Presentation is loading. Please wait.

Presentation is loading. Please wait.

Shallow Water Waves: Tsunamis and Tides Descriptions: Tsunamis, tides, bores Tide Generating Force Equilibrium tide Co-oscillating basins Knauss (1997):

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Shallow Water Waves: Tsunamis and Tides Descriptions: Tsunamis, tides, bores Tide Generating Force Equilibrium tide Co-oscillating basins Knauss (1997):"— Presentation transcript:

1 Shallow Water Waves: Tsunamis and Tides Descriptions: Tsunamis, tides, bores Tide Generating Force Equilibrium tide Co-oscillating basins Knauss (1997): p. 218-222 (tsunamis and seiches) p. 234-244 tides p. 223-226 Kelvin waves MAST-602 Lecture Oct.-14, 2008 (Andreas Muenchow)

2 Tsunamis: … shallow water gravity waves with a continuum of periods from minutes to hours that all propagate at a phase speed of c=(gH) 1/2 … forced by earth quakes and land slides

3 Dec.-26, 2004 Sumatra tsunami: deadliest natural disaster, 225,000 people killed, 30-m high wave Sealevel of Seychelles. Data from the Seychelles Meteorological Office. o Seychelles

4 Tides: … shallow water gravity waves with generally discrete periods near 12 hours (semi-diurnal) and 24 hours (diurnal) that all propagate at phase speeds c=(gH) 1/2 … like all waves, they can break(tidal bore movie) … forced by periodicities of the sun-moon-earth orbits Tsunamis: … shallow water gravity waves with a continuum of periods from minutes to hours that all propagate at a phase speed of c=(gH) 1/2 … forced by earth quakes and land slides

5 Tides High or low?

6 Tides High it was: Nova Scotia, Canada

7 Semi-diurnal Diurnal Mixed Tidal Wave Forms: Why do they all look different?

8 Tidal Sealevel Amplitude (color) and Phase (white contors) for the lunar semi-diurnal M 2 constituent (T=12.42 hours)

9 Energy Density on a log-scale Frequency (cycles/day) Muenchow and Melling 2008) in review Tidal Currents: Observations Predictions

10 Tide Generating Force is the vector sum of: 1.Gravitational force exerted by the moon on the earth; 2.Centrifugal force (inertia) of the revolution about the common center of mass of the earth-moon system. What’s wrong with this picture?

11 Tide Generating Force is the vector sum of: 1.Gravitational force exerted by the moon on the earth; 2.Centrifugal force (inertia) of the revolution about the common center of mass of the earth-moon system. What’s wrong with this picture? > inertia>gravity

12 Centripetal and Centrifugal forces Centripetal force is the actual force that keeps the ball “tethered:” “string” can be gravitational force Centrifugal force is the pseudo- force (apparent force) that one feels due to lack of awareness that the coordinate system is rotating or curving (inertia) centrifugal acceleration =  2 R

13 Revolution with Rotation Moon around Earth (“dark” side of the moon): R is not constant on the surface Revolution without Rotation Earth around Sun (summer/winter cycles): R is constant on the surface © 2000 M.Tomczak centrifugal acceleration =  2 R

14 Particles revolve around the center of gravity of the earth/moon system All particles revolve around this center of gravity without rotation … … and execute circular motion with the same radius R  centrifugal force the same everywhere

15 All particles revolve around this center of gravity without rotation … … and execute circular motion with the same radius R  centrifugal force the same everywhere Revolution without rotation

16 Sun or Moon © 1996-1999 M. Tomczak Force of gravity between two masses M and m that are a distance r apart Centrifugal acceleration same everywhere on the surface of earth but, gravitational acceleration is NOT because of distance r:

17 Tide Generating Force = Gravity-Centrifugal Force Local vertical component:1 part in 9,000,000 of g Local horizontal component:all that matters Horizontal tide generating force (hTGF) moves waters around

18 Equilibrium Tide: Diurnal Inequality  (t)=cos(  1 t)+cos(  2 t)  1 =2  /12.42 (M 2 )  2 =2  /23.93 (K 1 )

19  (t)=A*cos(  1 t)+B*cos(  2 t)  1 =2  /12.42 (M 2 )  2 =2  /23.93 (K 1 ) A>Bsemi-diurnal A~Bmixed A<Bdiurnal

20 Semi-diurnal Diurnal Mixed Tidal Wave Forms: Diurnal inequality plus spring/neap cycles

21 = mass/r 3 hTGF= Sun’s tide-generating force (hTGF) is 46% of the moon’s hTGF

22

23 Red: sun’s bulge Grey: moon’s bulge Blue: rotating earth Dials: 1 lunar month (29 days, outer dial) 1 solar day (24 hours, inner dial) Equilibrium Tide: Spring/Neap cycles  (t)=cos(  1 t)+cos(  2 t)  1 =2  /12.42 (M 2 )  2 =2  /12.00 (S 2 )

24 Equilibrium Tide: Other periodicities, e.g., lunar declination

25 Equilibrium tide: Other periodicities Orbital planes all change declinations slowly

26 Homework ---> head to Australia http://www.es.flinders.edu.au/~mattom/IntExerc/basic5/ Basic Exercises in Physical Oceanography Exercise 5: Tides Prof. Mathias Tomczak

27

28 Currents Sealevel Time

29 © 1996 M. Tomczak Kelvin wave propagation In the North Sea

Download ppt "Shallow Water Waves: Tsunamis and Tides Descriptions: Tsunamis, tides, bores Tide Generating Force Equilibrium tide Co-oscillating basins Knauss (1997):"

Similar presentations

Tides.

Tides.
Chapter 10 CIRCULAR MOTION

Chapter 10 CIRCULAR MOTION
Tides Fig. 10-6 Fig. 10-7.

Tides Fig Fig
Space Grades 3-5.

Space Grades 3-5.
Tides Tide producing forces Semi-diurnal; diurnal tides

Tides Tide producing forces Semi-diurnal; diurnal tides
© 2011 Pearson Education, Inc. CHAPTER 9 Tides. © 2011 Pearson Education, Inc. Chapter Overview Tides are the rhythmic rise and fall of sea level. Tides.

© 2011 Pearson Education, Inc. CHAPTER 9 Tides. © 2011 Pearson Education, Inc. Chapter Overview Tides are the rhythmic rise and fall of sea level. Tides.
© 2011 Pearson Education, Inc. CHAPTER 9 Tides. © 2011 Pearson Education, Inc. What are Tides? Tides – periodic raising and lowering of ocean sea level.

© 2011 Pearson Education, Inc. CHAPTER 9 Tides. © 2011 Pearson Education, Inc. What are Tides? Tides – periodic raising and lowering of ocean sea level.
Unit 8 - Tides.

Unit 8 - Tides.
Tides.

Tides.
Fig. 11-CO, p. 297. Fig. 11-1a, p. 299 Fig. 11-1b, p. 299.

Fig. 11-CO, p Fig. 11-1a, p. 299 Fig. 11-1b, p. 299.
Tides - The Last Wave Information by the University of California (Riverside) updated in 2014.

Tides - The Last Wave Information by the University of California (Riverside) updated in 2014.
Essentials of Oceanography 7th Edition

Essentials of Oceanography 7th Edition
Chapter 10: Tides Fig. 10-6 Fig. 10-7.

Chapter 10: Tides Fig Fig
Phases of the Moon Data http://aa.usno.navy.mil/data/docs/MoonPhase.html#y2001.

Phases of the Moon Data
CHAPTER 9 Tides. Overview Rhythmic rise and fall of sea level Rhythmic rise and fall of sea level Very long and regular shallow-water waves Very long.

CHAPTER 9 Tides. Overview Rhythmic rise and fall of sea level Rhythmic rise and fall of sea level Very long and regular shallow-water waves Very long.
Ocean Tides and Sea Level - tide – “daily rise and fall of sea level” (C&D) - tide – distortions of sea by gravitational attraction of Moon and Sun on.

Ocean Tides and Sea Level - tide – “daily rise and fall of sea level” (C&D) - tide – distortions of sea by gravitational attraction of Moon and Sun on.
Chapter 9 Tides.

Chapter 9 Tides.
CHAPTER 9 Tides.

CHAPTER 9 Tides.
Essentials of Oceanography

Essentials of Oceanography
TIDES. Tides - periodic rise and fall of sea surface Generated by the gravitational attraction of the Sun and Moon on the oceans moon closer to earth,

TIDES. Tides - periodic rise and fall of sea surface Generated by the gravitational attraction of the Sun and Moon on the oceans moon closer to earth,

Similar presentations

Ads by Google