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Sabtu, 12 Maret 2011

Danau Terbesar di Dunia

1. Laut Kaspia
Lokasi: Azerbaijan, Rusia, Kazakhstan, Turkmenistan, Iran
Luas (km²): 394.299
Panjang (km): 1.199
Kedalaman maksimum (m): 946

Laut Kaspia atau Laut Mazandaran merupakan sebuah laut yang terkurung daratan antara Asia, Azerbaijan, Iran (provinsi Guilan, Mazandaran dan Golestan), Turkmenistan dan Kazakhstan, dan Eropa (Rusia), Dagestan, Kalmykia dan Oblast Astrakhan. Dia merupakan kumpulan air terbesar di daratan, dengan luas permukaan 371.000 km², dan oleh karena itu memiliki karakteristik yang dimiliki oleh laut dan danau. Dia sering digolongkan sebagai danau terbesar dunia, meskipun ia tidak mengandung air tawar tapi air asin.


2. Superior
Lokasi: Amerika Serikat, Kanada
Luas (km²): 82.414
Panjang (km): 616
Kedalaman maksimum (m): 406

Danau Superior adalah Danau Besar Amerika Utara terbesar yang membatasi Ontario di Kanada, dan Minnesota, Wisconsin dan Michigan di Amerika Serikat. Dia merupakan danau air tawar terbesar di dunia dalam luas permukaan.


3. Victoria
Lokasi: Tanzania, Uganda
Luas (km²): 69.485
Panjang (km): 322
Kedalaman maksimum (m): 82

Danau Victoria atau Victoria Nyanza (juga dikenal sebagai Ukerewe) adalah Danau Terbesar di Afrika, danau tropis terbesar di dunia, dan danau air tawar kedua terbesar dunia dalam luas permukaan setelah Danau Superior. Danau ini terletak dalam dataran tinggi di bagian barat Great Rift Valley Afrika dan diatur oleh Tanzania, Uganda, dan Kenya.

4. Huron
Lokasi: Amerika Serikat, Kanada
Luas (km²): 59.596
Panjang (km): 397
Kedalaman maksimum (m): 229

Danau Huron ialah salsh satu dari 5 Danau Besar Amerika. Merupakan yang ke-3 dari muara. Seperti Danau Ontario, Danau Erie, dan Danau Superior, danau ini juga dimiliki bersama antara Amerika Serikat dan Kanada


5. Michigan
Lokasi: Amerika Serikat
Luas (km²): 58.016
Panjang (km): 517
Kedalaman maksimum (m): 281

Danau Michigan adalah salah satu dari 5 Danau Besar di Amerika Utara yang membatasi negara bagian Amerika Serikat: Indiana, Illinois, Wisconsin, dan Michigan. Chicago merupakan kota terbesar di Danau Michigan.

6. Aral
Lokasi: Kazakhstan, Uzbekistan
Luas (km²): 59.596
Panjang (km): 397
Kedalaman maksimum (m): 229

Danau ini terletak di Asia Tengah yaitu di Kazakhstan utara dan Uzbekistan di selatan.


7. Tanganyika
Lokasi: Tanzania, Republik Kongo
Luas (km²): 32.893
Panjang (km): 676
Kedalaman maksimum (m): 1.435

Danau ini merupakan danau ngarai terbesar dan terdalam di Afrika atau nomor 2 terdalam di dunia serta menyimpan cadangan air tawar terbesar yang berada di Western Rift di daerah Great Rift Valley dan berada di kawasan 4 negara yaitu Burundi, Republik Demokratik Kongo, Tanzania dan Zambia,

8. Baikal
Lokasi: Rusia
Luas (km²): 31.500
Panjang (km): 636
Kedalaman maksimum (m): 1.741

Danau Baikal atau juga dikenal dengan Mata Biru Siberia dan Laut Suci adalah danau terdalam dan tertua di dunia dan terbanyak (dalam isi) air tawarnya di Bumi. Danau ini berisi lebih dari 20% air tawar dunia dan lebih dari 90% air tawar Russia.

