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Techniques for Determining PSD of PM: Laser Diffraction vs. Electrical Sensing Zone A 242nd ACS National Meeting Presentation: Paper ID18440 Z. Cao1, M. Buser2, D. Whitelock3, L. Wang-Li*1, Y. Zhang4, C.B. Parnell5 1NCSU, 2OSU, 3USDA-ARS, 4UIUC, 5TAMU Introduction: • PM – NAAQS: PM10 & PM2.5 • Health effects, Source identification/estimation, Mitigation strategies – PM characteristics: Physical properties Mass, or number concentrations Particle size distribution (PSD) Morphology Density, etc. Chemical compositions Biological properties Introduction: • Various techniques for PSD measurement (analysis) Aerodynamic method (APS, Impactors, etc) Optical method (optical counters, light scattering analyzers, etc) Electrical sensing zone method (Coulter Counter) Electrical mobility and condensation method (DMA+CNC) Electron microscopy • No single agreed upon method – for different sources Aerodynamic Method for PSD Analysis: Aerodynamic Particle Sizer (APS) • Aerosol entering the tube is assumed to be uniform • Dilution system - reduce problems with particle coincidence in the sensor • Light scattered - changes rapidly with dp: small particle processor : AED 0.5 – 15.9 mm large particle processor: AED 5 – 30 mm • Monodisperse latex spheres are used for calibration of full size range of the APS • Not work for PSD on sampler filter • Field real-time measurement Ch5.8: pages 136-138 of Hinds Aerodynamic Method for PSD Analysis: Impactors • On-site measurements in mass concentration and PSD • Limited size ranges • Particle bounce • Particle losses Optical Method for PSD Analysis: Optical Particle Counters http://en.wikipedia.org/wiki/Particle_counter • Detect and counts one particle at a time • Calibration? http://www.particlecounters.org/optical/ • High level PM environment? Optical Method for PSD Analysis: LS13 320 Multi-wave Length Laser Diffraction Particle Size Analyzer (0.04 – 2000 mm) Polarization Intensity Differential Scattering (PIDS) Rayleigh Scattering Theory Mie Scattering theory (Source: Beckman Coulter, Miami, FL) Optical Method for PSD Analysis: LA-300 Laser Scattering Particle Size Analyzer Fraunhofer Diffraction and LA-300 (Source: Horiba Instrument Inc, Irvine, CA) Electrical Sensing Zone Method for PSD Analysis: Coulter Counter Multisizer • Only suitable for insoluble particles • Not an onsite measurement • Ultrasonic bath – all particles are fully dispersed in the liquid solution (PM on filter) Source: Beckman Coulter, Miami, FL • Current through the orifice • Particle electrical resistance ~ dp • Change in current ~ dp • Size calibrated with polystyrene spheres of known size • Counting rate – 3000 particles/s Electrical Mobility Method for PSD Analysis: Differential Mobility Analyzer (DMA) • Used as a monodisper aerosol generator to produce sub-micrometer-sized aerosols for testing and calibration • Measure PSD in the sub-micrometer size range Condensation Nucleus Counter (CNC) • Particles with greater mobility migrate to the center rod • Exiting aerosol – slightly charged and nearly monodisperse –size controlled by the voltage on the central rod • 0.005 – 1.0 mm Ch15.9 of Hinds Electron Microscopy Method for PSD Analysis: Electron Scanning Microscopy (ESM) Fly-ash Corn Starch Objectives: • Differences in PSD measurements for PM with MMDs in micrometers (agricultural sources) Light scattering method Electrical sensing zone method • PM sample types • Filter-based PM samples with MMD>>10 mm • Testing aerosols with MMD ~ 10 mm Materials & Methods PSD Analyzers LS13 320 multi-wave length laser diffraction particle size analyzer - NCSU LA-300 laser scattering particle size analyzer – UIUC Coulter Counter Multisizer3 – TAMU Coulter Counter Multisizer3 – USDA LS230 laser diffraction particle size analyzer – USDA Materials & Methods PM Field Sampling – Low-volume