Single-Particle Fluorescence Spectrometer for Ambient Aerosols

A fluorescence particle spectrometer (FPS) for real-time measurement of the fluorescence spectra of aerosol particles in the size range 1-10 w m diameter is reported. The prototype FPS has a sufficiently high sample rate (from 5 to 28 l/min for 3.5 w m to 11 w m diameter particles) to measure aeroso...

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Published in:	Aerosol science and technology Vol. 37; no. 8; pp. 628 - 639
Main Authors:	Pan, Yong Le, Hartings, Justin, Pinnick, Ronald G., Hill, Steven C., Halverson, Justin, Chang, Richard K.
Format:	Journal Article
Language:	English
Published:	Taylor & Francis Group 01-08-2003
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Abstract	A fluorescence particle spectrometer (FPS) for real-time measurement of the fluorescence spectra of aerosol particles in the size range 1-10 w m diameter is reported. The prototype FPS has a sufficiently high sample rate (from 5 to 28 l/min for 3.5 w m to 11 w m diameter particles) to measure aerosol within buildings at practical rates (from 1 up to 600 particle fluorescence spectra per minute). Previously reported bioaerosol prototype detectors for measurement of single particle spectra (Pan et al., Opt. Lett ., 24, 116-118 (1999); Hill et al., Field Anal. Chem. Tech ., 3, 221-239 (1999)) were unable to sample the ambient environment; air containing particles had to be forced under pressure into a sample cell. In addition, sample rates were so small (less than 0.01 l/min) as to be impractical for most applications. The present design overcomes these deficiencies by the use of an airtight cell that highly concentrates micrometer-sized particles. A virtual impactor first concentrates aerosol particles, which are then drawn under negative pressure through an aerodynamic focusing nozzle in the inlet of the instrument, through the sample region, providing further concentration. The rate of particle spectra measured by the FPS increases significantly when the particle inlet is within a few meters of some common sources of indoor biological particles, e.g., a person coughing, sneezing, or rubbing his skin, or the presence of a dog. The spectra obtained have a variety of spectral shapes. The FPS may be useful in a variety of areas, e.g., in studying and monitoring airborne particles that cause diseases or allergies.
AbstractList	A fluorescence particle spectrometer (FPS) for real-time measurement of the fluorescence spectra of aerosol particles in the size range 1-10 w m diameter is reported. The prototype FPS has a sufficiently high sample rate (from 5 to 28 l/min for 3.5 w m to 11 w m diameter particles) to measure aerosol within buildings at practical rates (from 1 up to 600 particle fluorescence spectra per minute). Previously reported bioaerosol prototype detectors for measurement of single particle spectra (Pan et al., Opt. Lett ., 24, 116-118 (1999); Hill et al., Field Anal. Chem. Tech ., 3, 221-239 (1999)) were unable to sample the ambient environment; air containing particles had to be forced under pressure into a sample cell. In addition, sample rates were so small (less than 0.01 l/min) as to be impractical for most applications. The present design overcomes these deficiencies by the use of an airtight cell that highly concentrates micrometer-sized particles. A virtual impactor first concentrates aerosol particles, which are then drawn under negative pressure through an aerodynamic focusing nozzle in the inlet of the instrument, through the sample region, providing further concentration. The rate of particle spectra measured by the FPS increases significantly when the particle inlet is within a few meters of some common sources of indoor biological particles, e.g., a person coughing, sneezing, or rubbing his skin, or the presence of a dog. The spectra obtained have a variety of spectral shapes. The FPS may be useful in a variety of areas, e.g., in studying and monitoring airborne particles that cause diseases or allergies.
Author	Hartings, Justin Chang, Richard K. Pinnick, Ronald G. Hill, Steven C. Pan, Yong Le Halverson, Justin
Author_xml	– sequence: 1 givenname: Yong Le surname: Pan fullname: Pan, Yong Le organization: Department of Applied Physics and Center for Laser Diagnostics , Yale University – sequence: 2 givenname: Justin surname: Hartings fullname: Hartings, Justin organization: U.S. Army Medical Research Institute for Infectious Diseases – sequence: 3 givenname: Ronald G. surname: Pinnick fullname: Pinnick, Ronald G. organization: U.S. Army Research Laboratory – sequence: 4 givenname: Steven C. surname: Hill fullname: Hill, Steven C. organization: U.S. Army Research Laboratory – sequence: 5 givenname: Justin surname: Halverson fullname: Halverson, Justin organization: Westinghouse Savannah River Company – sequence: 6 givenname: Richard K. surname: Chang fullname: Chang, Richard K. organization: Department of Applied Physics and Center for Laser Diagnostics , Yale University
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