Langmuir turbulence example
This example implements a Langmuir turbulence simulation reported in section 4 of
This example demonstrates
How to run large eddy simulations with surface wave effects via the Craik-Leibovich approximation.
How to specify time- and horizontally-averaged output.
Install dependencies
First let's make sure we have all required packages installed.
using Pkg
pkg"add Oceananigans, CairoMakie"using Oceananigans
using Oceananigans.Units: minute, minutes, hoursModel set-up
To build the model, we specify the grid, Stokes drift, boundary conditions, and Coriolis parameter.
Domain and numerical grid specification
We use a modest resolution and the same total extent as Wagner et al. (2021),
grid = RectilinearGrid(size=(32, 32, 32), extent=(128, 128, 64))32×32×32 RectilinearGrid{Float64, Periodic, Periodic, Bounded} on CPU with 3×3×3 halo
├── Periodic x ∈ [0.0, 128.0) regularly spaced with Δx=4.0
├── Periodic y ∈ [0.0, 128.0) regularly spaced with Δy=4.0
└── Bounded z ∈ [-64.0, 0.0] regularly spaced with Δz=2.0The Stokes Drift profile
The surface wave Stokes drift profile prescribed in Wagner et al. (2021), corresponds to a 'monochromatic' (that is, single-frequency) wave field.
A monochromatic wave field is characterized by its wavelength and amplitude (half the distance from wave crest to wave trough), which determine the wave frequency and the vertical scale of the Stokes drift profile.
using Oceananigans.BuoyancyModels: g_Earth
amplitude = 0.8 # m
wavelength = 60 # m
wavenumber = 2π / wavelength # m⁻¹
frequency = sqrt(g_Earth * wavenumber) # s⁻¹
# The vertical scale over which the Stokes drift of a monochromatic surface wave
# decays away from the surface is `1/2wavenumber`, or
const vertical_scale = wavelength / 4π
# Stokes drift velocity at the surface
const Uˢ = amplitude^2 * wavenumber * frequency # m s⁻¹0.06791774197745354The const declarations ensure that Stokes drift functions compile on the GPU. To run this example on the GPU, include GPU() in the RectilinearGrid constructor above.
The Stokes drift profile is
uˢ(z) = Uˢ * exp(z / vertical_scale)uˢ (generic function with 1 method)and its z-derivative is
∂z_uˢ(z, t) = 1 / vertical_scale * Uˢ * exp(z / vertical_scale)∂z_uˢ (generic function with 1 method)Oceananigans implements the Craik-Leibovich approximation for surface wave effects using the Lagrangian-mean velocity field as its prognostic momentum variable. In other words, model.velocities.u is the Lagrangian-mean $x$-velocity beneath surface waves. This differs from models that use the Eulerian-mean velocity field as a prognostic variable, but has the advantage that $u$ accounts for the total advection of tracers and momentum, and that $u = v = w = 0$ is a steady solution even when Coriolis forces are present. See the physics documentation for more information.
Finally, we note that the time-derivative of the Stokes drift must be provided if the Stokes drift and surface wave field undergoes forced changes in time. In this example, the Stokes drift is constant and thus the time-derivative of the Stokes drift is 0.
Boundary conditions
At the surface $z = 0$, Wagner et al. (2021) impose
Qᵘ = -3.72e-5 # m² s⁻², surface kinematic momentum flux
u_boundary_conditions = FieldBoundaryConditions(top = FluxBoundaryCondition(Qᵘ))Oceananigans.FieldBoundaryConditions, with boundary conditions
├── west: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── east: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── south: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── north: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── bottom: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── top: FluxBoundaryCondition: -3.72e-5
└── immersed: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)Wagner et al. (2021) impose a linear buoyancy gradient N² at the bottom along with a weak, destabilizing flux of buoyancy at the surface to faciliate spin-up from rest.
