Tsunami.

Presentasi berjudul: "Tsunami."— Transcript presentasi:

1 Tsunami

2 Why did the earthquake cause a tsunami?
Shallow focus earthquake Large volume of oceanic crust displaced The movement of the crust also displaces a large volume of water

3 Tsunami Satu gelombang bergerak ke arah patai dan satu lagi bergerak ke laut terbuka n

4 Tsunami di pantai BUKAN versi raksasa dari gelombang pecah Merupakan gelombang pasang yang sangat cepat, menghalau segala sesuatu di darat, air laut biasanya surut terlebih dahulu

5 Periode Serangkaian gelombang dapat tiba setiap menit

6 Tsunami Gelombang air dangkal. Mereka melintasi lautan dan gelombang tsunami terbentuk setelah mengenai dasar perairan. Di permukaan laut, gelombang ini hampir tidak terdeteksi (3 meter)

7 Wind versus tsunami wave
Wind waves Satu gelombang melibatkan keseluruhan massa air Kecepatan gelombang tergantung pada periode angin 17 mil/jam untuk periode angin selama 5 detik dan 70 mil/jam untuk periode angin selama 20 detik Tsunami Massa air yang sangat besar dengan momentum yang luar biasa

8 Velocity Increase in velocity with an increase in depth
Velocity: v = (g x D) ½ g – acceleration due to gravity; D – depth of water For average D = 5,500 m, v = 232 m/sec (518 mph) Actual observations of tsunami speed peak at 420 to 480 mph Wave will slow as approaches shore, but still fast

9 Kecepatan Tsunami kecepatan tsunami:
Anda menerima informasi bahwa ada gempa bumi di Seward, Alaska, dan itu cukup besar untuk menghasilkan tsunami di kedalaman lautan m. Hitung kecepatan tsunami di kedalaman ini. Kemudian, hitung waktu yang dibutuhkan tsunami untuk mencapai lokasi yang akan terkena dampak berikut: 1. Kodiak, Alaska 2. Pulau Kauai, Hawaii  kecepatan tsunami: S  =  sqrt(9.81m/s2*  4,000m) S  =  sqrt(39,240m2/s2) S  =  198m/s (198m/s)  *  (1km/1,000m)  *  (60s/1min)  *  (60min/1hr)  =  713 km/h Waktu yang dibutuhkan menuju Kodiak : sekitar 32 menit Hawaii : sekitar 6 jam

10 Tsunami: kecepatan Terkait dengan kedalaman air laut
Samudera Pasifik: rata-rata kedalaman kaki Kecepatan di laut terbuka:> 500 mph Model of Cascadia 1700 tsunami

11 Tsunami, Japan, 2011 Tinggi 90 feet Inundasi hingga 2,5 mil
Peringatan dini hanya 8-10 menit

12 Desa Minamisanriku, dimana sampai 10
Desa Minamisanriku, dimana sampai orang-60 persen dari populasi sekarang hilang, menurut kantor berita Telegraph. 44 miles south of Sendai

13 Kota Yagawahama

14 Sendai Airport

15 Japan, 2011 tsunami Milyaran dollar dihabiskan untuk menahan dampak tsunami 40% of pantai Jepang berdiri bangunan pantai setinggi 39 feet Gates close seconds after earthquake

16 Projection of Japan tsunami moving across the Pacific Ocean

17 Santa Cruz dan Emeryville
Crescent City, California

18 Shoreline arrival of tsunami
Tsunami mencapai ketinggian lebih besar ketika mereka memasuki pelabuhan atau ruang sempit lainnya -> 8 m gelombang di pantai terbuka -> 30 m gelombang di pelabuhan sempit Narrow bay, deeper closer to shore Same depth, farther from shore, open shoreline

19 Tsunami Tinggi bertambah
Ketika gelombang mencapai pantai, kecepatan berkurang Tinggi bertambah

20 Tsunami and You If You Feel the Earthquake
Mild shaking for more than 25 seconds: powerful, distant earthquake may have generated tsunami Sea may withdraw significantly, or may rise, before first big wave Water may change character, make unusual sounds

21 Tsunami and You Tsunami Warnings Coastal Maps
Tsunami-hazard map of Hawaii Big Island, based on local topography Coastline mapping of Indonesia, India and Sri Lanka after 2004 tsunami indicated where human activities increased damage and loss of life Removal of vegetation, reefs increased impact of waves Buoys and Pressure Sensors Before 2004, NOAO operated six-buoy warning system in northern Pacific Ocean Funding since provided for 32 buoys around world, transmitting information to scientists New tide-gauge stations and seismometers along coastlines

22 Tsunami and You Insert table 5.4

23 Tsunami and You Simuele Island, Indonesia, 26 December 2004
Daerah berpenduduk terdekat dengan pusat gempa yang berkekuatan 9,2 Richter Setelah goncangan berhenti, warga melarikan diri ke bukit dengan segera Hanya 7 dari jiwa tewas Dari cerita turun temurun dari orang tua: ketika tanah bergetar, lari ke bukit sebelum gelombang raksasa tiba 

24 Applied information from school project
Noticed bubbles and water retreated from the shoreline Notified parents and other hotel residents All moved to higher ground Phuket, Thailand

25 2004 Indonesia earthquake and tsunami

26 Chile earthquake, February 27, 2010

27 Chile earthquake and tsunami
Magnitude 8.8; hypocenter 21 miles Tsunami February 27, 2010

28 Concepcion: moved 10 feet to the west

29 Japan’s tsunami warning system

30 Seismic recording stations

31 Tsunami warning system

32

33 Pacific Tsunami Warning Center: 1967
Alaska: west coast of North America Hawaii: the remainder portion of the Ring of Fire NOAA: National Oceanographic and Atmospheric Administration Pacific Marine Environmental Laboratory

34 Deep-0cean Assessment and Reporting of Tsunami: DART
Goal is to reduce the loss of life and property Eliminate false alarms Stations are positioned in regions that traditionally produce tsunamis

35 Deep-0cean Assessment and Reporting of Tsunami: DART
Tsunami-harbor wave Seafloor pressure recording system An acoustic link is used to transmit data from the pressure recording system The data is relayed via satellite

36 DART Locations

37 DART II

38 Deep-0cean Assessment and Reporting of Tsunami: DART
Tsunami-harbor wave

39 DART locations: Indian Ocean

40 Tsunami Formed when a large volume of water is displaced
When offshore, one set of waves moves onshore and another offshore Waves arrive in a series in a shorter amount of time closer to the epicenter Waves increase velocity with depth of ocean As wave approaches the shoreline: the energy orbital collapses, friction increases along the ocean bottom, wave slows but energy is the same and drives the water onshore Topography of shoreline influences height of surge