 11 wherein said explosive is selected from
the group consisting of trinitrotoluene, pentaerythritol tetranitrate,
nitroglycerine and hexahydro-1,3,5-triazine.
13. A method according to claim 12 wherein said detecting step further
comprises a detection limit of approximately 70 picograms or less of
trinitrotoluene.
14. A method according to claim 9 wherein the airborne chemical detected
is one which undergoes an endothermic reaction when heated.
15. A method according to claim 9 wherein one of said piezoresistive
tracks is disposed substantially at the periphery of said cantilever.
16. A method according to claim 15 wherein said piezoresistive track
disposed substantially at the periphery is pulse heated.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims priority to U.S. Provisional Patent
Application 60/600,760 filed Aug. 11, 2004, and is herein incorporated by
reference.
FIELD OF THE INVENTION
[0003] This invention relates to portable detectors that can be
particularly useful in the identification of small amounts of powerful
explosives commonly used in "plastic explosives," particularly favored by
terrorist organizations, as well as other explosives capable of
deflagration caused by heat. The novel, portable system is especially
rugged and useful for the detection of any chemical that exhibits a rapid
exothermic or endothermic response to a heated surface.
BACKGROUND OF THE INVENTION
[0004] Cantilevers such as microcantilevers have become established as
useful experimental devices for the detection of very small samples of a
variety of analytes. Remarkable flexibility is obtained using optical
detection of small movements of the cantilevers based on changes in
vibrational frequency or surface energy changes. Representative of the
sophistication of this detection method is U.S. Pat. No. 6,763,705, to
Thundat et al., herein incorporated by reference, which provides the
advantage of high output for hybridization reactions; and U.S. Pat. No.
5,918,263, herein incorporated by reference, to Thundat, that teaches an
optical readout device for explosives detection.
[0005] The universal application of this technology has been limited by
the use of optics for detection, meaning that the systems are adapted for
laboratory use not used in the field. However, it is the detection of
chemical and biological agents outside a laboratory setting that has
taken on added urgency as the result of the activities of terrorists. The
current invention allows the development of a simple compact sensor that
does not need optics.
[0006] Of the common explosives that have been used in terrorist bombings,
high explosives such as pentaerythritol tetranitrate (PETN) and
hexahydro-1,3,5-triazine (RDX)--frequently used with plastic filler--are
the most serious threats in aircraft sabotage because they can be easily
molded for concealment, are very stable in the absence of a detonator,
and in small amounts are able to destroy a large airplane in flight, a
car, bus, passenger train car or a boat. They are, in fact, the
explosives most commonly used for this purpose. The vapor pressures of
PETN and RDX are quite low, in the range of parts per trillion (PPT) at
ambient temperatures.
[0007] The more recent and refined detection techniques are ion mobility
spectroscopy (IMS), negative-ion atmospheric pressure chemical ionization
mass spectrometry (APCI-MS) and laser-induced fluorescence. The most
sensitive method reported thus far seems to be IMS, for which limits of
detection (LOD) of 80 pg and 300 pg for PETN and RDX, respectively, have
been reported. However, the sampling in the reported testing was not in
the form of the vapor phase, and the explosive material was introduced by
the injection of prepared solutions.
[0008] The effort and technology involved in the detection of explosives
are orders of magnitude more expensive than the effort and costs incurred
by terrorists in deploying them. The sensors in current use are bulky and
expensive and cannot be miniaturized. Only with the development of
extremely sensitive and inexpensive sensors that can be mass-produced can
sensors be deployed in large enough numbers so that the cost of detection
by law enforcement will be less than the cost of deployment by
terrorists. Micro-electro-mechanical systems (MEMS) with sufficient
detection capability are good candidates for such miniature detectors. We
are aware of only four studies, herein incorporated by reference, using
MEMS to detect vapors from explosives, all four studies by us using
microcantilevers: (i) detection of plastic explosive vapors using
self-assembled monolayer coated microcantilevers (L. A. Pinnaduwage, V.
Boiadjiev, J. E. Hawk, and T. Thundat, "Sensitive Detection of Plastic
Explosives with Self-Assembled Monolayer-Coated Microcantilevers", Appl.
Phys. Lett., 83 (7), 1471-1473 (2003), (ii) our studies with
polymer-coated cantilevers, which yielded detection levels of 100 ppt for
DNT; L. A. Pinnaduwage, T. Thundat, J. E. Hawk, D. L. Hedden, P. F.