9. Great Bear
Lokasi: Kanada
Luas (km²): 31.080
Panjang (km): 373
Kedalaman maksimum (m): 82





10.Nyasa
Lokasi: Malawi, Mozambik, Tanzania
Luas (km²): 30.044
Panjang (km): 579
Kedalaman maksimum (m): 706.



Source : wikipedia

Laut Terdalam di Dunia

Laut merupakan kumpulan air asin dalam area luas yang menggenangi daratan dan membaginya menjadi benua dan pulau. Karakteristik laut bermacam-macam. Berikut ini adalah daftar 10 laut terdalam di dunia.

1. Samudra Pasifik

Selain menduduki peringkat pertama sebagai laut terdalam, Samudra Pasifik juga memecahkan rekor sebagai peringkat pertama laut terluas. Samudra Pasifik membentang dari Samudra Selatan, Asia, Australia, hingga belahan bumi bagian barat. Samudra ini menutupi satu pertiga permukaan bumi. Bagian terdalam di Samudra Pasifik adalah Palung Mariana, yaitu 11.033 m. Palung Mariana juga sekaligus sebagai titik terendah dari permukaan bumi.

2. Samudra Atlantik

Samudra Atlantik membentang mulai dari bagian utara bumi melalui Samudra Arktik hingga ke bagian selatan bumi melalui Lintasan Drake. Samudra ini menutupi 1/5 permukaan bumi. Bagian terdalam Samudra Atlantik adalah Palung Puerto Rico, yaitu 8.605 m.

3. Samudra Hindia

Samudra Hindia meliputi perairan di antara Afrika, Samudra Selatan, Asia, dan Australia. Bagian terdalam samudra ini adalah Palung Jawa, yang berkedalaman 7.258 m. Palung Jawa terletak di timur laut Samudra Hindia.

4. Laut Karibia

Laut Karibia merupakan bagian dari Samudra Atlantik yang terletak di belahan bumi bagian barat. Pulau-pulau yang terletak di sekitar Laut Karibia disebut negara-negara Karibia. Bagian terdalam laut ini adalah Cayman Trough dengan kedalaman 7.686 m. Cayman Trough terletak di antara Pulau Cayman dan Jamaika. Cayman Trough ditengarai memiliki celah gunung api terdalam di dunia yang membujur di dasar Laut Karibia.

5. Laut Jepang

Laut Jepang merupakan laut tepi bagian dari Samudra Pasifik bagian barat. Laut Jepang dibatasi oleh Jepang, Korea Selatan, Korea Utara, dan Rusia. Luas permukaannya sekitar 978.000 km. Bagian terdalam Laut Jepang adalah Palung Jepang, yaitu 3.742 m.

6. Teluk Meksiko

Teluk Meksiko merupakan bagian kecil dari Samudra Atlantik. Teluk Meksiko dikelilingi oleh Meksiko di bagian barat dan selatan serta dibatasi oleh Amerika di bagian utara dan barat. Teluk ini memiliki luas 1,6 juta km persegi. Teluk Meksiko berkedalaman rata-rata 1.614 m.

7. Laut Mediterania

Laut Mediterania terhubung dengan Samudra Atlantik yang dikelilingi oleh Mediterania. Laut ini hampir melingkungi seluruh dataran di bagian utara Anatolia dan Eropa, di bagian selatan Afrika, dan di bagian timur Levant. Luas permukaannya meliputi 2,5 juta km persegi. Laut Mediterania memiliki kedalaman rata-rata 1.501 m.

8. Laut Bering

Laut Bering meliputi perairan di Samudra Pasifik yang dibatasi oleh Semenanjung Alaska dan Kepulauan Aleutian. Luas permukaannya mencapai 2 juta km persegi. Kedalaman rata-rata Laut Bering adalah 1.491 m.

9. Laut Cina Selatan

Laut Cina Selatan merupakan laut di tepian Samudra Pasifik yang meliputi dari wilayah Singapura dan Selat Malaka hingga Selat Taiwan. Laut ini memiliki luas 3.500.000 km persegi. Dari luasnya, laut ini termasuk laut dengan luas terbesar kedua setelah lima samudra. Laut Cina Selatan memiliki kedalaman rata-rata 1.463 m.

