Optical-Feedback Cavity Ring-Down Spectroscopy Measurements of Extinction by Aerosol Particles

Butler, T.; Mellon, Daniel; Kim, Jin; Litman, Jessica; Orr-Ewing, Andrew J.

doi:10.1021/jp810310b

Cited by 43 publications

(47 citation statements)

References 40 publications

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“…A detailed introduction to the CRD technique for aerosol extinction measurement is given by Strawa et al (2003), whereas Moosmüller et al (2005) provide an overview over the various CRD and cavity-enhanced detection approaches. Driven by a rapid technology development, CRD instruments are now available as multi-wavelength systems for atmospheric measurements (Schmid et al, 2006;Baynard et al, 2007;Atkinson et al, 2010) and laboratory studies Butler et al, 2009;Cross et al, 2010).…”

Section: A Petzold Et Al: Intercomparison Of a Caps Pmex Monitormentioning

confidence: 99%

Intercomparison of a Cavity Attenuated Phase Shift-based extinction monitor (CAPS PMex) with an integrating nephelometer and a filter-based absorption monitor

et al. 2013

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Abstract. An evaluation of the Cavity Attenuated Phase Shift particle light extinction monitor (CAPS PMex) using a combination of a 3-wavelength Integrating Nephelometer (NEPH) and a 3-wavelength filter-based Particle Soot Absorption Photometer (PSAP) was carried out using both laboratory-generated test particles and ambient aerosols. An accurate determination of a fixed pathlength correction for the CAPS PMex was made by comparing extinction measurements using monodisperse PSL spheres in combination with Mie scattering calculations to account for the presence of PSL conglomerates. These studies yielded a linear instrument response over the investigated dynamical range from 20 to 450 Mm−1 (10−6 m−1) with a linear correlation coefficient of R2 > 0.98. The adjustment factor was determined to be 1.05 times that previously reported. Correlating CAPS extinction to extinction measured by the NEPH + PSAP combination using laboratory-generated polydisperse mixtures of purely scattering ammonium sulfate and highly absorbing black carbon provided a linear regression line with slope m = 1.00 (R2 = 0.994) for single-scattering albedo values (λ = 630 nm) ranging from 0.35 (black carbon) to 1.00 (ammonium sulfate). For ambient aerosol, light extinction measured by CAPS was highly correlated (R2 = 0.995) to extinction measured by the NEPH + PSAP combination with slope m = 0.95.

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Section: A Petzold Et Al: Intercomparison Of a Caps Pmex Monitormentioning

confidence: 99%

Intercomparison of a Cavity Attenuated Phase Shift-based extinction monitor (CAPS PMex) with an integrating nephelometer and a filter-based absorption monitor

et al. 2013

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“…The error in τ is somewhat more complex to evaluate, as the time between successive laser shots at 1 kHz is insufficient for particles to redistribute themselves throughout the laser beam. Under these conditions, successive τ measurements are correlated and therefore Poisson statistics are not directly applicable (Butler et al 2009). Indeed, evaluating the error in τ from the 1-s standard error of the mean of 1000 laser shots (as for τ 0 ) would significantly underestimate the true degree of uncertainty.…”

Section: Precisionmentioning

confidence: 99%

Aircraft Instrument for Comprehensive Characterization of Aerosol Optical Properties, Part I: Wavelength-Dependent Optical Extinction and Its Relative Humidity Dependence Measured Using Cavity Ringdown Spectroscopy

Langridge

Richardson

Lack

et al. 2011

Aerosol Science and Technology

104

117

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High-quality in situ observations of aerosol particle optical properties, namely extinction, scattering, and absorption, provide important information needed to constrain the role of aerosols in the climate system. This paper outlines the design and performance of an aircraft instrument utilizing cavity ringdown spectroscopy for the measurement of aerosol extinction. The 8-channel cavity ringdown spectrometer measures extinction at multiple wavelengths (405, 532, and 662 nm) and at multiple relative humidities (e.g., 10%, 70%, and 95%). Key performance characteristics include a 1-s detection limit better than 0.1 Mm −1 , accuracy of <2% for dry aerosol measurements, and a 1-s precision better than 40% for extinction levels of >10 Mm −1 . Laboratory and field data demonstrate that the 1-s precision is limited by the statistics of aerosol particles in the laser beam rather than the precision of the extinction measurement per se. The measurement precision improves with averaging to 5% at 60 s for extinction levels of >10 Mm