Britt, E. J. Houser, D. Bubb, S. Stepnowski, and R. A. McGill, "Detection
of 2,4 Dinitrotoluene Using Microcantilever Sensors", Sensors and
Actuators B 99, 223 (2004), and our studies on the detection of TNT using
uncoated microcantilevers: (iii) L. A. Pinnaduwage, Gehl, D. L. Hedden,
G. Muralidharan, T. Thundat, R. T. Lareau, 61. T. Sulchek, L. Manning, B.
Rogers, M. Jones, J. D. Adams, "A Microsensor for Trinitrotoluene
Vapour," Nature 425, 474 (2003), and (iv) L. A. Pinnaduwage, A. Wig, D.
Hedden, A. Gehl, D. Yi, T. Thundat, and R. T. Lareau, "Detection of
Trinitrotoluene via Deflagration on a Microcantilever", Journal of
Applied Physics 95, 5871 (2004).
[0009] For generic explosives, the knowledge that an explosive is present
may be all that is necessary for mass screening such as at airports,
train stations and docks. Land and personnel mines are a persistent
threat in many countries and a simple means for their detection is not
available. There abides a need for a simple, rugged, reliable sensor and
screening instrument for the detection of common explosives.
BRIEF DESCRIPTION OF THE INVENTION
[0010] Most work in this field has been done using optical detection of
cantilever bending, a highly accurate method which is not especially
rugged. Such systems can yield valuable information in the laboratory and
other highly controlled settings, but are not sufficiently portable and
rugged to be used on passengers, luggage compartments or shipping
containers.
[0011] We have found that comparable sensitivity can be obtained using
piezoelectric and piezoresistive self-sensing and self-actuating
cantilevers which are more compact and more rugged than optical sensing
methods and more suitable for field use. The system is especially useful
for the detection of common explosives such as trinitrotoluene (TNT),
pentaerythritol tetranitrate (PETN), nitroglycerin and
hexahydro-1,3,5-triazine (RDX).
[0012] The first aspect of this invention is based upon the use of an
uncoated cantilever which has been fabricated to have two piezoresistive
tracks. The first track is substantially the same as that found in
commercial piezoresistive cantilevers. The second track, preferably
around the perimeter of the cantilevers, serves as a resistive heater.
When the deflagration event is triggered by heating of the cantilever
using the second piezoresistive track, the event is detected using the
first piezoresistive track. Such a device is sturdy, self-cleaning,
immediately re-useable and small enough to be used as a hand-held device
and, in one embodiment, also can detect mass loading.
[0013] Uncoated cantilevers respond to a limited number of analytes but
are suitable for a number of analytes which have low vapor pressure but
are of critical interest; RDX, PETN, TNT and nitroglycerine being among
them. The two track cantilever detects both exothermic and endothermic
response on the heated surface. Exothermic reactions--those associated
with explosives--lead to the release of energy to the cantilever thus
resulting in "an additional bending" of the cantilever. Endothermic
reactions--those associated with non-explosives-remove heat from the
cantilever thus leading to the bending of the cantilever in the opposite
direction to that associated with an exothermic reaction. Both exothermic
and endothermic responses result in almost instantaneous removal of the
analyte from the surface of the cantilever. The cantilever responds by
returning to a neutral "unloaded" position.
[0014] Cantilevers with reduced dimensions are called nanocantilevers.
Nanocantilevers typically have a length of approximately 1 .mu.m
(micron). The thickness and width of a nanocantilever are adjusted such
that the cantilever is free from size-induced deformations. When the term
cantilever is used in this disclosure, both microcantilevers and
nanocantilevers are meant. Furthermore, even "macrocantilevers" of area
up to several square centimeters could be used as well, as long as the
spring constant is kept in the range of roughly about 0.05 N/m to 0.5
N/m.
BRIEF DESCRIPTION OF THE DRAWINGS
[0015] FIG. 1 is a schematic diagram of a prior art detection method for
explosives.
[0016] FIG. 2 is a schematic diagram of a two-track cantilever according
to this invention.
[0017] FIG. 3 is a schematic diagram of the electronic circuit of this
invention.
[0018] FIG. 4 is a plot sensor output vs. time during a detection cycle.
DETAILED DESCRIPTION OF THE INVENTION
[0019] We have developed a method for identifying explosives such as TNT,
PETN, nitroglycerin and RDX which is portable (hand held) and
self-contained using a proprietary probe and a personal computer or
personal assistant (PDA).
[0020] The inventors previously reported that PETN and RDX could be
detected using coated cantilevers heated by a piezoresistive track and
detected optically using a laser diode and a photodetector. FIG. 1 from
U.S. Pat. No. 5,918,263 illustrates the system. Such a system requires
coating the cantilever and the optical detection system is more suitable
for a laboratory than for use in the field searching luggage in airports
and for land mines in former battlefield areas. The inventors have
reported that molecular loading and deflagration on a heated, uncoated
cantilever can be detected using the optical detection system.