10. Laut Hitam

Laut Hitam merupakan bagian dari Samudra Atlantik. Laut ini terletak di antara Eropa, Anatolia, dan Kaukasus. Laut ini memiliki luas permukaan 436.400 km dengan kedalaman rata-rata 1.190 m.

http://www.anneahira.com/laut-terdalam-di-dunia.htm

10 Ikan Tercantik di Dunia

1. African Cichlids

Ikan ini diucapkan sebagai “Sick-Lids”. Ikan ini ditemukan di 3 danau di Afrika: Malawi, Tanganyika, dan Victoria. Spesies yg ada di Danau Victoria jumlahnya kurang beragam dan kurang berwarna-warni dibandingkan dengan lainnya. Biasanya mereka tumbuh hingga 6-7 inchi, dengan pengecualian untuk Spesies Frontosoa, yg bisa tumbuh sampe 12-14 inchi. Ikan2 ini adalah ikan2 air tawar yg bisa dengan gampang dipiara di akuarium rumahan. Selain di Afrika, ada juga spesies ikan ini yg idup di perairan Amazon, tapi ukurannya lebih besar dan lebih agresif dari yg di Afrika.

2. Parrotfish

Dinamakan demikian karena bentuk mulutnya yg mirip paruh burung. Ikan ini menggunakan mulutnya yg seperti paruh itu untuk memecah dan memakan invertebrata kecil yg hidup di daerah koral. Biasanya mereka akan memakan utuh2 bebatuan koral atau pasir2 laut lalu mengunyah invertebrata yg ada di dalamnya, lalu membuang sisa2nya.

3. Regal Tang

Ini ikan yang ada di Finding Nemo bukan sih? Btw, ikan ini tergolong dalam family Surgeonfish, yg memiliki pisau kecil dari zat kapur yg dapat disembunyikan di depan sirip ekornya. Pisau kecil ini digunakan terutama untuk sistem pertahanan dalam menghadapi predator.

4. Coral Beauty

Ikan ini tergolong dalam Angelfish. Ikan2 ini bisa disimpan dalam akuarium2 rumahan dan dapat bertahan hidup dengan baik di dalam habitatnya (hardy).

5. Flame Angel

Ikan ini memikiki hubungan dekat dengan Coral Beauty. Sifatnya sama seperti Coral Beauty, tapi sifatnya tidak ‘seteguh’ Coral Beauty.

6. Koi

Ada banyak variasi warna dari ikan koi (sekitar 100an). Koi dapat memiliki warna oranye, merah, putih, keemasan, atau hitam. Beberapa penggemar koi rela membayar ribuan dolar untuk seekor koi hanya untuk mencari pola warna koi yg langka.

7. Moorish Idol

Ikan ini tergolong susah untuk dipiara di akuarium rumahan, dan juga sangat mahal harganya. Di sumber yg gua baca, ga ada keterangan lebih lanjut untuk ikan ini. Mau googling?

8. Lionfish

Ikan ini disebut juga Zebrafish. Tulang belakangnya itu memiliki racun yg sangat menyakitkan dan cukup efektif. Orang yg memeliharanya pastinya harus ati2 kalo mo membersihkan akuariumnya

9. Discus
http://listverse.files.wordpress.com/2008/08/pompadour-discus-tm.jpg
Ikan ini merupakan spesies ikan air tawar yg mungkin merupakan ikan air tawar yg paling cantik. Harganya juga mahal banget: anakan yg panjangnya 3 inchi berkisar antara $50-$80.

10. Mandarinfish

Ada 2 varietas dari spesies ini: Mandarinfish standar dan Psychedelic Mandarin. Yang standar biasanya memiliki pola dan warna yg lebih bagus dibanding Psychedelic. Harganya ga lebih dari $20 per ekor, tapi yg jadi masalah adalah makanannya. Mereka cuma memakan mikro-invertebrata yg hidup di bebatuan koral. Untuk bisa memeliharanya di akuarium rumah, kita perlu memiliki bebatuan koral yg cukup di dalam akuarium selama sebulan untuk membiarkan si ikan beradaptasi dengan lingkungan barunya.


http://www.beritaunik.net/top-10/10-ikan-tercantik-di-dunia.html

Manusia Tertinggi di Dunia

Berikut adalah nama-nama manusia yang dijuluki sebagai raksasa karena tinggi badannya yang fantastis yang pernah ada didunia sepanjang sejarah,diantara mereka ada juga yang masih hidup hingga saat ini...


