- Source: Tides in marginal seas
Tides in marginal seas are tides affected by their location in semi-enclosed areas along the margins of continents and differ from tides in the open oceans. Tides are water level variations caused by the gravitational interaction between the Moon, the Sun and the Earth. The resulting tidal force is a secondary effect of gravity: it is the difference between the actual gravitational force and the centrifugal force. While the centrifugal force is constant across the Earth, the gravitational force is dependent on the distance between the two bodies and is therefore not constant across the Earth. The tidal force is thus the difference between these two forces on each location on the Earth.
In an idealized situation, assuming a planet with no landmasses (an aqua planet), the tidal force would result in two tidal bulges on opposite sides of the earth. This is called the equilibrium tide. However, due to global and local ocean responses different tidal patterns are generated. The complicated ocean responses are the result of the continental barriers, resonance due to the shape of the ocean basin, the tidal waves impossibility to keep up with the Moons tracking, the Coriolis acceleration and the elastic response of the solid earth.
In addition, when the tide arrives in the shallow seas it interacts with the sea floor which leads to the deformation of the tidal wave. As a results, tides in shallow waters tend to be larger, of shorter wavelength, and possibly nonlinear relative to tides in the deep ocean.
Tides on the continental shelf
The transition from the deep ocean to the continental shelf, known as the continental slope, is characterized by a sudden decrease in water depth. In order to apply to the conservation of energy, the tidal wave has to deform as a result of the decrease in water depth. The total energy of a linear progressive wave per wavelength is the sum of the potential energy (PE) and the kinetic energy (KE). The potential and kinetic energy integrated over a complete wavelength are the same, under the assumption that the water level variations are small compared to the water depth (
η
<<
H
{\displaystyle \eta <
).
∫
0
λ
P
E
=
∫
0
λ
K
E
=
1
2
ρ
g
∫
0
λ
η
2
d
x
{\displaystyle \int _{0}^{\lambda }PE=\int _{0}^{\lambda }KE={\frac {1}{2}}\rho g\int _{0}^{\lambda }\eta ^{2}dx}
where
ρ
{\displaystyle \rho }
is the density,
g
{\displaystyle g}
the gravitation acceleration and
η
{\displaystyle \eta }
the vertical tidal elevation. The total wave energy becomes:
E
=
ρ
g
∫
0
λ
η
2
d
x
{\displaystyle E=\rho g\int _{0}^{\lambda }\eta ^{2}dx}
If we now solve for a harmonic wave
η
(
x
)
=
A
c
o
s
(
k
x
)
{\displaystyle \eta (x)=Acos(kx)}
, where
k
{\displaystyle k}
is the wave number and
A
{\displaystyle A}
the amplitude, the total energy per unit area of surface becomes:
E
s
=
1
2
ρ
g
A
2
{\displaystyle E_{s}={\frac {1}{2}}\rho gA^{2}}
A tidal wave has a wavelength that is much larger than the water depth. And thus according to the dispersion of gravity waves, they travel with the phase and group velocity of a shallow water wave:
c
p
=
c
g
=
g
h
{\displaystyle c_{p}=c_{g}={\sqrt {gh}}}
. The wave energy is transmitted by the group velocity of a wave and thus the energy flux (
F
E
{\displaystyle F_{E}}
) is given by:
F
E
=
1
2
ρ
g
A
2
g
h
{\displaystyle F_{E}={\frac {1}{2}}\rho gA^{2}{\sqrt {gh}}}
The energy flux needs to be conserved and with
ρ
{\displaystyle \rho }
and
g
{\displaystyle g}
constant, this leads to:
F
E
,
1
=
F
E
,
2
⟹
A
1
2
g
h
1
=
A
2
2
g
h
2
{\displaystyle F_{E,1}=F_{E,2}\Longrightarrow {A_{1}}^{2}{\sqrt {gh_{1}}}={A_{2}}^{2}{\sqrt {gh_{2}}}}
where
h
2
<
h
1
{\displaystyle h2
and thus
A
2
>
A
1
{\displaystyle A_{2}>A_{1}}
.