Qᵇ = 2.307e-8 # m² s⁻³, surface buoyancy flux
N² = 1.936e-5 # s⁻², initial and bottom buoyancy gradient
b_boundary_conditions = FieldBoundaryConditions(top = FluxBoundaryCondition(Qᵇ),
bottom = GradientBoundaryCondition(N²))Oceananigans.FieldBoundaryConditions, with boundary conditions
├── west: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── east: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── south: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── north: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)
├── bottom: GradientBoundaryCondition: 1.936e-5
├── top: FluxBoundaryCondition: 2.307e-8
└── immersed: DefaultBoundaryCondition (FluxBoundaryCondition: Nothing)Note that Oceananigans uses "positive upward" conventions for all fluxes. In consequence, a negative flux at the surface drives positive velocities, and a positive flux of buoyancy drives cooling.
Coriolis parameter
Wagner et al. (2021) use
coriolis = FPlane(f=1e-4) # s⁻¹FPlane{Float64}(f=0.0001)which is typical for mid-latitudes on Earth.
Model instantiation
We are ready to build the model. We use a fifth-order Weighted Essentially Non-Oscillatory (WENO) advection scheme and the AnisotropicMinimumDissipation model for large eddy simulation. Because our Stokes drift does not vary in $x, y$, we use UniformStokesDrift, which expects Stokes drift functions of $z, t$ only.
model = NonhydrostaticModel(; grid, coriolis,
advection = WENO(),
timestepper = :RungeKutta3,
tracers = :b,
buoyancy = BuoyancyTracer(),
closure = AnisotropicMinimumDissipation(),
stokes_drift = UniformStokesDrift(∂z_uˢ=∂z_uˢ),
boundary_conditions = (u=u_boundary_conditions, b=b_boundary_conditions))NonhydrostaticModel{CPU, RectilinearGrid}(time = 0 seconds, iteration = 0)
├── grid: 32×32×32 RectilinearGrid{Float64, Periodic, Periodic, Bounded} on CPU with 3×3×3 halo
├── timestepper: RungeKutta3TimeStepper
├── advection scheme: WENO reconstruction order 5
├── tracers: b
├── closure: AnisotropicMinimumDissipation{ExplicitTimeDiscretization, @NamedTuple{b::Float64}, Float64, Nothing}
├── buoyancy: BuoyancyTracer with ĝ = NegativeZDirection()
└── coriolis: FPlane{Float64}(f=0.0001)Initial conditions
We make use of random noise concentrated in the upper 4 meters for buoyancy and velocity initial conditions,
Ξ(z) = randn() * exp(z / 4)Our initial condition for buoyancy consists of a surface mixed layer 33 m deep, a deep linear stratification, plus noise,
initial_mixed_layer_depth = 33 # m
stratification(z) = z < - initial_mixed_layer_depth ? N² * z : N² * (-initial_mixed_layer_depth)
bᵢ(x, y, z) = stratification(z) + 1e-1 * Ξ(z) * N² * model.grid.Lzbᵢ (generic function with 1 method)The simulation we reproduce from Wagner et al. (2021) is zero Lagrangian-mean velocity. This initial condition is consistent with a wavy, quiescent ocean suddenly impacted by winds. To this quiescent state we add noise scaled by the friction velocity to $u$ and $w$.
u★ = sqrt(abs(Qᵘ))
uᵢ(x, y, z) = u★ * 1e-1 * Ξ(z)
wᵢ(x, y, z) = u★ * 1e-1 * Ξ(z)
set!(model, u=uᵢ, w=wᵢ, b=bᵢ)Setting up the simulation
simulation = Simulation(model, Δt=45.0, stop_time=4hours)Simulation of NonhydrostaticModel{CPU, RectilinearGrid}(time = 0 seconds, iteration = 0)
├── Next time step: 45 seconds
├── Elapsed wall time: 0 seconds
├── Wall time per iteration: NaN days
├── Stop time: 4 hours
├── Stop iteration : Inf
├── Wall time limit: Inf
├── Callbacks: OrderedDict with 4 entries:
│ ├── stop_time_exceeded => Callback of stop_time_exceeded on IterationInterval(1)
│ ├── stop_iteration_exceeded => Callback of stop_iteration_exceeded on IterationInterval(1)
│ ├── wall_time_limit_exceeded => Callback of wall_time_limit_exceeded on IterationInterval(1)
│ └── nan_checker => Callback of NaNChecker for u on IterationInterval(100)
├── Output writers: OrderedDict with no entries
└── Diagnostics: OrderedDict with no entriesWe use the TimeStepWizard for adaptive time-stepping with a Courant-Freidrichs-Lewy (CFL) number of 1.0,
conjure_time_step_wizard!(simulation, cfl=1.0, max_Δt=1minute)Nice progress messaging
We define a function that prints a helpful message with maximum absolute value of $u, v, w$ and the current wall clock time.
