Your search keyword '"Suarez, J. M. S."' showing total 5 results

1. Evaluation of the eddy diffusivity in a pollutant dispersion model in the planetary boundary layer

Author

Goulart, A., Suarez, J. M. S., Lazo, M. J., and Marques, J. C.

Subjects

Physics - Atmospheric and Oceanic Physics, Mathematical Physics

Abstract

In this work, eddy diffusivity is derived from the energy spectra for the stable and convective regimes in the planetary boundary layer. The energy spectra are obtained from a spectral model for the inertial subrange that considers the anomalous behavior of turbulence. This spectrum is expressed as a function of the Hausdorff fractal dimension. The diffusivity eddies are employed in a classical Eulerian dispersion model, where the derivatives are of integer order and in fractional dispersion model, where the derivatives are of fractional order. The eddy diffusivity proposed considers the anomalous nature of geophysical turbulent flow. The results obtained with the fractional and classic dispersion models using the eddy diffusivity proposed is satisfactory when compared with the experimental data of the Prairie Grass and Hanford experiments in a stable regime, and the Copenhagen experiment in a convective regime.

Published

2024

2. A deformed derivative model for turbulent diffusion of contaminants in the atmosphere

Author

Goulart, A. G., Lazo, M. J., and Suarez, J. M. S.

Subjects

Physics - Fluid Dynamics, Physics - Atmospheric and Oceanic Physics

Abstract

In the present work, we propose an advection-diffusion equation with Hausdorff deformed derivatives to stud the turbulent diffusion of contaminants in the atmosphere. We compare the performance of our model to fit experimental data against models with classical and Caputo fractional derivatives. We found that the Hausdorff equation gives better results than the tradition advection-diffusion equation when fitting experimental data. Most importantly, we show that our model and the Caputo fractional derivative model display a very similar performance for all experiments. This last result indicates that regardless of the kind of non-classical derivative we use, an advection-diffusion equation with non-classical derivative displaying power-law mean square displacement is more adequate to describe the diffusion of contaminants in the atmosphere than a model with classical derivatives. Furthermore, since Hausdorff derivatives can be related to several deformed operators, and since differential equations with the Hausdorff derivatives are easier to solve than equations with Caputo and other non-local fractional derivatives, our result highlights the potential of deformed derivative models to describe the diffusion of contaminants in the atmosphere., Comment: accepted in Physica A. arXiv admin note: substantial text overlap with arXiv:1812.02038

Published

2020

3. A new parameterization for the concentration flux using the fractional calculus to model the dispersion of contaminants in the Planetary Boundary Layer

Author

Goulart, A. G., Lazo, M. J., and Suarez, J. M. S.

Subjects

Physics - Atmospheric and Oceanic Physics, Physics - Fluid Dynamics

Abstract

In the present work, we propose a new parameterization for the concentration flux using fractional derivatives. The fractional order differential equation in the longitudinal and vertical directions is used to obtain the concentration distribution of contaminants in the Planetary Boundary Layer. We solve this model and we compare the solution against both real experiments and traditional integer order derivative models. We show that our fractional model gives very good results in fitting the experimental data, and perform far better than the traditional Gaussian model. In fact, the fractional model, with constant wind speed and a constant eddy diffusivity, performs even better than some models found in the literature where it is considered that the wind speed and eddy diffusivity are functions of the position. The results obtained show that the structure of the fractional order differential equation is more appropriate to calculate the distribution of dispersed contaminants in a turbulent flow than an integer-order differential equation. Furthermore, a very important result we found it is that there should be a relation between the order $\alpha$ of the fractional derivative with the physical structure of the turbulent flow., Comment: accepted for publication in Physica A. arXiv admin note: text overlap with arXiv:1702.06345

Published

2018

4. Modelling Fractal Turbulent Velocity Spectra: Application to a Dispersion Model of Contaminants in Particular Cases of the Planetary Boundary Layer

Author

Goulart, A., Suarez, J. M. S., and Lazo, M. J.

Published

2022

5. Fractional derivative models for atmospheric dispersion of pollutants

Author

Goulart, A. G. O., Lazo, M. J., Suarez, J. M. S., and Moreira, D. M.

Subjects

Physics - Atmospheric and Oceanic Physics

Abstract

In the present work, we investigate the potential of fractional derivatives to model atmospheric dispersion of pollutants. We propose simple fractional differential equation models for the steady state spatial distribution of concentration of a non-reactive pollutant in Planetary Boundary Layer. We solve these models and we compare the solutions with a real experiment. We found that the fractional derivative models perform far better than the traditional Gaussian model and even better than models found in the literature where it is considered that the diffusion coefficient is a function of the position in order to deal with the anomalous diffusion., Comment: accepted for publication in Physica A

Published

2017