1.Robert Wadlow,8′ 11.1″
Pasti sudah pada tahu dong dengan raksasa satu ini,kemarin disiarin di salah satu televisi swasta di indonesia,Robert Wadlow adalah manusia raksasa tertinggi dalam sejarah. Dia sering disebut sebagai Alton raksasa karena ia datang dari Alton, Illinois. Pada saat kematiannya ia ditimbang 440 pon dan tidak menunjukkan tanda-tanda berhenti berkembang. Dia lahir tahun 1918, tertua dari lima bersaudara. Dia meninggal pada usia 22 tahun akibat infeksi yang disebabkan oleh lecet pada ankle. Peti mati-Nya ditimbang setengah ton dan 12 pallbearers diperlukan untuk melaksanakan. Dia telah dikuburkan dalam sebuah kubah solid beton, keluarganya memiliki ketakutan bilamana tubuhnya akan Diintervensi dengan rasa ingin tahu oleh para pencari berita.

2.Johan Aason,8′ 9-1/4″
Johan dilahirkan di Amerika setelah beberapa tahun ibunya pindah dari Norwegia. Menariknya ibunya juga raksasa dengan tinggi badan 7'2 ". Menurut sertifikat kematiannya dari Mendocino Rumah Sakit, pada saat meninggal tercatat tinggi badannya 9'2 "- jika hal ini benar, maka ia adalah manusia paling tinggi didunia sepanjang sejarah. Dia dikuburkan di Montana.

3.John Rogan,8′9″
John Rogan lahir pada 1868 dan dia tumbuh normal sampai umur 13 tahun.tingginya tercatat sampai dia meninggal dunia adalah 8'9 ". Karena penyakit dia ditimbang hanya 175 pon. Dia meninggal di 1905 akibat komplikasi dari penyakit.

4.John F Carroll,8′7″
John Carroll (lahir pada 1932) dilahirkan di Buffalo, New York dan dikenal sebagai Buffalo raksasa. Meskipun banyak perawatan medis, dia tumbuh di tingkat yang sangat cepat. Dia tumbuh tujuh inci dalam beberapa bulan. Dia meninggal pada tahun 1969 dan saat itu ketinggianya tidak dicatat pada saat meninggal,namum dipercaya bahwa ia memiliki tinggi badan hampir sembilan kaki.

5.Leonid Stadnyk,8′5″
Leonid Stadnyk lahir pada tahun 1971 di Ukraina. Dia adalah ahli bedah hewan terdaftar dan tinggal bersama ibunya. Saat ini beliau tercatat sebagai manusia tertinggi menurut Guinness Book of Records. Sekelompok pebisnis ukraina menyumbangkan antene parabola dan komputer untuk Stadnyk dan sekarang ia memiliki akses Internet.

6.Al Tomaini,8′4.5″
Al Tomaini adalah seorang raksasa yang diklaim memiliki ketinggian 8'4 "(walaupun Guinness Book of Records menyatakan bahwa dia 7'4"). Beratnya 356 pon (162 kg) dan pakai sepatu ukuran 27, Al kebanyakan hidupnya sebagai sirkus raksasa. Dia bekerja dengan sirkus di Great Lakes Exposition di Chicago, pada 1936, saat itu dia bertemu wanita yang kemudian menjadi istrinya , Jeanie Tomaini. Jeanie lahir tanpa kaki dan hanya memiliki tinggi 2 kaki 6 in (76 cm). Setelah pensiun dari sirkus, ia menetap di Jeanie sirkus komunitas Giant's Camp, Gibsonton, Florida.