using Printf
function progress(simulation)
u, v, w = simulation.model.velocities
# Print a progress message
msg = @sprintf("i: %04d, t: %s, Δt: %s, umax = (%.1e, %.1e, %.1e) ms⁻¹, wall time: %s\n",
iteration(simulation),
prettytime(time(simulation)),
prettytime(simulation.Δt),
maximum(abs, u), maximum(abs, v), maximum(abs, w),
prettytime(simulation.run_wall_time))
@info msg
return nothing
end
simulation.callbacks[:progress] = Callback(progress, IterationInterval(20))Callback of progress on IterationInterval(20)Output
A field writer
We set up an output writer for the simulation that saves all velocity fields, tracer fields, and the subgrid turbulent diffusivity.
output_interval = 5minutes
fields_to_output = merge(model.velocities, model.tracers, (; νₑ=model.diffusivity_fields.νₑ))
simulation.output_writers[:fields] =
JLD2OutputWriter(model, fields_to_output,
schedule = TimeInterval(output_interval),
filename = "langmuir_turbulence_fields.jld2",
overwrite_existing = true)JLD2OutputWriter scheduled on TimeInterval(5 minutes):
├── filepath: ./langmuir_turbulence_fields.jld2
├── 5 outputs: (u, v, w, b, νₑ)
├── array type: Array{Float64}
├── including: [:grid, :coriolis, :buoyancy, :closure]
├── file_splitting: NoFileSplitting
└── file size: 39.7 KiBAn "averages" writer
We also set up output of time- and horizontally-averaged velocity field and momentum fluxes.
u, v, w = model.velocities
b = model.tracers.b
U = Average(u, dims=(1, 2))
V = Average(v, dims=(1, 2))
B = Average(b, dims=(1, 2))
wu = Average(w * u, dims=(1, 2))
wv = Average(w * v, dims=(1, 2))
simulation.output_writers[:averages] =
JLD2OutputWriter(model, (; U, V, B, wu, wv),
schedule = AveragedTimeInterval(output_interval, window=2minutes),
filename = "langmuir_turbulence_averages.jld2",
overwrite_existing = true)JLD2OutputWriter scheduled on TimeInterval(5 minutes):
├── filepath: ./langmuir_turbulence_averages.jld2
├── 5 outputs: (U, V, B, wu, wv) averaged on AveragedTimeInterval(window=2 minutes, stride=1, interval=5 minutes)
├── array type: Array{Float64}
├── including: [:grid, :coriolis, :buoyancy, :closure]
├── file_splitting: NoFileSplitting
└── file size: 39.4 KiBRunning the simulation
This part is easy,
run!(simulation)[ Info: Initializing simulation...
[ Info: i: 0000, t: 0 seconds, Δt: 49.500 seconds, umax = (1.3e-03, 4.8e-04, 6.2e-04) ms⁻¹, wall time: 0 seconds
[ Info: ... simulation initialization complete (17.429 seconds)
[ Info: Executing initial time step...
[ Info: ... initial time step complete (18.384 seconds).