When the tidal wave propagates onto the continental shelf, the water depth
(
h
)
{\displaystyle (h)}
decreases. In order to conserve the energy flux, the amplitude of the wave needs to increase (see figure 1).
= Transmission coefficient
=The above explanation is a simplification as not all tidal wave energy is transmitted, but it is partly reflected at the continental slope. The transmission coefficient of the tidal wave is given by:
A
2
A
1
=
2
c
1
(
c
1
+
c
2
)
{\displaystyle {\frac {A_{2}}{A_{1}}}={\frac {2c_{1}}{(c_{1}+c_{2})}}}
This equation indicates that when
c
1
=
c
2
{\displaystyle c_{1}=c_{2}}
the transmitted tidal wave has the same amplitude as the original wave. Furthermore, the transmitted wave will be larger than the original wave when
c
1
>
c
2
{\displaystyle c_{1}>c_{2}}
as is the case for the transition to the continental shelf.
The reflected wave amplitude (
A
′
{\displaystyle A^{'}}
) is determined by the reflection coefficient of the tidal wave:
A
′
A
1
=
c
1
−
c
2
(
c
1
+
c
2
)
{\displaystyle {\frac {A^{'}}{A_{1}}}={\frac {c_{1}-c_{2}}{(c_{1}+c_{2})}}}
This equation indicates that when
c
1
=
c
2
{\displaystyle c_{1}=c_{2}}
there is no reflected wave and if
c
1
>
c
2
{\displaystyle c_{1}>c_{2}}
the reflected tidal wave will be smaller than the original tidal wave.
= Internal tide and mixing
=At the continental shelf the reflection and transmission of the tidal wave can lead to the generation of internal tides on the pycnocline. The surface (i.e. barotropic) tide generates these internal tides where stratified waters are forced upwards over a sloping bottom topography. The internal tide extracts energy from the surface tide and propagates both in shoreward and seaward direction. The shoreward propagating internal waves shoals when reaching shallower water where the wave energy is dissipated by wave breaking. The shoaling of the internal tide drives mixing across the pycnocline, high levels carbon sequestration and sediment resuspension. Furthermore, through nutrient mixing the shoaling of the internal tide has a fundamental control on the functioning of ecosystems on the continental margin.
Tidal propagation along coasts
After entering the continental shelf, a tidal wave quickly faces a boundary in the form of a landmass. When the tidal wave reaches a continental margin, it continues as a boundary trapped Kelvin wave. Along the coast, a boundary trapped Kelvin is also known as a coastal Kelvin wave or Edge wave. A Kelvin wave is a special type of gravity wave that can exist when there is (1) gravity and stable stratification, (2) sufficient Coriolis force and (3) the presence of a vertical boundary. Kelvin waves are important in the ocean and shelf seas, they form a balance between inertia, the Coriolis force and the pressure gradient force. The simplest equations that describe the dynamics of Kelvin waves are the linearized shallow water equations for homogeneous, in-viscid flows. These equations can be linearized for a small Rossby number, no frictional forces and under the assumption that the wave height is small compared to the water depth (
η
<<
h
{\displaystyle \eta <
). The linearized depth-averaged shallow water equations become:
u momentum equation:
∂
u
∂
t
−
f
v
=
−
g
∂
η
∂
x
{\displaystyle {\frac {\partial u}{\partial t}}-fv=-g{\frac {\partial \eta }{\partial x}}}
v momentum equation:
∂
v
∂
t
+
f
u
=
−
g
∂
η
∂
y
{\displaystyle {\frac {\partial v}{\partial t}}+fu=-g{\frac {\partial \eta }{\partial y}}}
the continuity equation:
∂
η
∂
t
+
h
(
∂
u
∂
x
+
∂
v
∂
y
)
=
0
{\displaystyle {\frac {\partial \eta }{\partial t}}+h({\frac {\partial u}{\partial x}}+{\frac {\partial v}{\partial y}})=0}
where
u
{\displaystyle u}
is the zonal velocity (
x
{\displaystyle x}
direction),
v
{\displaystyle v}
the meridional velocity (
y
{\displaystyle y}
direction),
t
{\displaystyle t}
is time and
f
{\displaystyle f}
is the Coriolis frequency.