7.Ella Ewing,8′4″
Ella Ewing lahir di Missouri pada tahun 1872. Dia dikenal sebagai 'Missouri Giant'. Dia tumbuh normal sampai usia 7, yang pada waktu ia mulai tumbuh pesat.karena kurangnya catatan dia tidak terdaftar dalam Guinness Book of Records. Ia berkesempatan menampilkan sisi-aneh sampai dia meninggal pada tahun 1913 karena tuberkulosis.

8.Edouard Beaupré,8′3″
Édouard Beaupré, lahir pada 1881,manusia kuat, dan bintang di Barnum dan Baileys. Dia adalah anak tertua dari 20 bersaudara dan dilahirkan di Kanada. saat usianya sembilan tahun tingginya sudah mencapai 6 kaki. Sertifikat kematiannya menunjukkan dia memiliki tinggi badan 8'3 "dan masih berkembang. Sebagai orang kuat, maka fitur ini crouching bawah menghalangi pengangkatan dan kuda pada bahu. Dia dilaporkan mengangkat kuda seberat 900 pound. Dia meninggal di 1904 karena tuberkulosis.

9.Väinö Myllyrinne,8′3″
Myllyrinne dilahirkan di Finlandia pada 1909. Pada satu titik dia secara resmi dijuluki manusia tetinggi didunia. Pada usia 21 tingginya mencapai 7 kaki 3,5 inci, dan ditimbang 31 batu. Dia mengalami pertumbuhan lain setelah serangan yang membawanya kepada akhir ketinggian 8 kaki 3 inci. Dia meninggal pada tahun 1963.

10.Bernard Coyne,8'2"
Coyne lahir pada 1897 di Iowa, Amerika Serikat. tahun 1918 Dunia tercatat memiliki tinggi badan 8 kaki. Guinness buku catatan entri menyatakan bahwa dia menolak masuk ke perang karena dia tinggi. Pada saat kematiannya itu mungkin dia telah mencapai ketinggian 8 kaki 4 inci. Dia meninggal di 1921 karena penyakit pada hati dan masalah dgn kelenjar. Dia dimakamkan di tempat kelahirannya,peti matinya dibuat khusus ekstra besar.


http://blog-artikel-menarik.blogspot.com/2008/10/10-manusia-manusia-tertinggi-di-dunia.html

Minggu, 06 Maret 2011

10 Negara Terkaya di Dunia

10 Negara Terkaya di Dunia

Kekuatan ekonomi suatu negara biasanya diukur melalui Produk Domestik Bruto (PDB). Menilik angka itu, Amerika Serikat masih menduduki posisi tertinggi sebagai negara kaya melampaui China dan Jepang, Agustus silam.
Namun, PDB tidak mampu menunjukkan kekayaan negara yang sesungguhnya karena bisa jadi uang itu hanya terkonsentrasi di sejumlah pengusaha, bukan pemerintah. Itulah mengapa nilai Pendapatan Nasional Bruto (PNB) menjadi penting untuk mengukur kekayaan suatu negara.

Berikut 10 Negara Terkaya di Dunia dengan PNB tertinggi per kapita, berdasar data terbaru Bank Dunia, seperti dikutip dari laman Daily Finance:

1. Luxemburg
PNB per kapita: $58,810
Tingkat buta huruf: 1%
Tingkat pengangguran: 4,8%
Anggaran belanja pendidikan per PDB: 3,7%

Merupakan daratan kecil yang berbatasan dengan Prancis, Jerman, dan Belgia. Diapit sejumlah negara besar, negara ini tumbuh menjadi salah satu pusat bisnis utama di Benua Eropa. Dalam tiga tahun ke depan, negara ini berencana menyediakan layanan bandwidth dengan kapasitas supertinggi untuk mendorong pengembangan ekonomi digital yang canggih.

2. Norwegia
PNB per kapita: $55,190
Tingkat buta huruf: 0%
Tingkat pengangguran: 1,7%
Anggaran belanja pendidikan per PDB: 6,7%

Merupakan negara superkaya yang mendapat keuntungan besar dari ekspor minyak bumi pada 1970-an. Pendapatan utama negara ini berasal dari sektor minyak dan gas, juga teknologi dan komunikasi. Saking kayanya, negara ini mampu mendanai berbagai program sosial dan pendidikan tanpa membebani pajak. Tak heran jika tak ada warga buta huruf di sana.

