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17 results on '"emission"'

1. Modeling polycyclic aromatic hydrocarbons (PAHs) concentrations from wildfires in California.

Author

Zhu, Shupeng, Wu, Kai, Mac Kinnon, Michael, Wu, Jun, and Samuelsen, Scott

Subjects
*WILDFIRES, *CALIFORNIA wildfires, *POLYCYCLIC aromatic hydrocarbons, *WILDFIRE prevention, *AIR pollutants, *BIOMASS burning, *VEGETATION mapping, *PARTICULATE matter
Abstract

• Wildfires contribute 92 % of Naphthalene, 82 % of PM_PAH emissions in study period. • Model performance improved for PM2.5 and PAHs prediction with proposed method. • PM_PAH impacts broader areas, while naphthalene's effect is localized to fire zones. • In fire season, 32 % (particles) and 10 % (gas) of PAH exposure linked to wildfires. In recent years, wildfires in California have increased in frequency and intensity due to climate change and prolonged drought. The air pollutants released by wildfires cause significant health consequences, among which polycyclic aromatic hydrocarbons (PAHs) are particularly toxic. Estimating PAH emissions from wildfires is challenging due to variability in vegetation types. In this study, we estimate PAH emission rates across California at a high resolution, based on laboratory-measured PAH emission rates from 22 different vegetation types and detailed vegetation mapping. By combining these estimates with biomass burning data from the NCAR Fire Inventory, the Community Multiscale Air Quality Modeling System simulates PAH concentrations for the 2017 fire season. The modeling results compare favorably to measurements from three PAH monitoring sites in California. The peak PAH emissions from wildfire events are up to be 80 times higher in the gas phase and 32 times higher in the particle phase compared to a case without fire emissions. The population-weighted PAH concentrations from the fire case (0.053 µg/m3) are 47 % higher compared to a non-fire case (0.036 µg/m3) in the particle phase and 11 % higher in the gas phase (9.82 ppt compared to 8.83 ppt) during the study period. While highly depended on the meteorological condition, the simulated spatial distribution indicates that gas-phase PAHs are less likely to travel long distances from the fire source and are prone to aging into the particle phase during transport. Consequently, populations are more likely to be exposed to particle-phase PAHs during wildfire events. This finding has important implications for understanding the health impacts of wildfire-induced PAH concentrations, as particle-phase PAHs may have different toxicological effects compared to gas-phase PAHs. [ABSTRACT FROM AUTHOR]

Published
2024
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3. AMMONIA MEASUREMENTS AND EMISSIONS FROM A CALIFORNIA DAIRY USING POINT AND REMOTE SENSORS.

Author

Moore, K. D., Young, E., Gurell, C., Wojcik, M. D., Martin, R. S., Bingham, G. E., Pfeiffer, R. L., Prueger, J. H., and Hatfield, J. L.

Subjects
*AMMONIA, *EMISSIONS (Air pollution), *TRACE gases, *LIVESTOCK, *DAIRY industry
Abstract

Ammonia (NH3) is an important trace gas species in the atmosphere that can have negative impacts on human, animal, and ecosystem health. Agriculture has been identified as the largest source of NH3, specifically livestock operations. NH3 emissions from a commercial dairy in California were investigated during June 2008. Cattle were held in open-lot pens, except for young calves in hutches with shelters. Solid manure was stored in the open-lot pens. Liquid manure from feed lanes was passed through a solids settling basin and stored in a holding pond. Passive sensors and open-path Fourier transform infrared spectrometers (OP-FTIR) were deployed around the facility to measure NH3 concentrations. Emissions from pens and the liquid manure system (LMS) were estimated using inverse modeling. Mean emission factors (EFs) for the entire facility were 140.5 ±42.5 g d-1 animal-1 from the passive sampler data and 199.2 ±22.0 g d-1 animal-1 from the OP-FTIR data, resulting in the facility's summer emissions calculated at 265.2 ±80.2 kg d-1 and 375.4 ±27.1 kg d-1, respectively. These EFs are within the range of values reported in the literature. Both concentrations and emissions exhibited a strong diurnal cycle, peaking in the late afternoon. Total facility emissions exhibited significant positive correlations with temperature and wind speed. The findings of this study show that NH3 emissions from a commercial dairy can vary by a factor of 10 or more throughout the day, and EFs can vary by two orders of magnitude when compared to other U.S. dairies, based on literature values. [ABSTRACT FROM AUTHOR]

Published
2014
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4. Full Closure or Partial Closure? Evaluation of Construction Plans for the I-5 Closure in Downtown Sacramento.

Author

Qian, Zhen (Sean) and Michael Zhang, H.