[ Info: i: 0020, t: 15.907 minutes, Δt: 59.895 seconds, umax = (2.4e-02, 1.1e-02, 1.8e-02) ms⁻¹, wall time: 50.888 seconds
[ Info: i: 0040, t: 33 minutes, Δt: 1 minute, umax = (3.5e-02, 9.9e-03, 1.6e-02) ms⁻¹, wall time: 1.039 minutes
[ Info: i: 0060, t: 53 minutes, Δt: 1 minute, umax = (4.7e-02, 1.3e-02, 1.5e-02) ms⁻¹, wall time: 1.228 minutes
[ Info: i: 0080, t: 1.182 hours, Δt: 53.546 seconds, umax = (5.6e-02, 1.8e-02, 1.5e-02) ms⁻¹, wall time: 1.425 minutes
[ Info: i: 0100, t: 1.446 hours, Δt: 48.566 seconds, umax = (5.9e-02, 2.3e-02, 2.0e-02) ms⁻¹, wall time: 1.613 minutes
[ Info: i: 0120, t: 1.680 hours, Δt: 48.257 seconds, umax = (6.2e-02, 2.6e-02, 2.0e-02) ms⁻¹, wall time: 1.799 minutes
[ Info: i: 0140, t: 1.917 hours, Δt: 45.404 seconds, umax = (6.6e-02, 2.9e-02, 2.5e-02) ms⁻¹, wall time: 1.987 minutes
[ Info: i: 0160, t: 2.157 hours, Δt: 41.503 seconds, umax = (6.7e-02, 3.5e-02, 2.6e-02) ms⁻¹, wall time: 2.170 minutes
[ Info: i: 0180, t: 2.367 hours, Δt: 38.740 seconds, umax = (7.2e-02, 4.3e-02, 3.2e-02) ms⁻¹, wall time: 2.300 minutes
[ Info: i: 0200, t: 2.575 hours, Δt: 38.676 seconds, umax = (7.4e-02, 4.4e-02, 3.3e-02) ms⁻¹, wall time: 2.415 minutes
[ Info: i: 0220, t: 2.770 hours, Δt: 39.109 seconds, umax = (7.4e-02, 4.3e-02, 3.8e-02) ms⁻¹, wall time: 2.580 minutes
[ Info: i: 0240, t: 2.980 hours, Δt: 36.778 seconds, umax = (6.9e-02, 4.5e-02, 3.6e-02) ms⁻¹, wall time: 2.753 minutes
[ Info: i: 0260, t: 3.177 hours, Δt: 38.279 seconds, umax = (7.2e-02, 4.9e-02, 3.5e-02) ms⁻¹, wall time: 2.995 minutes
[ Info: i: 0280, t: 3.374 hours, Δt: 35.046 seconds, umax = (7.0e-02, 5.1e-02, 3.6e-02) ms⁻¹, wall time: 3.163 minutes
[ Info: i: 0300, t: 3.559 hours, Δt: 37.918 seconds, umax = (7.3e-02, 4.6e-02, 4.1e-02) ms⁻¹, wall time: 3.303 minutes
[ Info: i: 0320, t: 3.761 hours, Δt: 35.485 seconds, umax = (7.6e-02, 4.7e-02, 4.0e-02) ms⁻¹, wall time: 3.422 minutes
[ Info: i: 0340, t: 3.947 hours, Δt: 35.746 seconds, umax = (7.4e-02, 4.8e-02, 3.6e-02) ms⁻¹, wall time: 3.528 minutes
[ Info: Simulation is stopping after running for 3.560 minutes.
[ Info: Simulation time 4 hours equals or exceeds stop time 4 hours.
Making a neat movie
We look at the results by loading data from file with FieldTimeSeries, and plotting vertical slices of $u$ and $w$, and a horizontal slice of $w$ to look for Langmuir cells.
using CairoMakie
time_series = (;
w = FieldTimeSeries("langmuir_turbulence_fields.jld2", "w"),
u = FieldTimeSeries("langmuir_turbulence_fields.jld2", "u"),
B = FieldTimeSeries("langmuir_turbulence_averages.jld2", "B"),
U = FieldTimeSeries("langmuir_turbulence_averages.jld2", "U"),
V = FieldTimeSeries("langmuir_turbulence_averages.jld2", "V"),
wu = FieldTimeSeries("langmuir_turbulence_averages.jld2", "wu"),
wv = FieldTimeSeries("langmuir_turbulence_averages.jld2", "wv"))
times = time_series.w.times
xw, yw, zw = nodes(time_series.w)
xu, yu, zu = nodes(time_series.u)We are now ready to animate using Makie. We use Makie's Observable to animate the data. To dive into how Observables work we refer to Makie.jl's Documentation.
