Technical Note: Sensitivity of 1-D smoke plume rise models to the inclusion of environmental wind drag

Freitas, Saulo R.; Longo, Karla M.; Trentmann, J.; Latham, Don

doi:10.5194/acpd-9-14713-2009

Cited by 22 publications

(35 citation statements)

References 9 publications

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“…One of the most widely used parameterizations is the plume‐rise model developed by Freitas et al [2007], and recently modified to include the effect of horizontal winds [ Freitas et al , 2010]. The plume‐rise model uses a prognostic scheme for simulating plume heights for tropical fires.…”

Section: Introductionmentioning

confidence: 99%

“… Freitas et al [2007]demonstrated, using Atmospheric Infrared Sounder (AIRS) and aircraft observations, that explicitly accounting for fire smoke injection processes significantly improves regional atmospheric model predictions of tropospheric CO across the central Amazon. However, at present, the validation of this plume‐rise model has focused only on three case studies: the Quinault fire described by Trentmann et al [2002] [see also Freitas et al , 2007] and two simulated fires with the 3‐D Active Tracer High Resolution Atmospheric Model (ATHAM) [ Freitas et al , 2010].…”

Section: Introductionmentioning

confidence: 99%

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Space‐based observational constraints for 1‐D fire smoke plume‐rise models

et al. 2012

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[1] We use a plume height climatology derived from space-based Multiangle Imaging Spectroradiometer (MISR) observations to evaluate the performance of a widely used plume-rise model. We initialize the model with assimilated meteorological fields from the NASA Goddard Earth Observing System and estimated fuel moisture content at the location and time of the MISR measurements. Fire properties that drive the plume-rise model are difficult to constrain, and we test the model with four estimates each of active fire area and total heat flux, obtained from Moderate Resolution Imaging Spectroradiometer (MODIS) fire radiative power (FRP) thermal anomalies available for each MISR plume and other empirical data. We demonstrate the degree to which the fire dynamical heat flux (related to active fire area and sensible heat flux) and atmospheric stability structure influence plume rise, although entrainment and possibly other less well constrained factors are also likely to be significant. Using atmospheric stability conditions, MODIS FRP, and MISR plume heights, we find that smoke plumes reaching high altitudes are characterized by higher FRP and weaker atmospheric stability conditions than those at low altitude, which tend to remain confined below the boundary layer, consistent with earlier results. However, over the diversity of conditions studied, the model simulations generally underestimate the plume height dynamic range observed by MISR and do not reliably identify plumes injected into the free troposphere, key information needed for atmospheric models to simulate smoke dispersion. We conclude that embedding in large-scale atmospheric studies an advanced plume-rise model using currently available fire constraints remains a difficult proposition, and we propose a simplified model that crudely constrains plume injection height based on two main physical factors for which some observational constraints often exist. Field experiments aimed at directly measuring fire and smoke plume properties in detail are likely to produce the next major advances in plume-rise modeling.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Space‐based observational constraints for 1‐D fire smoke plume‐rise models

et al. 2012

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“…During SAMBBA campaign, we also detected the presence of similar plumes during the flight B742, classified mostly as FP, with a unique CO mixing ratio value, peaking ~5,000 ppbv at about 600 m. These results demonstrate the strength of vertical transport during a fresh 260 biomass burning event, with the plume injection height up to 2 km. Freitas et al (2006Freitas et al ( , 2007Freitas et al ( , 2010 highlighted the importance of representing the injection height of biomass burning plumes in numerical models to describe the regional smoke distribution. and some forest studies (up to 600 ppbv) conducted by Andreae et al (1988), Kaufman et al (1992) and Yokelson et al (2007).…”

Section: Ambient Distributions Of Co Nox and O3mentioning

confidence: 99%

Biomass burning emissions disturbances on the isoprene oxidation in a tropical forest

Charrua-Santos¹,

Longo²,

Kim³

et al. 2017

Preprint

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Abstract. We present a characterization of the chemical composition of the atmosphere of the Brazilian Amazon rainforest based on trace gases measurements carried out during the South American Biomass Burning Analysis (SAMBBA) airborne experiment in September 2012. We analyzed the observations of primary biomass burning emission tracers, i.e., carbon monoxide (CO) and 20 nitrogen oxides (NOx), ozone (O3), isoprene, and its main oxidation products, methyl vinyl ketone (MVK), methacrolein (MACR), and hydroxyhydroperoxides (ISOPOOH). The focus of SAMBBA was primarily on biomass burning emissions, but there were due to cloud edge effects on photolysis rates, which have a major impact on OH production rates.

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“…PREP-CHEM-SRC integrates emissions inventories and forest fire hotspots onto a specified domain. The biomass burning emissions were estimated using the Brazilian Biomass Burning Emissions Model (3BEM; Longo et al, 2010) and were injected into the atmosphere using the plume rise model described in Freitas et al (2006Freitas et al ( , 2007Freitas et al ( , 2010. The forest fire hotspots database integrated in the model includes a combination of the MODIS fire locations database (U.S.…”

Section: Domain Setup and Data Integrationmentioning

confidence: 99%

Numerical Study of the Transport and Convective Mechanisms of Biomass Burning Haze in South-Southeast Asia

Oozeer

Chan

Ooi

et al. 2016

Aerosol Air Qual. Res.

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This study aims to identify the vertical transport mechanisms that uplifted the forest fire emissions from Sumatra to the upper troposphere during the June 2013 haze crisis. WRF-Chem is used to simulate the formation and transport of biomass-burning haze during the study period of 18 th to 26 th June 2013. The South-Southeast Asian synoptic weather patterns and their effects on the transport of biomass-burning emissions from Sumatra to Peninsular Malaysia were studied computationally to explain the phenomenon. Results show that PM 10 emissions were lifted to 200 hPa height (approximately 12 km) over the Strait of Malacca on 24 th June. The two identified vertical transport mechanisms confirmed a previously conjectured convergence over the Strait of Malacca and orographic lifting over Peninsular Malaysia. These mechanisms were able to uplift the biomass-burning emissions to the upper troposphere and this could have significant long-range transport and global climatic effects.

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Technical Note: Sensitivity of 1-D smoke plume rise models to the inclusion of environmental wind drag

Cited by 22 publications

References 9 publications

Space‐based observational constraints for 1‐D fire smoke plume‐rise models

Space‐based observational constraints for 1‐D fire smoke plume‐rise models

Biomass burning emissions disturbances on the isoprene oxidation in a tropical forest

Numerical Study of the Transport and Convective Mechanisms of Biomass Burning Haze in South-Southeast Asia

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