Jeremy A. Gibbs, Ph.D.
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    • Improving the Performance of a Reduced-Order Mass-Consistent Model for Urban Environments and Complex Terrain With a Higher-Order Geometrical Representation
    • Revisiting the laminar plume
    • QES-Plume v1.0: a Lagrangian dispersion model
    • A method for generating a quasi-linear convective system suitable for observing system simulation experiments
    • Inclination Angles of Turbulent Structures in Stably Stratified Boundary Layers
    • QES-Fire: a dynamically coupled fast-response wildfire model
    • Utilizing dynamic parallelism in CUDA to accelerate a 3D red-black successive over relaxation wind-field solver
    • Large-Eddy Simulation of the Atmospheric Boundary Layer
    • Structure functions and structure parameters of velocity fluctuations in numerically simulated atmospheric convective boundary layer flows
    • Current and Future Uses of UAS for Improved Forecasts/Warnings and Scientific Studies
    • On the evaluation of the proportionality coefficient between the turbulence temperature spectrum and structure parameter
    • Assessing systematic impacts of PBL schemes on storm evolution in the NOAA Warn-on-Forecast System
    • The Great Plains low-level jet during PECAN: observed and simulated characteristics
    • The Great Plains low-level jet during PECAN: observed and simulated characteristics
    • Numerical study of nocturnal low-level jets over gently sloping terrain
    • Numerical study of nocturnal low-level jets over gently sloping terrain
    • Sensitivity of turbulence statistics in the lower portion of a numerically simulated stable boundary layer to parameters of the Deardorff subgrid turbulence model
    • Comparison of Direct and Spectral Methods for Evaluation of the Temperature Structure Parameter in Numerically Simulated Convective Boundary Layer Flows
    • An analytical verification test for numerically simulated convective flow above a thermally heterogeneous surface
    • Measurements of the Temperature Structure-Function Parameters with a Small Unmanned Aerial System Compared with a Sodar
    • Methods for Evaluating the Temperature Structure-Function Parameter Using Unmanned Aerial Systems and Large-Eddy Simulation
    • Revisiting Surface Heat-Flux and Temperature Boundary Conditions in Models of Stably Stratified Boundary-Layer Flows
    • Effects of Temporal Discretization on Turbulence Statistics and Spectra in Numerically Simulated Convective Boundary Layers
    • A Time Series Sodar Simulator Based on Large-Eddy Simulation
    • Comparison of Convective Boundary Layer Velocity Spectra Retrieved from Large-Eddy-Simulation and Weather Research and Forecasting Model Data
    • Downscaling Techniques for Retrieval of Near-surface Meteorological Fields and Turbulence Parameters From Atmospheric Numerical Model Outputs
    • Evaluating Weather Research and Forecasting (WRF) model predictions of turbulent flow parameters in a dry convective boundary layer
    • Turbulent Transport and Surface Interactions Within Inhomogeneous Atmospheric Environments: An Evaluation of Parameterization Schemes in the Weather Research and Forecasting Model
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    • Environmental Fluid Dynamics
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    • Large-Eddy Simulation
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pyBurgers

Oct 26, 2023 ยท 1 min read
Go to Project Site

A fun tool to study turbulence.

Last updated on Oct 26, 2023
Python Turbulence DNS LES
Jeremy A. Gibbs
Authors
Jeremy A. Gibbs
Physical Scientist

ยฉ 2017โ€“2025 Jeremy A. Gibbs. This work is licensed under CC BY NC ND 4.0