n = Observable(1)
wxy_title = @lift string("w(x, y, t) at z=-8 m and t = ", prettytime(times[$n]))
wxz_title = @lift string("w(x, z, t) at y=0 m and t = ", prettytime(times[$n]))
uxz_title = @lift string("u(x, z, t) at y=0 m and t = ", prettytime(times[$n]))
fig = Figure(size = (850, 850))
ax_B = Axis(fig[1, 4];
xlabel = "Buoyancy (m s⁻²)",
ylabel = "z (m)")
ax_U = Axis(fig[2, 4];
xlabel = "Velocities (m s⁻¹)",
ylabel = "z (m)",
limits = ((-0.07, 0.07), nothing))
ax_fluxes = Axis(fig[3, 4];
xlabel = "Momentum fluxes (m² s⁻²)",
ylabel = "z (m)",
limits = ((-3.5e-5, 3.5e-5), nothing))
ax_wxy = Axis(fig[1, 1:2];
xlabel = "x (m)",
ylabel = "y (m)",
aspect = DataAspect(),
limits = ((0, grid.Lx), (0, grid.Ly)),
title = wxy_title)
ax_wxz = Axis(fig[2, 1:2];
xlabel = "x (m)",
ylabel = "z (m)",
aspect = AxisAspect(2),
limits = ((0, grid.Lx), (-grid.Lz, 0)),
title = wxz_title)
ax_uxz = Axis(fig[3, 1:2];
xlabel = "x (m)",
ylabel = "z (m)",
aspect = AxisAspect(2),
limits = ((0, grid.Lx), (-grid.Lz, 0)),
title = uxz_title)
wₙ = @lift time_series.w[$n]
uₙ = @lift time_series.u[$n]
Bₙ = @lift time_series.B[$n][1, 1, :]
Uₙ = @lift time_series.U[$n][1, 1, :]
Vₙ = @lift time_series.V[$n][1, 1, :]
wuₙ = @lift time_series.wu[$n][1, 1, :]
wvₙ = @lift time_series.wv[$n][1, 1, :]
k = searchsortedfirst(grid.zᵃᵃᶠ[:], -8)
wxyₙ = @lift interior(time_series.w[$n], :, :, k)
wxzₙ = @lift interior(time_series.w[$n], :, 1, :)
uxzₙ = @lift interior(time_series.u[$n], :, 1, :)
wlims = (-0.03, 0.03)
ulims = (-0.05, 0.05)
lines!(ax_B, Bₙ, zu)
lines!(ax_U, Uₙ, zu; label = L"\bar{u}")
lines!(ax_U, Vₙ, zu; label = L"\bar{v}")
axislegend(ax_U; position = :rb)
lines!(ax_fluxes, wuₙ, zw; label = L"mean $wu$")
lines!(ax_fluxes, wvₙ, zw; label = L"mean $wv$")
axislegend(ax_fluxes; position = :rb)
hm_wxy = heatmap!(ax_wxy, xw, yw, wxyₙ;
colorrange = wlims,
colormap = :balance)
Colorbar(fig[1, 3], hm_wxy; label = "m s⁻¹")
hm_wxz = heatmap!(ax_wxz, xw, zw, wxzₙ;
colorrange = wlims,
colormap = :balance)
Colorbar(fig[2, 3], hm_wxz; label = "m s⁻¹")
ax_uxz = heatmap!(ax_uxz, xu, zu, uxzₙ;
colorrange = ulims,
colormap = :balance)
Colorbar(fig[3, 3], ax_uxz; label = "m s⁻¹")
fig
And, finally, we record a movie.
frames = 1:length(times)
record(fig, "langmuir_turbulence.mp4", frames, framerate=8) do i
n[] = i
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