Juha Nikmo scite author profile

Abstract.We have presented an overview of a mathematical model, BUOYANT, that was originally designed for the evaluation of the dispersion of buoyant plumes originated from major warehouse fires. The model addresses the variations of the cross-plume integrated properties of a buoyant plume in the presence of a vertically varying atmosphere. The model also includes a treatment for a rising buoyant plume interacting with an inversion layer. We have compared the model predictions with the data of two prescribed wild-land fire experiments. For the SCAR-C experiment in Quinault (US) in 1994, the predicted vertical extents of the plume at maximum plume rise were between 500 and 800 m and between 200 and 700 m, using two alternative meteorological data sets. The corresponding observed injection heights of the aerosol particles measured using an airborne lidar (light detection and ranging) ranged from 250 to 600 m. For the prescribed burning experiment in Hyytiälä (Finland) in 2009, the model predictions were compared with plume elevations and diameters, determined based on particulate matter number concentration measurements onboard an aeroplane. However, the agreement between modelled and measured results substantially depends on how the properties of the source term are evaluated, especially regarding the convective heat fluxes from the fire. The results demonstrate that in field experiments on wild-land fires, there are substantial uncertainties in estimating both (i) the source terms for the atmospheric dispersion computations and (ii) the relevant vertical meteorological profiles.

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Evaluation of the CALINE4 and CAR-FMI models against measurements near a major road

Levitin

Härkönen

Kukkonen

et al. 2005

Atmospheric Environment

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The influence of residential wood combustion on the concentrations of PM<sub>2.5</sub> in four Nordic cities

et al. 2020

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Abstract. Residential wood combustion (RWC) is an important contributor to air quality in numerous regions worldwide. This study is the first extensive evaluation of the influence of RWC on ambient air quality in several Nordic cities. We have analysed the emissions and concentrations of PM2.5 in cities within four Nordic countries: in the metropolitan areas of Copenhagen, Oslo, and Helsinki and in the city of Umeå. We have evaluated the emissions for the relevant urban source categories and modelled atmospheric dispersion on regional and urban scales. The emission inventories for RWC were based on local surveys, the amount of wood combusted, combustion technologies and other relevant factors. The accuracy of the predicted concentrations was evaluated based on urban concentration measurements. The predicted annual average concentrations ranged spatially from 4 to 7 µg m−3 (2011), from 6 to 10 µg m−3 (2013), from 4 to more than 13 µg m−3 (2013) and from 9 to more than 13 µg m−3 (2014), in Umeå, Helsinki, Oslo and Copenhagen, respectively. The higher concentrations in Copenhagen were mainly caused by the relatively high regionally and continentally transported background contributions. The annual average fractions of PM2.5 concentrations attributed to RWC within the considered urban regions ranged spatially from 0 % to 15 %, from 0 % to 20 %, from 8 % to 22 % and from 0 % to 60 % in Helsinki, Copenhagen, Umeå and Oslo, respectively. In particular, the contributions of RWC in central Oslo were larger than 40 % as annual averages. In Oslo, wood combustion was used mainly for the heating of larger blocks of flats. In contrast, in Helsinki, RWC was solely used in smaller detached houses. In Copenhagen and Helsinki, the highest fractions occurred outside the city centre in the suburban areas. In Umeå, the highest fractions occurred both in the city centre and its surroundings.

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Evaluation of a road dust suspension model for predicting the concentrations of PM10 in a street canyon

Kauhaniemi

Kukkonen

Härkönen

et al. 2011

Atmospheric Environment

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Dispersion from Strongly Buoyant Sources

Kukkonen

Nikmo

Ramsdale

et al. 2000

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Juha Nikmo

Applicability of an integrated plume rise model for the dispersion from wild-land fires

Evaluation of the CALINE4 and CAR-FMI models against measurements near a major road

The influence of residential wood combustion on the concentrations of PM<sub>2.5</sub> in four Nordic cities

Evaluation of a road dust suspension model for predicting the concentrations of PM10 in a street canyon

Dispersion from Strongly Buoyant Sources

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Resources

About

Juha Nikmo

Applicability of an integrated plume rise model for the dispersion from wild-land fires

Evaluation of the CALINE4 and CAR-FMI models against measurements near a major road

The influence of residential wood combustion on the concentrations of PM&lt;sub&gt;2.5&lt;/sub&gt; in four Nordic cities

Evaluation of a road dust suspension model for predicting the concentrations of PM10 in a street canyon

Dispersion from Strongly Buoyant Sources

Contact Info

Product

Resources

About

The influence of residential wood combustion on the concentrations of PM<sub>2.5</sub> in four Nordic cities