Air Quality Impacts from Prescribed Burning Karsten Baumann, Sangil Lee, Mei Zheng, Venus Dookwah, Michael Chang, and Ted Russell Funded in part by DoD/EPA/State P2 Partnership Small Grants Program
Clean Air Act Endangered Species Act The Conflict
Issues on Local to Global Scales In the continental U.S. prescribed burns and forest fires contribute ~37 % to the total direct fine PM emissions of ~1 Mio t per year * * Nizich et al., EPA Report 454/R (NTIS PB ), RTP, NC, 2000 Effects on Health Visibility Air Quality Climate Do prescribed burns reduce the risk of wild fires?
To what extent does prescribed burning impact local and regional air quality? VOCs PM NOx O 3, SOA
Secondary organic aerosol (SOA): Organic compounds, some highly oxygenated, residing in the aerosol phase as a function of atmospheric reactions that occur in either gas or particle phases. SOA formation mainly depends on: Emissions & forming potential of precursors aromatics (BTX, aldehydes, carbonyls) terpenes (mono-, sesqui-) other biogenics (aldehydes, alcohols) Presence of other initiating reactants O 3, OH, NO 3, sunlight, acid catalysts Mechanisms (with half hr to few hr yields): Gas-to-particle conversion/partitioning e.g. terpene oxidation Heterogeneous reactions aldehydes via hydration and polymerization, forming hemiacetal/acetal in presence of alcohols Particle-phase reactions acetal formation catalytically accelerated by particle sulfuric acid (Jang and Kamens, ES&T, 2001)
Biomass Litter Composites MHFF… mixed hardwood (oak) forest foliage FPSP… Florida palmetto & slash pine WGLP… wiregrass & longleaf pine BUT also Primary PM Emissions from Foliar Fuel Combustion Hays, Geron et al., ES&T 36, , 2002
Other Organic Carbon {SOA} 30% Wood Combustion 39% Meat Cooking 6% Vegetative Detritus 2% Gasoline Exhaust 3% Diesel Exhaust 20% Source Contributions to Organic Carbon (OC) in Ambient PM 2.5 Pensacola, FL October 1999 Measured average [PM 2.5 ] = 16.6 g m -3 [OC] = 4.6 g m -3 Zheng et al., ES&T 2002
FAQS Observations: Regional Problem of PM 2.5 Period MAY-OCT NOV-APR
Seasonal Differences in Diurnal Cycles: O 3 & PM 2.5 PM 2.5 Sources Near Columbus Driving Nighttime Averages in Winter 2001/02 WinterSummer
PM 2.5 Eceedance at Columbus-OLC near Fort Benning for SE winds in Winter 2001/02 Despite regional character of PM 2.5, local PM sources on military installations dominant in winter half.
PM 2.5 Exceedances at Columbus-OLC in Oct-Nov 2001
Objectives and Outlook In this initial pilot study, establish understanding of the direct and indirect impact of current burn practices on sub- regional Air Quality. Lay foundation for more comprehensive and better focused Phase II Study to optimize burn practices toward minimum AQ impact. Create results of general applicability for the benefit of LMBs on other military installations in the SE-US and beyond. Learn lessons that help create and implement new revised land management strategies for the benefit of other agencies and institutions that face often times devastating wild fires in other parts of the Nation.
OLC site upgrade Research site at Oxbow Meadows Environmental Learning Center upgraded for PM source apportionment and in situ gas phase sampling 3’ 4’ a/c 11’ 8’ Stair step 4’14’ Guy wired 8m Tower tilt down 10’ Gate 45’ x 40’ Fence N 10’ x 12’ Shelter 4 additional 20 A circuit breakers 33’ x 7’ level Platform ~ 1’ above ground 4 quadruple outlets on individual breakers
OLC Preliminary PM 2.5 Mass & Composition Individual Burn Events and Acres Burned JanuaryMay 2003 No-Burn Background 937 acres 1256 acres 3770 acres4006 acres Burning early in the season seems advantageous
OLC Preliminary PM 2.5 Mass & Composition OM/OC & [O 3 -max] Averages per Burn Event JanuaryMay 2003 Higher PM mass and OM/OC with higher [O 3 ] later in the season
Preliminary Results March 2003 Progressively increasing fine PM mass and organics fraction correlate with increased temperature, solar radiation, and O 3, indicating increased oxidizing potential, hence formation of SOA.
