Improved Formulations for Air-Surface Exchanges Related to National Security Needs: Dry Deposition Models

Droppo, Jasha

doi:10.2172/890729

Cited by 13 publications

(10 citation statements)

References 77 publications

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“…Particle dry deposition, the removal of particles from the atmosphere to the surface in absence of precipitation (Seinfeld and Pandis, 2006), can be divided into several sub-processes, including turbulence diffusion, surface collection and gravitational settling (Droppo, 2006). The inferential method is widely used to estimate particle deposition flux in terms of particle concentration and deposition velocity (or its inverse, the resistance) (Sehmel, 1980;Slinn, 1982;Hicks et al, 1987;Wesely and Hicks, 2000;Raupach et al, 2001;Zhang et al, 2001;Petroff and Zhang, 2010;Seinfeld and Pandis, 2006;Kouznetsov and Sofiev, 2012).…”

Section: Introductionmentioning

confidence: 99%

A new parameterization of particle dry deposition over rough surfaces

Zhang

Shao

2014

Atmos. Chem. Phys.

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Abstract. In existing particle dry deposition schemes, the effects of gravity and surface roughness elements on particle motion are often poorly represented. In this study, we propose a new scheme to overcome such deficiencies. Particle deposition velocity is a function of aerodynamic, surfacecollection and gravitational resistances. In this study, the effect of gravitation settling is treated analytically. More importantly, the new scheme takes into consideration the impacts of roughness elements on turbulent particle diffusion and surface particle collection. A relationship between aerodynamic and surface-collection processes is established by using an analogy between drag partition and depositionflux partition. The scheme is then tested against a windtunnel data set for four different surfaces and a good agreement between the scheme predictions and the observations is found. The sensitivity of the scheme to the input parameters is tested. Important factors which affect particle deposition in different particle size ranges are identified. The scheme shows good capacity for modeling particle deposition over rough surfaces.

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Section: Introductionmentioning

confidence: 99%

A new parameterization of particle dry deposition over rough surfaces

Zhang

Shao

2014

Atmos. Chem. Phys.

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“…Phoretic mechanisms are the result of gradients in the surrounding environment that affect particle motion. Such mechanisms influence the deposition rates of particles small enough to have high ion mobility or to be impacted by molecular collisions (Droppo, 2006). The magnitudes of phoretic forces are small compared to the deposition processes discussed above and are therefore ignored by the majority of dry deposition models 17 .…”

Section: Phoretic Mechanismsmentioning

confidence: 99%

Deposition Velocity Methods For DOE Site Safety Analyses

Sugiyama¹,

Gowardhan²,

Simpson³

et al. 2014

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This report documents the results of an investigation of deposition velocity methods for use in Department of Energy (DOE) Documented Safety Analysis (DSA) modeling. The project was sponsored by the National Nuclear Security Administration (NNSA) Nuclear Safety Research and Development Program and monitored by the Chief of Nuclear Safety (CNS) from the Office of the Under Secretary for Management and Performance. Based on initial scoping discussions, the primary focus of this effort was on the dry deposition of particulate matter. However, within the constraints of the project, we also explored the sensitivity of safety analysis modeling to other key input parameters (wind direction variability, atmospheric stability, release characteristics, model assumptions), examined the 95 th percentile methodology, and investigated a few aspects of a commonly-used DOE safety analysis code, MACCS2 (MELCOR Accident Consequence Code System). viii be usable in site hazard analyses. This model was used to conduct a set of evaluation and sensitivity studies. We then implemented the recommended deposition velocity model into our 95 th percentile software and applied this to two illustrative case studies. KEY RESULTS Key findings from our investigation are summarized below: • Deposition velocity (v d). The Office of Health, Safety, and Security (HSS Safety Bulletin, 2011) currently recommends the use of default deposition velocities of 0.1 cm/s for unmitigated/unfiltered particles with Aerodynamic Equivalent Diameters (AEDs) in the range of 2-4 µm, and 0.01 cm/s for mitigated/filtered releases of particles with AEDs of 0.2-0.4 µm. With a few caveats discussed below, these values were found to be generally appropriate for particulate plume modeling, unlike the previously recommended default values of 1 cm/s and 0.1 cm/s. Related findings are as follows:

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“…The parameterizations about the forest canopy structure of land surface models that are commonly coupled in meteorological or climate simulations are listed in Table 1 [9][10][11][12][13][14][15]. Different parameterization schemes divide the canopy into one layer, two layers or multiple layers to calculate the energy decomposition or radiative transfer in the canopy [16][17][18][19]. For the calculation of the atmospheric dynamic process, the current land surface models that have been widely used in climate and hydrology researches, such as simple biosphere model (SiB4) and biosphere atmosphere transfer scheme (BATS), are based on the measured empirical wind speed profile in the canopy and provide an empirical solution to calculate the turbulent exchange in the canopy [20,21].…”

Section: Introductionmentioning

confidence: 99%

Improvement and Impacts of Forest Canopy Parameters on Noah-MP Land Surface Model from UAV-Based Photogrammetry

Chang

Zhu²,

Cao

et al. 2020

Remote Sensing

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Taking a typical forest’s underlying surface as our research area, in this study, we employed unmanned aerial vehicle (UAV) photogrammetry to explore more accurate canopy parameters including the tree height and canopy radius, which were used to improve the Noah-MP land surface model, which was conducted in the Dinghushan Forest Ecosystem Research Station (CN-Din). While the canopy radius was fitted as a Burr distribution, the canopy height of the CN-Din forest followed a Weibull distribution. Then, the canopy parameter distribution was obtained, and we improved the look-up table values of the Noah-MP land surface model. It was found that the influence on the simulation of the energy fluxes could not be negligible, and the main influence of these canopy parameters was on the latent heat flux, which could decrease up to −11% in the midday while increasing up to 15% in the nighttime. Additionally, this work indicated that the description of the canopy characteristics for the land surface model should be improved to accurately represent the heterogeneity of the underlying surface.

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Improved Formulations for Air-Surface Exchanges Related to National Security Needs: Dry Deposition Models

Cited by 13 publications

References 77 publications

A new parameterization of particle dry deposition over rough surfaces

A new parameterization of particle dry deposition over rough surfaces

Deposition Velocity Methods For DOE Site Safety Analyses

Improvement and Impacts of Forest Canopy Parameters on Noah-MP Land Surface Model from UAV-Based Photogrammetry

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