[Pinnaduwage et al., Nature (London) 425, 474 (2003); herein incorporated
by reference] and, [Pinnaduwage et al., J. Appl. Phys., 95, 5871; herein
incorporated by reference]. The cantilever had a single piezoresistive
track which was used for heating only.
[0021] It now has been discovered that the optical detector can be
deleted, installation and maintenance simplified, and ruggedness and
reliability improved by use of a novel cantilever having two tracks; one
for heating and one for detection.
[0022] FIG. 2 shows a schematic diagram of the two-track piezoresistive
cantilever according to the invention. The cantilever 1 has a first major
surface 3 and a second major surface (not shown). A first piezoresistive
track 5 detects movement in the cantilever. A second piezoresistive track
7 disposed substantially around the periphery of the cantilever serves as
the heating element.
[0023] Cantilevers are typically formed from silicon or silicon nitride.
The most commonly used dopant to form the piezoresistive channel is
boron. Other dopants, both p- and n-type, may be employed. The width of
the channel is approximately 4 micrometers and the resistance
approximately 2 to 2.5 kohms. This allows the cantilever to be heated to
approximately 500.degree. C., using a 10 V, 10 ms voltage pulse
(corresponding to a current of ca. 5 mA).
[0024] FIG. 3 is a schematic of the measurement scheme with a two-track
piezoresistive microcantilever. A voltage pulse is applied to the outer
track 7 to heat the microcantilever and thereby to deflagrate the
deposited explosive material. The first track 5 is connected to a
Wheatstone bridge circuit so that the change in resistance can be
monitored simultaneously with the application of the voltage pulse to the
outer track 7.
[0025] When the reaction of the analyte is an exothermic event, the
microcantilever senses the change of its resistance due to two factors;
1) temperature change arising from the heat generated by the deflagration
event; and 2) change in cantilever bending arising from the heat
generated. In the first case, the heat released by the deflagration event
of the explosives increases the cantilever temperature. Since the
resistance of the cantilever is related with its temperature, the heat
from the deflagration even will cause the change of cantilever
resistance. Also, the temperature change results in the bending of the
cantilever, presumably due to the bi-material thermal expansion.
Therefore, the resistance of the cantilever changes more due to the
piezoresistive effect.
[0026] Mass loading can be determined by monitoring the resonance
frequency of the cantilever before and after exposure to the explosive
vapor. This is accomplished by driving the cantilever with a signal of
constant amplitude but variable frequency in the region of the resonance
frequency of the cantilever. The bending signal is maximized when the
driving signal approaches the resonance frequency of the cantilever.
[0027] Referring to FIG. 4, a five-event TNT detection test is graphically
presented using the self-sensing platform illustrated in FIG. 1. During
event 1, before loading with TNT a reference voltage pulse (25 volts) is
applied to the piezoresistive heater causing a temporary upward spike in
circuit output that is due to heating. TNT loading (event 2) causes a
gradual upward shift in sensor output which then gradually decreases when
the TNT begins to desorb from the cantilever (event 3). The second pulse
(5 volts) during desorption does not raise the cantilever temperature
sufficiently for deflagration (event 4). The third pulse (25 volts)
causes deflagration as shown by a visible smoke plume, and a dramatic
mass decrease, which is verified by a reduction in circuit output (event
5) that overwhelms the upward thermal signal evident in event 1.
Post-deflagration reference pulses of 25 volts resulted in spikes similar
to the one seen in event 1.
[0028] The occurrence of deflagration was inferred from three consistent
observations. First, the cantilever returns to its pre-test resonance
frequency after deflagration, suggesting that all of the adsorbed
material has been lost. Second, a specific voltage (corresponding to a
threshold or deflagration point temperature) is necessary to cause
deflagration. Third, the measurement of heat added to the cantilever
during deflagration shows that the reaction is exothermic ruling out
other possible reactions such as melting, vaporization or decomposition.
[0029] Our method currently detects the deflagration of approximately 70
picograms (1.9.times.10.sup.11 molecules) or less of TNT (calculated from
the shift in cantilever resonance). This limit of detection is the same
as that of an improved version of the ion-mobility mass-spectrometry
technology now used for airport security. Calculations show that the
detection limit could be improved by up to three orders of magnitude by
using optimized cantilevers.
INDUSTRIAL UTILITY
[0030] The detection system and device of this invention is useful in the
inspection of facilities in which valuable property may be kept on in
which people may assemble. Particular value is seen in the mass
transportation industry due to specificity, ease of use and portability.
[0031] The sensor device of the invention can be used by security
personnel to screen for plastic explosives in all transportation
facilities.
[0032] The invention has been described in terms of specific embodiments
which are indicative of a broad utility but are not limitations to the
scope of the invention. Additions and modifications apparent to those
with skill in the art are included within the scope and spirit of the
invention.
* * * * *
