Analysis of a Suspect Explosive Component:
Hydrogen Peroxide in Hair Coloring Developer
Edward G. Bartick
Research Chemist
Rena A. Merrill
Chemist
Forensic Science Research Unit
Federal Bureau of Investigation
Quantico, Virginia
Kelly H. Mount
Examiner
Explosives Unit
Federal Bureau of Investigation
Washington, DC
Introduction.......Experimental.......Results
and Discussion
Conclusion.......References
Introduction
The objective of this article is to demonstrate
the approach used for the analysis of a suspect explosive component
submitted as case evidence. Samples of evidence taken from the
home of a suspect who was under suspicion for producing bombs
were submitted to the FBI Laboratory. The evidence included two
five-ounce cans labeled citric acid, five tubes labeled hexamine,
an empty one-pint bottle labeled Welloxide® liquid stabilizer
developer, and a small vial containing a portion of the liquid
originally in the Welloxide® bottle. Welloxide® is a
hair coloring developer that contains hydrogen peroxide (H2O2)
to oxidize hair in the coloring process. The extremely unstable
explosive material, hexamethylenetriperoxidediamine (HMTD), can
be produced by combining 45 g of 30% hydrogen peroxide, 14 g
of hexamine, and 21 g of powdered citric acid (Urbanski 1985).
To demonstrate, in this case, that all the required components
to prepare HMTD were present, it was necessary to verify the
contents of the containers as labeled. This article specifically
concerns the analysis of the Welloxide® liquid developer
to determine if there was sufficient H2O2
to produce HMTD. Analysis schemes to identify HMTD explosive
have been reported (Reutter et al.1983; Zitrin et al. 1983),
but in this case it was necessary to identify each precursor.
Because peroxides are highly corrosive, care was taken to use
a method that would not damage instruments during the chemical
analysis. Infrared (IR) and Raman spectrometry techniques were
chosen for the analysis because both offer safe sampling methods.
Forensic IR analysis is a well-established
method (Bartick and Tungol 1993; Suzuki 1993), and Raman spectroscopy
is an emerging method in forensic analysis. Using an attenuated
total reflectance (ATR) accessory with a horizontal internal
reflection element (IRE) is a convenient IR analysis technique
for liquid and solid samples (Harrick et al. 1992). Liquid samples
can be deposited on the IRE for direct analysis with no sample
preparation. Raman spectroscopy, however, has the advantage over
IR in that samples can be analyzed directly through glass vials
and in water without interference from water absorption. Raman
spectral bands result from scattered energy caused by an electron
dipole moment (polarization) that produces a shift from an excitation
laser frequency (Colthup et al. 1990). Raman peaks are usually
plotted as intensity versus wavenumber shift (cm-1).
IR peaks result from an absorption of energy caused by molecular
dipole moment vibrations and are plotted as intensity versus
frequency in wavenumbers (cm-1). Raman and IR are
considered complimentary methods but are frequently used independently.
By using both of these methods, more chemical structural information
can be obtained.
In 1928 C. V. Raman of India discovered the
Raman effect, and in 1930 he was awarded the Nobel Prize for
his discovery. Until recently, Raman spectroscopy has not been
used widely outside of research laboratories. It was difficult
to perform Raman analysis because the instrumentation was very
complex, poor response was obtained, and samples fluoresced when
subjected to the excitation source. When samples fluoresce, the
spectral features are often washed out. Fluorescence often masked
the Raman signal and yielded poor or no spectral information.
Recent developments in Raman instrumentation, including dispersive
and Fourier transform (FT) instruments, have reduced these problems.
Advances include improved excitation lasers, holographic notch
filters, monochromators, fiber-optic sampling probes, and charge-coupled-device
(CCD) detectors (Chase 1994). Current Raman spectrographs have
become fast and easy to use with far fewer difficulties than
earlier instruments, and as a result, Raman spectrometry has
gained new interest in research, industry, and forensic science
for routine analysis. Particular interest has developed with
forensic and law enforcement personnel because of the potential
to analyze unopened containers of possibly hazardous samples
both in the laboratory and with portable instruments in the field.
Experimental
IR analysis was conducted on a Model 710 Fourier
transform infrared (FT-IR) spectrometer (Nicolet Instruments,
Madison, Wisconsin). An ACS grade 50.0% wt./vol. H2O2
reference standard in water was analyzed using an ATR accessory
(Spectra-Tech, Shelton, Connecticut) with a horizontally placed
zinc selenide IRE. Approximately 5 ml of the standard was pipetted
onto the IRE to fill the trough. To obtain IR spectra of H2O2
and water, 128 scans were made at 4 cm-1 resolution
within the range of 4000–700 cm-1. A Model 2000
Microscope System (Renishaw, Gloucestershire, United Kingdom)
with a 781-nm Renishaw diode laser was used for the Raman analysis.
A macro sampling device was mounted on the microscope stage,
and a 5× power, right-angle objective was used to focus
on the samples in glass vials. Standards of H2O2
were prepared starting at 50.0% and diluted within a range to
3.0% wt./vol. A continuous grating scan was used from 3000–200
cm-1 with an exposure time of 60 seconds at 100% laser
power. The instrument frequency calibration fell within range
of the ASTM E1840-96 guideline using a napthalene standard. The
standards were analyzed three times each, and calibration plots
were prepared based on peak height and area. Three analyses were
conducted on Welloxide® liquid developer that had been placed
in a glass vial in the same manner as the standards.