TSP Samplers High-rise Layer House (a) (b) (c) (d) Materials & Methods • Field PM samples: filter-based 26 samples/season for two seasons: distributed to the three locations Analyzed under the same operation procedure • Testing materials: not filter-based aerosols Limestone Starch No.3 Micro Aluminum No.5 Micro Aluminum Materials & Methods PM Sample Assignment/Distribution PM Samples NCSU LS13 320 UIUC LA-300 TAMU CCM3 USDA CCM3 Winter PM samples Spring PM samples Testing aerosols Winter PM samples LS230 Spring PM samples Testing aerosols Materials & Methods • PM10 and PM2.5 mass fraction analyses Measured by the analyzer Calculated using the lognormal distribution equation Checked for agreements (Relative Difference, %) Measured Lognormal RD 100% Measured Measured = PM10 or PM2.5 measured by the analyzer Lognormal = PM10 or PM2.5 calculated using the lognormal distribution equation Results & Discussion Measured MMDs (mm) for Winter Samples: N=26 LS13 320 17.13±0.81 LA-300 22.71±1.43 CCM3 13.94±1.00 Results & Discussion Measured GSDs for Winter Samples: N=26 LS13 320 2.63±0.04 LA-300 2.02±0.11 CCM3 1.85±0.04 Results & Discussion Measured MMDs (mm) for Spring Samples: N=26 LS13 320 18.44±1.44 LA-300 22.62±2.68 LS230 18.47±1.38 CCM3 13.99±0.74 Results & Discussion Measured GSDs for Spring Samples: N=26 LS13 320 2.67±0.11 LA-300 1.99±0.15 LS230 2.65±0.22 CCM3 1.84±0.04 Results & Discussion Measured PSDs of Testing Aerosols LS13 320 LA-300 LS230 CCM3 Testing aerosols MMD (µm) GSD MMD (µm) MMD (µm) GSD MMD (µm) GSD Limestone 7.50 3.07 12.29 1.83 8.11 3.15 8.56 1.72 Starch 13.31 1.59 16.78 1.50 14.38 1.55 14.32 1.33 #3 Micro aluminum 5.28 1.98 7.62 1.56 5.37 1.93 5.03 1.42 #5 Micro aluminum 7.09 1.69 8.38 1.49 7.21 1.71 6.31 1.39 GSD Results & Discussion Results & Discussion Results & Discussion PM10 and PM2.5 Mass Fraction Analyses (NCSU) LS13 320 Measured mass fraction (%) Lognormal mass fraction (%) Relative difference (%) PM10 36.16±2.73 34.92±2.71 3.44±0.85 PM2.5 8.40±0.61 3.56±0.66 57.9±5.37 N=52 (26 for Winter, 26 for Spring) Results & Discussion LS13 320 PM10 PM2.5 N=52 26 for Winter 26 for Spring) Results & Discussion PM10 and PM2.5 Mass Fraction Analyses (UIUC) LA-300 Measured mass fraction (%) Lognormal mass fraction (%) Relative difference (%) PM10 20.60±2.53 19.88±2.56 3.34±5.34 PM2.5 4.57±0.64 0.25±0.14 94.46±3.05 N=52 (26 for Winter, 26 for Spring) Results & Discussion LA-300 PM10 PM2.5 N=52 26 for Winter 26 for Spring Results & Discussion PM10 Mass Fraction Analyses (TAMU) CCM3 PM10 Measured mass fraction (%) Lognormal mass fraction (%) Relative difference (%) 41.75±3.74 40.76±4.19 2.46±2.06 N= 26 for Winter Results & Discussion TAMU-CCM3 (N=26) Results & Discussion PM10 and PM2.5 Mass Fraction Analyses (USDA) PM10 Measured mass fraction (%) Lognormal mass fraction (%) Relative difference (%) 33.71±3.29 33.39±2.99 0.79±4.45 LS230 PM2.5 8.18±0.96 3.28±1.06 60.44±11.53 PM10 41.11±3.68 40.93±3.50 0.39±0.80 0.65±0.26 54.96±13.04 CCM3 PM2.5 1.43±0.35 N= 26 for Spring Results & Discussion LS230 PM10 PM2.5 N=26 for Spring Results & Discussion CCM3 PM10 PM2.5 N=26 for Spring Conclusions • Different analyzers: significant differences in MMDs and GSDs for filter-based samples LA-300: the largest MMDs; CCM3: the smallest MMD LS13 320: the largest GSDs; CCM3: the smallest • The PSD results of testing aerosols - consistent with that of filter-based samples LA-300: large MMDs LS13 320 & LS230: large GSD • PSDs measured by LS13 320 & LS230 agreed well Conclusions • All RDs in PM10 mass fractions of the measured and the fitting values < 5%, which is acceptable • All RDs in PM2.5 mass fractions of the measured and the fitting values >> 5%, which is not acceptable. Acknowledgement • The USDA NRI Grant No. 2008-35112-18757 • Help from Qianfeng Li & Zifei Liu for field sampling • Support from the egg production farm