Kelvin waves are named after Lord Kelvin, who first described them after finding solutions to the linearized shallow water equations with the boundary condition
u
(
x
,
y
,
t
)
=
0
{\displaystyle u(x,y,t)=0}
. When this assumption is made the linearized depth-averaged shallow water equations that can describe a Kelvin wave become:
u momentum equation:
v
=
−
g
f
∂
η
∂
x
{\displaystyle v={\frac {-g}{f}}{\frac {\partial \eta }{\partial x}}}
v momentum equation:
∂
v
∂
t
=
−
g
∂
η
∂
y
{\displaystyle {\frac {\partial v}{\partial t}}=-g{\frac {\partial \eta }{\partial y}}}
the continuity equation:
∂
η
∂
t
+
h
∂
v
∂
y
=
0
{\displaystyle {\frac {\partial \eta }{\partial t}}+h{\frac {\partial v}{\partial y}}=0}
Now it is possible to get an expression for
η
{\displaystyle \eta }
, by taking the time derivative of the continuity equation and substituting the momentum equation:
∂
2
η
∂
t
2
−
g
h
∂
2
η
∂
y
2
=
0
{\displaystyle {\frac {\partial ^{2}\eta }{\partial t^{2}}}-gh{\frac {\partial ^{2}\eta }{\partial y^{2}}}=0}
The same can be done for
v
{\displaystyle v}
, by taking the time derivative of the v momentum equation and substituting the continuity equation
∂
2
v
∂
t
2
−
g
h
∂
2
v
∂
y
2
=
0
{\displaystyle {\frac {\partial ^{2}v}{\partial t^{2}}}-gh{\frac {\partial ^{2}v}{\partial y^{2}}}=0}
Both of these equations take the form of the classical wave equation, where
c
=
g
h
{\displaystyle c={\sqrt {gh}}}
. Which is the same velocity as the tidal wave and thus of a shallow water wave. These preceding equations govern the dynamics of a one-dimensional non-dispersive wave, for which the following general solution exist:
η
=
−
h
F
(
y
+
c
t
)
e
−
x
R
{\displaystyle \eta =-h\ F(y+ct)\ e^{\frac {-x}{R}}}
v
=
g
h
F
(
y
+
c
t
)
e
−
x
R
{\displaystyle v={\sqrt {gh}}\ F(y+ct)\ e^{\frac {-x}{R}}}
where length
R
=
g
h
f
{\displaystyle R={\frac {\sqrt {gh}}{f}}}
is the Rossby radius of deformation and
F
(
y
+
c
t
)
{\displaystyle F(y+ct)}
is an arbitrary function describing the wave motion. In the most simple form
F
{\displaystyle F}
is a cosine or sine function which describes a wave motion in the positive and negative direction. The Rossby radius of deformation is a typical length scale in the ocean and atmosphere that indicates when rotational effects become important. The Rossby radius of deformation is a measure for the trapping distance of a coastal Kelvin wave. The exponential term results in an amplitude that decays away from the coast.
The expression of tides as a bounded Kelvin wave is well observable in enclosed shelf seas around the world (e.g. the English channel, the North Sea or the Yellow sea). Animation 1 shows the behaviour of a simplified case of a Kelvin wave in an enclosed shelf sea for the case with (lower panel) and without friction (upper panel). The shape of an enclosed shelf sea is represented as a simple rectangular domain in the Northern Hemisphere which is open on the left hand side and closed on the right hand side. The tidal wave, a Kelvin wave, enters the domain in the lower left corner and travels to the right with the coast on its right. The sea surface height (SSH, left panels of animation 1), the tidal elevation, is maximum at the coast and decreases towards the centre of the domain. The tidal currents (right panels of animation 1) are in the direction of wave propagation under the crest and in the opposite direction under the through. They are both maximum under the crest and the trough of the waves and decrease towards the centre. This was expected as the equations for
η
{\displaystyle \eta }
and
v
{\displaystyle v}
are in phase as they both depend on the same arbitrary function describing the wave motion and exponential decay term. Therefore this set of equations describes a wave that travels along the coast with a maximum amplitude at the coast which declines towards the ocean. These solutions also indicate that a Kelvin wave always travels with the coast on their right hand side in the Northern Hemisphere and with the coast at their left hand side in the Southern Hemisphere. In the limit of no rotation where
f
→
0
{\displaystyle f\rightarrow 0}
, the exponential term increase without a bound and the wave will become a simple gravity wave orientated perpendicular to the coast. In the next section, it will be shown how these Kelvin waves behaves when traveling along a coast, in an enclosed shelf seas or in estuaries and basins.