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“…Several different methods of drying have been reported in the cavity ring down literature to date, including mixing of the aerosol flow with large volumes of dry air (Radney et al 2009), use of Nafion dryers (Butler et al 2009;Miles et al 2010aMiles et al , 2010b or those containing molecular sieves, activated alumina or silica gel crystals (Baynard et al 2006;Bulatov et al 2006;Garland et al 2007;Riziq et al 2007;Spindler et al 2007;Riziq et al 2008;Thompson et al 2008;Adler et al 2010), or a combination of several of the above (Freedman et al 2009;Khalizov et al 2009;Xue et al 2009;Beaver et al 2010). The absorption crosssection of water at λ = 560 nm is very low (∼5 × 10 −27 cm 2 molec −1 (HITRAN)); thus, the effect of any residual solvent in our study is likely to be minimal; for τ 0 = 14 µs, a relative humidity of 50% at 20…”

Section: Intra-cavity Absorption By Nebulization Solventmentioning

confidence: 99%

“…By measuring the extinction coefficient b ext as a function of particle number density N for size-selected particles of known diameter, the size-dependent values of the particle extinction efficiency can be extracted from the experimental data. Measuring the value of Q ext at a range of particle radii, r, or size parameter (x = 2π r/λ) allows the complex refractive index of the aerosol to be determined through comparison with theoretical Q ext values calculated from Mie theory Dinar et al 2008;Riziq et al 2008;Butler et al 2009;Freedman et al 2009;Lang-Yona et al 2009Adler et al 2010;Hasenkopf et al 2010;Miles et al 2010aMiles et al , 2010b. This approach relies critically on knowing the size distribution of particles within the cavity, their morphology, and their number density.…”

Section: Introductionmentioning

confidence: 99%

“…A-CRDS is now routinely used in laboratory (Sappey et al 1998;Vander Wal and Ticich 1999;Smith and Atkinson 2001;Bulatov et al 2002Bulatov et al , 2003Bulatov et al , 2006Strawa et al 2003;Pettersson et al 2004;Baynard et al 2006;Garland et al 2007;Riziq et al 2007;Rudić et al 2007;Dinar et al 2008;Riziq et al 2008;Butler et al 2009;Freedman et al 2009;Khalizov et al 2009;Lang-Yona et al 2009Radney et al 2009;Xue et al 2009;Adler et al 2010;Hasenkopf et al 2010;Miles et al 2010aMiles et al , 2010b and field studies (Thompson et al 2002(Thompson et al , 2003Strawa et al 2006;Garland et al 2008;Nakayama et al 2010) to measure extinction by both aerosol ensembles (Vander Wal and Ticich 1999;Thompson et al 2002Thompson et al , 2003Thompson et al , 2008Strawa et al 2003;Pettersson et al 2004;Baynard et al 2006Baynard et al , 2007Garland et al 2007;Riziq et al 2007;Beaver et al 2008;…”

Section: Introductionmentioning

confidence: 99%

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Sources of Error and Uncertainty in the Use of Cavity Ring Down Spectroscopy to Measure Aerosol Optical Properties

Miles

Rudić

Orr-Ewing

et al. 2011

Aerosol Science and Technology

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The use of cavity ring down spectroscopy to retrieve aerosol complex refractive index from optical property measurements has seen increasing popularity over the past few years. However, few studies have looked at the limit which sources of error and uncertainty inherent in the cavity ring down method place on the accuracy with which the refractive index can be retrieved. In this paper, we consider both experimental sources of error and those which compromise the theoretical models against which measurements are compared, both reviewing previously published work and presenting new data. Our results show that for absolute measurements made using single-cavity instruments, factors such as uncertainty in the length of the ring down cavity occupied by aerosol and the counting efficiency of the CPC can introduce an error of ∼2.5% into the real part of the refractive index retrieved from experiment. This is significantly higher than the typical 1% error quoted in previously published work. We note that due to the dependence of particle extinction efficiency on diameter, the effect of a given error on measurements for different particle sizes is not constant.

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Optical-Feedback Cavity Ring-Down Spectroscopy Measurements of Extinction by Aerosol Particles

Cited by 43 publications

References 40 publications

Intercomparison of a Cavity Attenuated Phase Shift-based extinction monitor (CAPS PMex) with an integrating nephelometer and a filter-based absorption monitor

Intercomparison of a Cavity Attenuated Phase Shift-based extinction monitor (CAPS PMex) with an integrating nephelometer and a filter-based absorption monitor

Aircraft Instrument for Comprehensive Characterization of Aerosol Optical Properties, Part I: Wavelength-Dependent Optical Extinction and Its Relative Humidity Dependence Measured Using Cavity Ringdown Spectroscopy

Sources of Error and Uncertainty in the Use of Cavity Ring Down Spectroscopy to Measure Aerosol Optical Properties

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