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Results and Discussion
The IR spectrum of the 50.0% reference standard
is shown in Figure 1A. The band of greatest significance to identify
H2O2, the O–O stretching at 876 cm-1
(Bellamy 1975), is not observable in the standard spectrum. The
major broad bands near 3300 and 1640 cm-1 are from
the water O–H stretching and bending, respectively. The
small broad band near 1400 cm-1 results from the O–H
bending of the H2O2, but the assignment
for the band near 2820 cm-1 is unknown. In an attempt
to remove the large water contributions, a water blank was scanned
and is shown in Figure 1B. This spectrum was subtracted from
the H2O2 spectrum in Figure 1A, and the
resulting spectrum is shown in Figure 1C. The H2O2
indicating peak near 876 cm-1, from the O–O stretching
vibration is small but observable after the subtraction. A large
peak is not expected in the IR because the symmetrical shape
of the H2O2 molecule (H–O–O–H)
does not have a significant molecular dipole moment. The small
size of this peak makes it difficult to positively identify H2O2
by IR alone. To obtain a more definitive spectrum of H2O2,
the 50.0% H2O2 standard was scanned using
Raman spectroscopy. Figure
2 shows the standard spectrum obtained while
contained in a glass vial. The 876 cm-1 band in the
Raman spectrum is significantly larger than the same band in
the IR spectrum. The spectrum of the Welloxide® liquid developer
under investigation in Figure 2 shows the peak of interest clearly
visible with significantly less intensity. The recorded 876 cm-1
peak of the standard and developer agrees with reported Raman
H2O2 spectra in water (Vasque et al. 1997).
Analysis of the H2O2
standards produced calibration curves with correlation coefficients
of 0.9944 by peak height and 0.9929 by peak area measurement
of the 876 cm-1 band. The standard deviations were
0.49% and 0.77% for height and area respectively. For three measurements,
the average concentration of the liquid developer in question
was 6.70% by height and 6.33% by area measurement. Figures
3 and 4 show the calibration plots for each measurement type.
Figure
5 shows the liquid under investigation with a slightly less peak
intensity than that of the 7.0% standard sample. To produce HMTD,
a 30% H2O2 in water solution is normally
used. However, the age and storage conditions of the H2O2
sample in this particular case were unknown, and the percentage
could be reduced gradually on the basis of these variables.
Conclusion
The components found in the subject's possession,
each with confirmed identification, could be used to produce
HMTD. Raman spectroscopy shows the distinct presence of the hydrogen
peroxide O–O stretching peak at 876 cm-1. The
IR peak is not observable until the water spectrum is subtracted,
and still the peak of interest is weak. The analysis by Raman
spectroscopy is carried out directly through the sample glass
vial, making the analysis of this corrosive substance safe and
rapid. Raman analysis is clearly the method of choice to determine
the concentration of H2O2, and with sufficient
quantity, the Welloxide® liquid stabilizer developer can
be concentrated for use in the production of HMTD.
References
Bartick, E. G. and Tungol, M. W. Infrared
microscopy and its forensic applications. In: Forensic Science
Handbook, Volume III. R. Saferstein, ed. Prentice Hall, Englewood
Cliffs, New Jersey, 1993, pp. 196–252.
Bellamy, L. J. The Infra-red Spectra of
Complex Molecules. Chapman and Hall, London, 1975.
Chase, B. A new generation of Raman instrumentation,
Applied Spectroscopy (1994) 48:14A–18A.
Colthup, N. B., Daly, L. H., and Wiberley,
S. E. Introduction to Infrared and Raman Spectroscopy.
3rd ed., Academic Press, New York, 1990.
Harrick, N. J., Milosevic, M., and Berets,
S. L. New developments in internal reflection spectroscopy—Part
II: The horizon, American Laboratory (1992) June:29–32.
Reutter, D. J., Bender, E. C., and Rudolph,
T. L. Analysis of an unusual explosive: Methods used and conclusions
drawn from two cases. In: Proceedings of the International
Symposium on the Forensic Aspects of Explosives Analysis.
U.S. Government Printing Office, Washington, DC, 1983, pp. 149–158.
Suzuki, E. M. Forensic applications of infrared
spectroscopy. In: Forensic Science Handbook, Volume III.
R. Saferstein, ed. Prentice Hall, Englewood Cliffs, New Jersey,
1993, pp. 71–195.
Urbanski, T. Chemistry and Technology of
Explosives, Volume 3. Pergamon Press, New York, 1985.
Vasque, V., Sombret, B., Huvenne, J. P., Legrand,
P., and Suc, S. Characterization of the O-O peroxide bond by
vibrational spectroscopy, Spectrochemica Acta Part A (1997)
53:55–66.
Zitrin, S., Kraus, S., and Glattstein, B.
Identification of two rare explosives. In: Proceedings of
the International Symposium on the Forensic Aspects of Explosives
Analysis. U.S. Government Printing Office, Washington, DC,
1983, pp.137–141.
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