Fig. 7.4.1: Water level distribution (input signal: 3 positive single signals, wave height 5 m,
from the north, North Sea 2 km)
Left: after 1.5 hours with realistic depth distribution (T 1800 s)
Flight: after 0.5 hour with constant water depth (h 500 m, T 600 s)
54
7.4 North Sea signal from the north
Figs. 7.4.1-6 show, in their left part, the propagation of the boundary signal described in
section 7.1 (three positive signals, 71800 s, H 5 m). For better physical understanding,
computations were additionally carried out with a constant water depth of 500 m in the entire
North Sea. In these simulations, the same kind of boundary signals were used, but a period
of 600 s.
7.4.1 Propagation
The influence of realistic bottom topography is obvious from the faster propagation in deep
water, in this case the Norwegian Trench. In the north, the simulation shows major local
water level maxima (Figs. 7.4.1 and 7.4.2, left figures). They are caused by directional
changes and subsequent superposition among the single signals due to an inhomogeneous
depth gradient (refraction). These maxima do not occur in the comparative computations with
a flat bottom (right figures).
Diffraction and reflection produce locally very high water levels in bays and estuaries, and
near islands (e.g. Lerwick station, Fig. 7.1.3). Such processes are governed by the shape of
the coastline and the location of islands. They may, however, be subject to modification by
variable bottom topography, which influences the direction and velocity of propagation, cf.
Figs. 7.4.2 and 7.4.3, left figures.
The German coast is located in the wave shadow of Norway. It is reached first by extensions
of the input signal that has weakened on the shelf (Fig. 7.4.4). Later, a secondary signal
generated by superposition of a diffraction pattern also arrives at the coast (Fig. 7.4.6). It is
generated mainly by diffraction and reflection on the British coast. It is better visible in the
flat-bottom simulations but also constitutes a significant signal in model time series using a
realistic topography.
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