Dataset Available

Dataset for: Oil Droplet Transport under Non-Breaking Waves: An Eulerian RANS Approach Combined with a Lagrangian Particle Dispersion Model

Authors: Roozbeh Golshan, Michel Boufadel, Victor Rodriguez, Xiaolong Geng, Feng Gao, Thomas King, Brian Robinson, Andrés Tejada-Martínez
Published On: Feb 28 2018 20:33 UTC
DOI: https://doi.org/10.7266/N7KK999Q
UDI: R4.x265.000:0052
Files

Individual Files

No. of Downloads: 3

No. of Files: 19

File Size: 616.83 KB

File Format(s):
dat, txt

Project Information

Funded By:
Gulf of Mexico Research Initiative

Funding Cycle:
RFP-IV

Research Group:
Consortium for Advanced Research on Transport of Hydrocarbon in the Environment II (CARTHE II)

Point of Contact

Michel Boufadel
New Jersey Institute of Technology / Department of Civil and Environmental Engineering
michel.boufadel@njit.edu

Theme keywords

RANS, Reynolds-averaged Navier-Stokes, non-breaking ocean waves, random walk method, Lagrangian particle dispersion, oil spill model, wave velocity, turbulent kinetic energy, eddy diffusivity

ISO 19115-2 Metadata
  View Metadata
Abstract:

We simulated the two-dimensional regular wave by using Computational Fluid Dynamics (CFD) and coupling the CFD data with Lagrangian Particle Tracking method to evaluate the transport of oil droplet with waves. The dataset was collected from the above mentioned numerical simulation, including the wave velocity, turbulent kinetic energy, eddy diffusivity and oil droplet trajectories. This dataset supports the publication: Golshan, R., Boufadel, M.C., Rodriguez, V.A., Geng, X., Gao, F., King, T., Robinson, B., & Tejada-Martínez, A.E. (2018). Oil Droplet Transport under Non-Breaking Waves: An Eulerian RANS Approach Combined with a Lagrangian Particle Dispersion Model. Journal of Marine Science and Engineering. 6(1), 7; doi: 10.3390/jmse6010007

Suggested Citation:

Roozbeh Golshan, Michel Boufadel, Victor Rodriguez, Xiaolong Geng, Feng Gao, Thomas King, Brian Robinson, Andrés Tejada-Martínez. 2018. Dataset for: Oil Droplet Transport under Non-Breaking Waves: An Eulerian RANS Approach Combined with a Lagrangian Particle Dispersion Model. Distributed by: GRIIDC, Harte Research Institute, Texas A&M University–Corpus Christi. doi:10.7266/N7KK999Q

Publications:

Golshan, R., Boufadel, M., Rodriguez, V., Geng, X., Gao, F., King, T., … Tejada-Martínez, A. (2018). Oil Droplet Transport under Non-Breaking Waves: An Eulerian RANS Approach Combined with a Lagrangian Particle Dispersion Model. Journal of Marine Science and Engineering, 6(1), 7. doi:10.3390/jmse6010007

Purpose:

To understand oil droplet transport under the effect of ocean waves.

Data Parameters and Units:

Figure 4: time series of wave velocity (numerical vs. theoretical solutions) Data points (dimensionless), Horizontal distance (x, m), Vertical distance (y, m), Horizontal velocity (u, m/s), Vertical velocity (v, m/s) Figure 5: Crest 1 and Trough 1 are actual data, Crest 2 and Trough 2 are theoretical solutions Horizontal distance (x, m), Vertical distance (y, m), Horizontal velocity (u, m/s), Vertical velocity (v, m/s) Figure 6: Data for the crest and trough, respectively Horizontal distance (x, m), Vertical distance (y, m), Turbulent kinetic energy (TKE, m^2/s^2), Turbulence dissipation rate (Epsilon, m^2/s^3), Eddy diffusivity (m^2/s) Figure 7: Particle positions (100 um and 1000 um) at different time levels Time level (t, s), Horizontal position (x, m), Vertical position (y, m) Figure 8: Ensemble averaged plume trajectory of particles of diameter (100 um and 1000 um) (particles were initially placed released at 2.5 m

Individual Files: