Oceanography Lecture Notes Outline
Seiches, tsunami, and tides
I. Contents - Topics
Covered
Seiches
Storm Surges
Tsunami !
Tides
Tides Affect
on Marine Organisms
Tidal Power
II. What is a Seiche?
A. Defined
1. A seiche is a rhythmic rocking back-and-forth of a body
of water within a confining basin
·
Confined basins include
harbors, bays, and inlets
·
Seiche wave periods range
from minutes to
more than a day
2. Each confined body of water has a specific
resonating
frequency dependent on two factors
·
Size or shape of the basin
·
The amount of water in the
basin
3. Energy can be harmonically added to a
seiche, thereby
increasing its amplitude
·
The process of swinging
ever so higher on a swing set is a similar phenomena
4. A seiche in the form a wave that rises and
falls at the
ends of a basin, but with only a
back-and-forth motion
in the middle of the basin is called a standing wave
·
Standing waves oscillate
vertically, with little to no forward movement
B. How Are
Seiches Generated?
1. Seiche waves are generated and set into
motion by a
disturbing force acting on the basin water
·Persistent wind that suddenly stops
·Ocean swell (surf beat)
·Storm surge
·Landslide
·Tsunami
·Tidal bore
C. Coastal Damage
by Seiches is Rare 1. Only when
associated with large storm surge
and spring tides
2.
The rareness is attributed
to the low wave height of
seiches (centimeters to 3 meters max)
III. Storm Surge
A. Defined
1. An abrupt bulge of water
driven ashore by a storm system
·
Hurricanes
·
Winter frontal systems
2. A storm surge can be up
to 1 meter high in deep water
3.
A storm surge can add up to 10 meters in water height
when
it crams up against a shoreline
4.
Technically not a wave
·
It has a crest
·
It does not have a trough
·
It has no period or
wavelength
5. Storm surges are short-lived (typically hours)
a. The time it takes for a storm center to pass
B. How is Storm Surge Generated?
1. Created underneath an atmospheric center of very
low pressure
·
Intense
storm systems like hurricanes
·
Low
pressure causes ocean surface to bulge
·
Bulge
moves with low pressure center
2. When the storm surge meets the shoreline it piles up
very
rapidly
·
Acts
like an intense, very high incoming tide
·
Can
add up to 10 meters of water above normal
sea level
·
Storm
surges are typically accompanied by storm-generated wind waves and swell
C. Coastal Damage by Storm
Surge Can Be Catastrophic
1.
Combination of storm surge, large surf, and high tides
spells
disaster low lying coastal areas
2. Storm
surge waters can batter low lying coastal areas
much
like a small tsunami
3. Storm
surges up to 40 feet high have been extremely
deadly in various shorelines of the world
that are low
lying and have high population densities
·
The
·
IV. Tsunami!
A. Defined
1. Tsunami are very long wavelength shallow water
progressive
(gravity) waves caused by the rapid
displacement
of ocean water
·
Tsunami is mistakenly
called a tidal wave
·
Seismic sea waves are
tsunami
·
Not all tsunamis are seismic
sea waves
B. The Nature of Tsunami
1. Tsunami are shallow water waves
because they always
travel in water depths shallower than ½ their
wavelength
·
Tsunami wavelengths are up
to 200 kilometers
5. Tsunami waves
travel very fast
·
Calculated by the shallow
water wave equation:
C = √gd
where C is speed, g is acceleration
due to gravity, and d
is water depth (typically 15,000 feet in the Pacific)
·
up to 500 miles per hour
·
Can cross the
4. Tsunami waves in open ocean only 1-2 meter in height
·
Ocean vessels on the high seas
wouldn’t notice one
5. Tsunami resemble
a swiftly rising tide (a tidal bore) rather
than a breaking
wave when they make shore
·
Picture a super gigantic
“mush burger” wave
·
Unlike a normal sea wave,
the tsunami wave keeps driving onshore for minutes
C. How
are Tsunami Generated
1. Tsunami
are generated by several water disturbing forces
which acts to displace surface
water
·
Earthquake/Faulting (sea
bottom displacement)
·
Shoreline or underwater landslide
event
·
Volcanic eruption
·
Bolide impact
2. Seismic sea waves are
generated when the ocean bottom is rapidly raised, or lowered, along an
underwater fault zone
during a large
earthquake, i.e. large fault rupture
·
Up-lifted sea bottom causes
an initial “bump” in the ocean surface
Ø Crest of tsunami wave forms first
·
Down-dropped sea bottom
causes an initial “dimple” in the ocean surface
Ø Trough of tsunami wave forms first
3. After a tsunami is generated, the wave typically
disperses
into multiple
crests
·
The first wave often is not
the largest
·
Because of the long
wavelength, the crests may be separated by 10s of minutes or even hours.
D. Tsunami
Are Classified Into Two Categories
1.
Based on their proximity to origin
·
Local
·
Far traveled
2. Local tsunamis
primarily affect a small area and are usually caused by landslides (often
underwater) which are triggered by earthquakes or volcanic eruptions.
·
These are sometimes very
severe and occur with
virtually no
warning.
3. The largest local tsunami on record occurred in
·
From damage to trees, it is
estimated to have reached more than 1500 feet up the mountainside
·
A wave about 150 feet high swept down the bay and out to sea
·
Four of six people aboard three boats anchored in the bay
survived.
4. Tsunami can hit coastlines that are thousands of kilometers
from the point of tsunami generation
5. They are free gravity waves like ocean swell
6. They do lose energy the further they travel
7. The Pacific basin is notorious for abundant far-traveled
tsunami
8. Tsunami can be predicted after an earthquake
D. When
Tsunami Meet the Shoreline
1.
Fast-moving tsunami waves
change radically when they
encounter the
shoreline very
·
Slows down
·
Wavelength shortens
dramatically
·
Tremendous increase in wave
height
·
First wave encountered may
be either the trough or the crest
Ø Trough – Appears like a Super low low tide
Ø Crest - Looks like a
humungous tidal bore
2.
Low-lying areas along
coastlines are at serious risk when a
tsunami hits
·
A very rapid onslaught of
sea water rushes onshore
·
The driving surge pushes
inland as Sea level
3. Examples
of devastating far-traveled tsunami events
E. Tsunami
Prediction and Warning Network
F. Important Tsunami Safety Tips
1. If you are in a coastal community less than 50 feet above
sea level,
and you feel a severe earthquake (one that
makes it almost impossible to stand up, which is
causing substantial damage to buildings, or is opening
cracks in the ground), RUN for the highest point you
can reach within minutes.
·
Once you see the wave, you
cannot outrun it. If all else fails, some people have survived by climbing
trees.
2. Even if you have felt no earthquake, or only a mild one,
a
sudden recession of water is always a danger sign.
·
Run away from the water to high ground.
3. Remember - more
severe waves can follow for hours.
·
Do not return to low-lying
areas for 24 hours.
4.
Ships at anchor should
weigh anchor and head to sea.
5.
Ships at dock should also, if there is a warning due to a distant
earthquake.
·
However, if at dock during
a severe earthquake, it is questionable whether the best choice is to jump
ashore and run inland, or to try to ride it out aboard (loose mooring lines if
possible.)
6.
Tsunami warnings for
distant sites are still inexact.
·
They can warn that a
tsunami might occur, and approximately when, but the danger at a
particular location depends on topography, the particular characteristics of
the wave, and other factors
·
This results in many false alarms, leading people to disregard
alarms when they occur
V. Tides
A. Tides
Defined
1. Tides are the regular rise and fall of sea level that occurs
either once a day (every 24.8
hours) or twice a day
(every 12.4 hours).
2. Tides are waves with very long periods
(24.8 or 12.4
hours) and wavelengths (thousands of
km)
3. Tides are shallow-water waves (that is,
their speed is
slowed by friction with the ocean
bottom) even in the deepest
parts of the ocean.
B. The Equilibrium Theory
1. Tides are caused by the
combination of several forces:
·
Gravitational attraction
between the Earth and moon
·
Gravitational attraction
between the Earth and sun
·
Centripetal "forces" that result from the moon's
orbiting around the Earth and the Earth's orbiting around the sun.