Preliminary VOC Results: March 2 nd Period Carbon Balance (ppb/ppm) Relatively strong emissions of CO, alkenes, aromatics, biogenics, and methyl chloride from burn units during flaming (FLA) stages
Preliminary POC Results: February 2003
Still to do (Pending continued funding) Evaluate regional PM from previous years relative to regional burn activity and precipitation Integrate GFC fire statistics Integrate GFC Forestry Weather & Smoke Management Forecast Data Integrate ECMI met data from Fort Benning Collect one more PCM sample in summer Analyze POC High-Volume samples QA/QC all met, gas and PM data Do source apportionment for select samples Merge all AQ data with fuel data Evaluate fuel-type – AQ relationship Prepare data for model integration Develop strategy for phase II
Acknowledgement Collaborators and Contributors CSU-OLC: Jill Whiting, Jim Trostle, site operators Becky Champion, director, “courier” Ft Benning:Polly Gustafson, EMD, reporting to J Brent Jack Greenlee, LMB, reporting to R Larimore Hugh Westbury, SERDP, contractor, reporting to D Price, US Army, Vicksburg, MS Ft Gordon:Allen Braswell, ENRMO, reporting to S Willard Augusta RP:Shari Mendrick, Col.Cty.Eng.Dept., Evans, GA
For more information Dr. Karsten Baumann (PI) Dr. Mei Zheng Dr. Michael Chang Dr. Ted Russell Find this presentation as DOD-P2 Atlanta in ppt-format at
Supplementary Material
Progressively Increasing PM 2.5 Mass & %-Organics
Gas-phase Emissions from Biomass Burning From laboratory combustion experiments by Lobert et al. [1990], published by Crutzen PJ and MO Andreae, Biomass burning in the tropics: impact on atmospheric chemistry and biogeochemical cycles, Science 250, , CO 2, NO x, SO 2, N 2 O, CH 3 Cl ( not measured ) mainly during flaming, CO, Nitriles (HCN, CH 3 CN), HC mainly during smoldering. Emission ratios (mol/mol) averaged for entire burning process: CO/NO x ~ > 25 CO/SO 2 ~ 200 Lobert JM, DH Scharffe, WM Hao, and PJ Crutzen, Nature 346, , 1990.
Particle Composition Monitor “PCM” Channel 1: NH 3 Na +, K +, NH 4 +, Ca +2 Channel 2: HF, HCl, HONO, HNO 3, SO 2, HCOOH, CH 3 COOH, (COOH) 2 F -, Cl -, NO 3 -, SO 4 =, HCOO -, CH 3 COO -, C 2 O 4 = Channel 3: EC, OC, WSOC, “SVOC” Additional higher resolution CO, NO, NOy, O 3, PM-mass, and basic meteorology
High-Vol Sampling and GC/MS Analyses Quantification of >100 Particle-phase Organic Compounds n-alkanes, branched alkanes, cycloalkanes n-alkanoic acids, n-alkenoic acids alkanedioic acids PAHs, oxy-PAHs retene steranes hopanes resin acids pimaric acid abietic acid sandaracopimaric acid aromatic acids levoglucosan POC
Canister Sampling and GC/FID Detection of Volatile Organic Compounds VOC Collaborating with Prof. Don Blake, UC Irvine, CA C 2 -C 6 n-alkanes, alkenes, branched alkenes, alkynes isoprene Cyclic compounds monoterpenes ( -, -pinene) Aromatics, organic nitrates, halogenated species methylchloride Quantification of >60 compounds, incl. CO 2 for “fire” samples