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BREEZE SCIPUFF

BREEZE SCIPUFF is a time-dependent Gaussian puff model developed by Titan's ARAP Group that employs second-order closure turbulence modeling techniques to relate the dispersion rate to velocity fluctuation statistics.

BREEZE developers created a Graphical User Interface (GUI) that include a GIS, user-friendly data entry forms, parameter range checks, 3D visualization, reporting, and more. In addition to the capability of running the system on a standard Windows® desktop PC, BREEZE developed a system that runs the SCIPUFF model on a LINUX cluster.

SCIPUFF Overview

SCIPUFF is a Lagrangian puff dispersion model that uses a collection of Gaussian puffs to represent an arbitrary, three-dimensional, time-dependent concentration field. The turbulent diffusion parameterization is based on modern turbulence closure theory, specifically the second-order closure model of Donaldson (1973) and Lewellen (1977), which provides a direct relationship between the predicted dispersion rates and the measurable turbulent velocity statistics of the wind field. In addition to the average concentration value, the closure model also provides a prediction of the statistical variance in the concentration field resulting from the random fluctuations in the wind field. The closure approach also provides a direct representation for the effect of averaging time (Sykes and Gabruk, 1997).

The general features of SCIPUFF are as follows:

  • Continuous, instantaneous, moving and stack sources
  • Gaseous and particulate materials
  • Buoyant and non-buoyant releases
  • Flat and complex terrain
  • Dry deposition
  • Wet deposition and gravitational settling of particles
  • Linear decay of released materials
  • Short and long range transport
  • Fixed winds, surface or profile observations, or gridded meteorological input accepted
  • Puff sampling capability (i.e., receptors)

In addition, SCIPUFF also:

  • Provides estimates of the uncertainty in the concentration field
  • Performs accurate treatment of wind shear
  • Merges puffs in addition to splitting them using an efficient adaptive multi-grid scheme
  • Uses an efficient adaptive time-stepping scheme
  • Utilizes static puffs near the source to reduce computation time
  • Flexible output displays color contour plots of concentration and probabilities of exceeding user-specified concentrations.

Donaldson, C. du P., 1973. Atmospheric turbulence and the dispersal of atmospheric pollutants, AMS Workshop on Micrometeorology, D.A. Haugen (Ed.). Science Press, Boston. pp. 313-390.

Lewellen, W.S., 1977. Use of invariant modeling, Handbook of Turbulence, W. Frost and T.H. Moulden (Eds.). Plenum Press. pp. 237-280.

Sykes, R.I. and R.S. Gabruk, 1997. A second-order closure model for the effect of averaging time on turbulent plume dispersion. J. Appl. Meteor., 36: 165-184.