Chemical composition of atmospheric nanoparticles formed from nucleation in Tecamac, Mexico: Evidence for an important role for organic species in nanoparticle growth
暂无分享,去创建一个
Timothy M. VanReken | James N. Smith | Peter H. McMurry | Mark R. Stolzenburg | J. Smith | M. Stolzenburg | P. Mcmurry | L. Huey | M. Dunn | Kenjiro Iida | Matthew J. Dunn | L. G. Huey | T. VanReken | J. Smith | M. Dunn | K. Iida | Ken Iida
[1] James N. Smith,et al. Chemical composition of atmospheric nanoparticles during nucleation events in Atlanta , 2005 .
[2] C. Kuang,et al. Dependence of nucleation rates on sulfuric acid vapor concentration in diverse atmospheric locations , 2008 .
[3] Hanna Vehkamäki,et al. New parameterization of sulfuric acid‐ammonia‐water ternary nucleation rates at tropospheric conditions , 2007 .
[4] J. Smith,et al. Growth rates of freshly nucleated atmospheric particles in Atlanta , 2005 .
[5] K. Prather,et al. Formation of aerosol particles from reactions of secondary and tertiary alkylamines: characterization by aerosol time-of-flight mass spectrometry. , 2001, Environmental science & technology.
[6] J. Smith,et al. A criterion for new particle formation in the sulfur-rich Atlanta atmosphere , 2005 .
[7] H. Tammet. Inclined grid mobility analyzer: the plain model , 2002 .
[8] A. Wexler,et al. Ultrafine nitrate particle events in Baltimore observed by real-time single particle mass spectrometry , 2004 .
[9] G. Mann,et al. The contribution of boundary layer nucleation events to total particle concentrations on regional and global scales , 2006 .
[10] S. Solomon. The Physical Science Basis : Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change , 2007 .
[11] J. Smith,et al. Atmospheric Measurements of Sub-20 nm Diameter Particle Chemical Composition by Thermal Desorption Chemical Ionization Mass Spectrometry , 2004 .
[12] K. Lehtinen,et al. Estimating nucleation rates from apparent particle formation rates and vice versa: Revised formulation of the Kerminen–Kulmala equation , 2007 .
[13] J. Smith,et al. Thermal Desorption Chemical Ionization Mass Spectrometer for Ultrafine Particle Chemical Composition , 2003 .
[14] P. Ziemann,et al. Real-Time Chemical Analysis of Organic Aerosols Using a Thermal Desorption Particle Beam Mass Spectrometer , 2000 .
[15] C E Kolb,et al. Guest Editor: Albert Viggiano CHEMICAL AND MICROPHYSICAL CHARACTERIZATION OF AMBIENT AEROSOLS WITH THE AERODYNE AEROSOL MASS SPECTROMETER , 2022 .
[16] T. Petäjä,et al. The contribution of sulfuric acid and non‐volatile compounds on the growth of freshly formed atmospheric aerosols , 2005 .
[17] A. Wexler,et al. A hypothesis for growth of fresh atmospheric nuclei , 2002 .
[18] S. Friedlander. Smoke, Dust, and Haze: Fundamentals of Aerosol Dynamics , 2000 .
[19] Hanna Vehkamäki,et al. Formation and growth rates of ultrafine atmospheric particles: a review of observations , 2004 .
[20] J. Smith,et al. Estimating nanoparticle growth rates from size-dependent charged fractions: Analysis of new particle formation events in Mexico City , 2008 .
[21] Da-Ren Chen,et al. Measurement of Atlanta Aerosol Size Distributions: Observations of Ultrafine Particle Events , 2001 .
[22] P. Mcmurry. New particle formation in the presence of an aerosol: Rates, time scales, and sub-0.01 μm size distributions , 1983 .
[23] O. Edenhofer,et al. Mitigation from a cross-sectoral perspective , 2007 .
[24] J. Peischl,et al. Observations of hydroxyl and the sum of peroxy radicals at Summit, Greenland during summer 2003 , 2007 .
[25] K. Hämeri,et al. Chemical composition of aerosol during particle formation events in boreal forest , 2001 .
[26] A. Wexler,et al. Secondary organics and atmospheric cloud condensation nuclei production , 2000 .
[27] D. Worsnop,et al. Size and composition measurements of background aerosol and new particle growth in a Finnish forest during QUEST 2 using an Aerodyne Aerosol Mass Spectrometer , 2005 .