7
*STTR
Project: Two Dimensional
Chromatography of Atmospheric Aerosols: A
New In‑Situ Instrument—Aerosol
Dynamics, Inc., 935 Grayson Street,
Berkeley, CA
94710-2401; 510-649-9360,
http://www.aerosol.us/
Dr.
Susanne V. Hering, Principal Investigator, Susanne@aerosol.us
Dr.
Susanne V. Hering, Business Official, Susanne@aerosol.us
DOE
Grant No. DE-FG02-05ER86235
Amount:
$749,995
Research
Institution
The
Regents of the University
of California
Berkeley, CA
Organic
matter is a major constituent of airborne particles, comprising 20-50% of their
mass. Identification of its components is critical for tracing sources, e
luc
idating transformation and formation processes,
assessing affects on human health, and assessing affects on global climate.
Therefore, in situ,
high-time-resolution comprehensive measurements of organic aerosol speciation
are required. In previous work, a
Thermal Desorption Aerosol Gas Chromatography (TAG) Mass Spectrometer (MS) was
developed, which provides identification and quantification of organic
constituents at the molecular level, with hourly in
situ measurements. Although many
compounds can be identified with TAG, a significant portion of the material
eluting from the single dimension chromatography column is not separated.
Therefore, this project will improve the chromatographic resolution of
the TAG by using two-dimensional (2D) chromatography, thereby allowing a vastly
increased number of individual organic species in ambient aerosols to be
measured. Phase I successfully
incorporated a 2D chromatography system onto the existing 1D-TAG system. A
considerable improvement in the separation of organic compounds, in both complex
standards and ambient aerosols, was demonstrated. The
2D-TAG was able to separate more than 6 times as many compounds as the 1D-TAG. In
Phase II, a fast mass spectrometry capability will be added to the 2D-TAG, and
the chromatography will be refined to enhance the separation of individual
organic compounds. The complete
2D-TAG-MS system will be tested, along with traditional filter-based methods and
a variety of complementary measurement system.
Commercial
Applications and other Benefits as
described by the awardee: Beyond
the on-line chemical analysis of aerosols for atmospheric research, the
technology should be applicable to drug manufacturing and to the detection of
biological or chemical agents related to homeland defense.