Subjects
*ROAD closures, *ROAD work zones, *NETWORK analysis (Planning), *ENERGY consumption, *TRAFFIC flow
Abstract

Three alternative construction plans with full highway closures and limited capacity closures (partial closures) are evaluated for a large-scale freeway reconstruction project in the Sacramento metropolitan area. By using a dynamic network analysis tool, the potential impact resulting from different construction plans is estimated and analyzed measured by changes in total demand, travel delays, vehicle miles/hours traveled (VMT/VHT), fuel consumptions, and emissions. The results show that, for this Interstate 5 closure, if only user delay costs are considered, the actual full closure plan is the best. It produces considerably less total system travel delay than the two partial closure plans although it closed more lanes. This plan, however, may induce more VMT than the other two. In fact, the other two partial closure plans produce slightly fewer emissions and consume slightly less fuel. The outcome of which plan comes out on top crucially depends on two other factors, besides the chosen objective: the amount of demand reduction a plan induces and the availability of alternative routes to divert traffic away from the work zone area. Developing efficient demand management measures will be the key to improving the network performance and to reduce the emissions. Moreover, when data are available, construction costs and emissions produced by construction activities should also be included in the evaluations, in addition to the user costs considered in this study. [ABSTRACT FROM AUTHOR]

Published
2013
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5. Size-resolved particle number and volume emission factors for on-road gasoline and diesel motor vehicles

Author

Ban-Weiss, George A., Lunden, Melissa M., Kirchstetter, Thomas W., and Harley, Robert A.

Subjects
*PARTICULATE matter, *PARTICLE size distribution, *EMISSIONS (Air pollution), *DIESEL motor exhaust gas, *GASOLINE, *AIR pollution
Abstract

Abstract: Average particle number concentrations and size distributions from ∼61,000 light-duty (LD) vehicles and ∼2500 medium-duty (MD) and heavy-duty (HD) trucks were measured during the summer of 2006 in a San Francisco Bay area traffic tunnel. One of the traffic bores contained only LD vehicles, and the other contained mixed traffic, allowing pollutants to be apportioned between LD vehicles and diesel trucks. Particle number emission factors (particle diameter ) were found to be (3.9±1.4)×1014 and (3.3±1.3)×1015 #kg−1 fuel burned for LD vehicles and diesel trucks, respectively. Size distribution measurements showed that diesel trucks emitted at least an order of magnitude more particles for all measured sizes per unit mass of fuel burned. The relative importance of LD vehicles as a source of particles increased as decreased. Comparing the results from this study to previous measurements at the same site showed that particle number emission factors have decreased for both LD vehicles and diesel trucks since 1997. Integrating size distributions with a volume weighting showed that diesel trucks emitted 28±11 times more particles by volume (per unit fuel) than LD vehicles, consistent with the diesel/gasoline emission factor ratio for PM2.5 mass measured using gravimetric analysis of Teflon filters, reported in a companion paper. [Copyright &y& Elsevier]

Published
2010
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6. Short-term methane emissions from 2 dairy farms in California estimated by different measurement techniques and US Environmental Protection Agency inventory methodology: A case study.

Author

Arndt C, Leytem AB, Hristov AN, Zavala-Araiza D, Cativiela JP, Conley S, Daube C, Faloona I, and Herndon SC

Subjects
Animal Husbandry, Animals, California, Cattle, Environmental Monitoring standards, Farms, Manure analysis, Seasons, United States, United States Environmental Protection Agency, Air Pollutants analysis, Environmental Monitoring methods, Methane analysis
Abstract

Reported estimates of CH 4 emissions from ruminants and manure management are up to 2 times higher in atmospheric top-down calculations than in bottom-up (BU) inventories. We explored this discrepancy by estimating CH 4 emissions of 2 dairy facilities in California with US Environmental Protection Agency (US EPA) methodology, which is used for BU inventories, and 3 independent measurement techniques: (1) open-path measurements with inverse dispersion modeling (hereafter open-path), (2) vehicle measurements with tracer flux ratio method, and (3) aircraft measurements with the closed-path method. All 3 techniques were used to estimate whole-facility CH 4 emissions during 3 to 6 d per farm in the summer of 2016. In addition, open-path was used to estimate whole-facility CH 4 emissions over 13 to 14 d per farm in the winter of 2017. Our objectives were to (1) compare whole-facility CH 4 measurements utilizing the different measurement techniques, (2) compare whole-facility CH 4 measurements to US EPA inventory methodology estimates, and (3) compare CH 4 emissions between 2 dairies. Whole-facility CH 4 estimates were similar among measurement techniques. No seasonality was detected for CH 4 emissions from animal housing, but CH 4 emissions from liquid manure storage were 3 to 6 times greater during the summer than during the winter measurement periods. The findings confirm previous studies showing that whole-facility CH 4 emissions need to be measured throughout the year to estimate and evaluate annual inventories. Open-path measurements for liquid manure storage emissions were similar to monthly US EPA estimates during the summer, but not during the winter measurement periods. However, the numerical difference was relatively small considering yearly emission estimates. Manure CH 4 emissions contributed 69 to 79% and 26 to 47% of whole-facility CH 4 emissions during the summer and winter measurement periods, respectively. Methane yields from animal housing were similar between farms (on average 20.9 g of CH 4 /kg of dry matter intake), but CH 4 emissions normalized by volatile solids (VS) loading from liquid manure storage (g of CH 4 per day/kg of VS produced by all cattle per day) at 1 dairy were 1.7 and 3.5 times greater than at the other during the summer (234 vs. 137 g of CH 4 /kg of VS) and winter measurement periods (78 vs. 22 g of CH 4 /kg of VS), respectively. We attributed much of this difference to the proportion of manure stored in liquid (anaerobic) form, and suggest that manure management practices that reduce the amount of manure solids stored in liquid form could significantly reduce dairy CH 4 emissions., (The Authors. Published by FASS Inc. and Elsevier Inc. on behalf of the American Dairy Science Association®. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).)

Published
2018
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