= Tides in enclosed shelf seas
=The expression of tides as a bounded Kelvin wave is well observable in enclosed shelf seas around the world (e.g. the English channel, the North Sea or the Yellow sea). Animation 1 shows the behaviour of a simplified case of a Kelvin wave in an enclosed shelf sea for the case with (lower panel) and without friction (upper panel). The shape of an enclosed shelf sea is represented as a simple rectangular domain in the Northern Hemisphere which is open on the left hand side and closed on the right hand side. The tidal wave, a Kelvin wave, enters the domain in the lower left corner and travels to the right with the coast on its right. The sea surface height (SSH, left panels of animation 1), the tidal elevation, is maximum at the coast and decreases towards the centre of the domain. The tidal currents (right panels of animation 1) are in the direction of wave propagation under the crest and in the opposite direction under the through. They are both maximum under the crest and the trough of the waves and decrease towards the centre. This was expected as the equations for
η
{\displaystyle \eta }
and
v
{\displaystyle v}
are in phase as they both depend on the same arbitrary function describing the wave motion and exponential decay term.
On the enclosed right hand side, the Kelvin wave is reflected and because it always travels with the coast on its right, it will now travel in the opposite direction. The energy of the incoming Kelvin wave is transferred through Poincare waves along the enclosed side of the domain to the outgoing Kelvin wave. The final pattern of the SSH and the tidal currents is made up of the sum of the two Kelvin waves. These two can amplify each other and this amplification is maximum when the length of the shelf sea is a quarter wavelength of the tidal wave. Next to that, the sum of the two Kelvin waves result in several static minima's in the centre of the domain which hardly experience any tidal motion, these are called Amphidromic points. In the upper panel of figure 2, the absolute time averaged SSH is shown in red shading and the dotted lines show the zero tidal elevation level at roughly hourly intervals, also known as cotidal lines. Where these lines intersect the tidal elevation is zero during a full tidal period and thus this is the location of the Amphidromic points.
In the real world, the reflected Kelvin wave has a lower amplitude due to energy loss as a result of friction and through the transfer via Poincare waves (lower left panel of animation 1). The tidal currents are proportional to the wave amplitude and therefore also decrease on the side of the reflected wave (lower right panel of animation 1). Finally, the static minima's are no longer in the centre of the domain as wave amplitude is no longer symmetric. Therefore, the Amphidromic points shift towards the side of the reflected wave (lower panel figure 2).
The dynamics of a tidal Kelvin wave in enclosed shelf sea is well manifested and studied in the North Sea.
= Tides in estuaries and basins
=When tides enter estuaries or basins, the boundary conditions change as the geometry changes drastically. The water depth becomes shallower and the width decreases, next to that the depth and width become significantly variable over the length and width of the estuary or basin. As a result the tidal wave deforms which affects the tidal amplitude, phase speed and the relative phase between tidal velocity and elevation. The deformation of the tide is largely controlled by the competition between bottom friction and channel convergence. Channel convergence increases the tidal amplitude and phase speed as the energy of the tidal wave is traveling through a smaller area while bottom friction decrease the amplitude through energy loss. The modification of the tide leads to the creation of overtides (e.g.
M
4
{\displaystyle M_{4}}
tidal constituents) or higher harmonics. These overtides are multiples, sums or differences of the astronomical tidal constituents and as a result the tidal wave can become asymmetric. A tidal asymmetry is a difference between the duration of the rise and the fall of the tidal water elevation and this can manifest itself as a difference in flood/ebb tidal currents. The tidal asymmetry and the resulting currents are important for the sediment transport and turbidity in estuaries and tidal basins. Each estuary and basin has its own distinct geometry and these can be subdivided in several groups of similar geometries with its own tidal dynamics.