J. F. Clarke scite author profile

Abstract. In this paper, we describe the latest version of the dry deposition inferential model, which is used to estimate the deposition velocities (V a) for SO2, 03, HNO3, and particles with diameters less than 2 •m. The dry deposition networks operated by the National Oceanic and Atmospheric Administration (NOAA) and the Environmental Protection Agency (EPA) use this model to estimate dry deposition on a weekly basis. This model uses a multilayer approach, discretizing the vegetated canopy into 20 layers. The use of canopy radiative transfer and simple wind profile models allows for estimates of stomatal (rs) and leaf boundary layer (%) resistances to be determined at each layer in the plant canopy for both sunlit and shaded leaves. The effect of temperature, water stress, and vapor pressure deficits on the stomatal resistance (rs) have been included. This paper describes the multilayer modeling approach for estimating the dry deposition of SO2, HNO3, and 03 that is currently implemented in the NOAA and EPA national networks. The model is evaluated against 30 min average direct flux measurements recently obtained over corn near Bondville, Illinois, over soybeans near Nashville, Tennessee, and over grass near Sand Mountain, Alabama. 22,645

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Electrostatically driven charge-ordering in Fe2OBO3

Attfield

Bell

Rodrı́guez-Martı́nez

et al. 1998

Nature

112

104

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letters to nature 658 NATURE | VOL 396 | 17 DECEMBER 1998 | www.nature.com T CO 317 K. Hence a conducting, magnetically ordered state is not found in Fe 2 OBO 3 as T C , T CO . The differences between the estimated activation energies for electron hopping in the chargedisordered (E a < 0 for T . T V ) and ordered (E a < 0:04 eV for T , T V ) 13 states of magnetite and those of Fe 2 OBO 3 (E a < 0:31 eV for E a < 0:35 eV for T . T CO are equal, showing that this small difference is essentially independent of spin alignment, although the ferromagnetic order in magnetite reduces both activation energies by 0.3 eV relative to those in paramagnetic Fe 2 OBO 3 .M

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Dry deposition calculations for the clean air status and trends network

Clarke

Edgerton²,

Martin

1997

Atmospheric Environment

155

114

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Ozone and sulfur dioxide dry deposition to forests: Observations and model evaluation

Finkelstein¹,

Ellestad²,

Clarke³

et al. 2000

J. Geophys. Res.

126

103

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Abstract. Fluxes and deposition velocities of 03 and SO2 were measured over both a deciduous and a mixed coniferous-deciduous forest for full growing seasons. Fluxes and deposition velocities of 03 were measured over a coniferous forest for a month. Mean deposition velocities of 0.35 to 0.48 cm/s for 03 and 0.6 to 0.72 cm/s for SO2 were observed during the growing seasons of 1997 and 1998. Weekly averages of 03 deposition velocity ranged from 0.25 cm/s at the beginning and end of the season to 1.25 cm/s in late June. SO2 had a smaller seasonal variation, from 0.75 to 1.5 cm/s between the beginning and peak of the season. Because 03 concentrations are higher, the flux of 03 to forests is considerably greater than the flux of SO2. Daytime deposition velocities are very similar at each site, from 0.75 to 0.79 cm/s for 03, and from 1.01 to 1.04 cm/s for SO2. Diurnal cycles for both gases are discussed, as are the impact of some weather events. The peak time for 03 deposition velocity is in midmorning, while it is near midday for SO2. Surface wetness is usually associated with a small increase in deposition velocity, but for some rain events a major increase was noted. Minimum deposition velocities usually occur at night and increase slowly in the predawn hours before light. Comparisons are made between observations of deposition velocity and predictions made with the Meyers multilayer deposition velocity model. While the model is, on average, unbiased for 03, it tends to underpredict the higher deposition velocity values. The model is slightly biased low (underpredicts) for SO2 deposition velocity. The strengths of the model are noted, as are opportunities for improvement. IntroductionIn addition to their use in local and regional scale air quality models, deposition velocity models are integral to the inferential dry deposition monitoring networks that operate in the United States, Canada, and Europe ]. Because of the high cost and complexity of direct flux measurements, operational dry deposition networks measure concentrations of air pollutants and infer the flux of pollutants to the surface using a modeled deposition velocity (flux equal to deposition velocity times concentration).In an earlier paper [Meyers et al., 1998] we reported on the formulation of the Multilayer Model (MLM) for deposition velocity which is being used in operational dry deposition networks in the United States and the observations from three field studies which were used to evaluate and improve the MLM. Those studies were performed over agricultural fields of pasture, corn, and soybeans. Details of the model and field This work reports on three new field studies which measured fluxes of 03 and SO2 over forests, and the evaluation of the MLM with those data. The studies were conducted over a pine plantation in central North Carolina during the spring of 1996, over a deciduous forest in northwestern Pennsylvania during the growing season of 1997, and over a mixed forest in the Adirondack Mountain region of New York during the growing season...

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An Investigation of the Conditional Sampling Method Used to Estimate Fluxes of Active, Reactive, and Passive Scalars

Katul¹,

Finkelstein²,

Clarke³

et al. 1996

J. Appl. Meteor.

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J. F. Clarke

A multilayer model for inferring dry deposition using standard meteorological measurements

Electrostatically driven charge-ordering in Fe2OBO3

Dry deposition calculations for the clean air status and trends network

Ozone and sulfur dioxide dry deposition to forests: Observations and model evaluation

An Investigation of the Conditional Sampling Method Used to Estimate Fluxes of Active, Reactive, and Passive Scalars

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