·
Another important factor is
the land blocking the free motion of the tide around the earth
2. The moon is the
strongest gravitational force
·
Being closest, it is
responsible for most of the tide
3. The Earth and Moon are both orbiting around
the
center of gravity of the Earth-moon
pair
·
A point of rotation within,
but not at Earth’s center
·
See Figure 11.13 in the
text
4. At all points of the Earth's surface,
there are two forces
acting to produce lunar tides:
·
The gravity of the moon,
and
·
A centrifugal force that
acts parallel to the Earth-moon axis, outward or away from the moon.
5. Gravity (tidal
forces) becomes weaker with distance
·
The gravitational
attraction of the moon is strongest for the side of the Earth closest to the
moon
·
The gravitational attraction of the moon is weakest for the
opposite side
·
On the other hand, the centrifugal force is the same everywhere
6. Because there is a slight excess of gravity on the side
of
the Earth nearer
the moon, the ocean "bulges" toward
the moon on that
side
7.
Because there is a slight
deficiency of gravity on the side
of the Earth which faces away from the
moon, the ocean
"bulges" away from the moon on
that side, also
8.
The Earth rotates beneath
the bulges
·
We would expect 2 high and
2 low tides each day
·
This in fact occurs in most places
Ø This is termed a semidiurnal tide
·
However, some places have only 1 high and 1 low tide a day
Ø This is termed a diurnal tide
9.
The Earth-Sun system acts
like the Earth-Moon system,
except that the
tide generated is smaller
·
The observed tide is the
sum of lunar and solar tides
10. The relative positions of the Earth, sun, and moon
change during a month
·
When the Earth, sun, and
moon are aligned (new and full lunar phases), the tidal forces reinforce each
other and there are unusually large tides
Ø Termed spring
tides
·
When the Earth, sun, and
moon form a right angle (first and third quarter lunar phase), the lunar and solar
tides partly cancel out, so tides are smaller than average tides
Ø Termed neap tides
11. This model of tides (the equilibrium model) is not useful
for actually
predicting tides
·
Does not take into account
many important factors
Ø Size of the ocean basin
Ø Shape of the ocean basin
Ø Bottom topography of ocean basin
Ø Northern or Southern Hemisphere
12. A more
sophisticated model was created that could
accurately predict the tides – the dynamic model of tides
C. The Dynamic
Theory of the Tides
1. The dynamic theory of tides describes the
tides in terms
of a very
large number (> 400) of factors that influence
them
2. The dynamic
model of tides considers the fact that the
tide is trapped
within each ocean basin
·
Acts like a standing wave which rotates around a
center point called a node
·
In the case of tides, the
node is called an amphidromic point.
3. In the northern hemisphere, tides rotate counterclockwise
due to the Coriolis
effect
4. In the southern hemisphere, tides rotate clockwise
5. Some ocean
basins, due to their shape, have more than
one amphidromic point
·
There are about 12 in the
world's oceans
D. There are
Three Major Types of Tides:
1. Diurnal tides have 1 high and 1 low per day
·
They are found in
Australia, Antarctica, and the Gulf of Mexico
2. Semidiurnal tides
have 2 equal highs and lows each day
·
They are found in the
Atlantic and Indian Oceans
3. Mixed tides have two unequal highs and lows each day.
·
They are found in the
VI. Tides Affect on Marine Life
A. Tides Have Important Effects on Marine
Organisms
1. Tidal
currents are often the strongest currents in coastal
areas
2. Important to migration and reproduction of animals
·
For example, larvae may
rely on such currents to move them toward or away from the coast
·
Another is fish like the
grunion
3. Intertidal
organisms are strongly influenced by the
periodic
advance and retreat of the ocean
·
They are often arranged in patterns
(intertidal zonation) which
depend on the amount of time the area of beach is exposed to the air.
4. Tides affect navigation of ships
·
Depth of bottom
·
Tidal Currents
5. Tides
affect on surfing conditions
·
Surfers rely on tides for
choosing when to surf
·
Some locals are best at low
tide
·
Some spots are best at high
tide
VII. Tidal Power
A. Humans
Have Harnessed the Power of Tides
1. Electrical
energy generation
·
Much like a regular
hydroelectric dam system
·
Better because it can work
both ways
·
An inexhaustible source of
energy
·
Only practical at certain
coastal localities
3.
Flood control purposes
·
Regulate tidal bores and
currents
·
Safer conditions for river
mouths and inlets
·
Also useful for storm surge
events
VIII. Vocabulary Terms