3. Kuwait
PNB per kapita: $53,390
Tingkat buta huruf: 6%
Tingkat pengangguran: 1,3%
Anggaran belanja pendidikan per PDB: 3,8%

Negara kecil di Timur Tengah ini memiliki 9 persen dari cadangan minyak dunia. Tidak seperti negara penghasil minyak di sekitarnya, negara ini cukup stabil secara politik. Dibanding dengan negara Teluk lainnya, tingkat pendidikan di Kuwait cukup baik. Daya serap tenaga kerja mencapai lebih 98 persen, baik di bidang perminyakan atau ekspor semen dan bata.

4. Macau
PNB per kapita: $52,410
Tingkat buta huruf: 7%
Tingkat pengangguran: 3%
Anggaran belanja pendidikan per PDB: 2,2%

Daerah administrasi khusus di daratan China ini mendapat banyak pemasukan dari ekspor tekstil dan aneka produk manufaktur. Negara ini juga sangat terkenal sebagai salah satu destinasi perjudian dunia yang cukup masyur. Bahkan pada 2006, pendapatan dari sektor judi melebihi Las Vegas. Mayoritas warga memanfaatkannya sebagai ladang bisnis dengan membuka kasino, hotel, dan pembangunan resor untuk menarik wisatawan mancanegara.

5. Brunei PNB per kapita: $50,920
Tingkat buta huruf: 5%
Tingkat pengangguran: 3,7%
Anggaran belanja pendidikan per PDB: 3,7%

Seperti Norwegia dan Kuwait, sumber utama pendapatan pemerintah adalah dari industri minyak. Sebanyak 60 persen warganya bergantung hidup di sektor itu. Kemapanan finansial membuat pemerintah sanggup memberikan pendidikan gratis hingga perguruan tinggi. Sekadar catatan, Sultan Brunei bahkan pernah menjadi orang terkaya di dunia. Namun belakangan, ada kekhawatiran, menipisnya cadangan minyak mentah akan menjatuhkan standar hidup negara itu.
6. Singapura
PNB per kapita: $50,780
Tingkat buta huruf: 5%
Tingkat pengangguran: 3,95%
Anggaran belanja pendidikan per PDB: 2,2%

Singapura mempromosikan diri sebagai pelabuhan yang ramah bagi perdagangan internasional. Pemerintah setempat sangat ketat mengontrol perekonomian rakyat melalui kemajuan bidang industri elektronik dan farmasi. Selain mengedepankan kesejahteraan umum dan jasa publik, pemerintah sangat peduli terhadap tingkat pendidikan masyarakatnya.

7. Amerika Serikat
PNB per kapita: $46,760
Tingkat buta huruf: 1%
Tingkat pengangguran: 9,6%
Anggaran belanja pendidikan per PDB: 5,6%

Jumlah penduduk dan kondisi geografis membuat negara adidaya ini tak muncul sebagai negara paling kaya di dunia. Bahkan angka pengangguran dua kali Luxemburg. Negara ini mengedepankan perekonomi kapitalis yang tak terlalu memprioritaskan program sosial. Namun, negara ini tak ragu menghabiskan anggaran besar untuk pendidikan. Meski tergolong maju, kesenjangan sosial-ekonomi di negara ini cukup kentara.

8. Hong Kong
PNB per kapita: $44,090
Tingkat buta huruf: 3,4%
Tingkat pengangguran: 3,6%
Anggaran belanja pendidikan per PDB: 3,3%

Ekonomi negara ini sangat bergantung pada re-ekspor sejumlah produk. Hong Kong mendapat keuntungan dari transisi ekonomi eksportir industri ke pusat perbankan internasional. Pemerintah Hong Kong pro perdagangan bebas. Negara ini memprioritaskan anggarannya untuk kesejahteraan publik dan pendidikan warganya.

9. Swiss
PNB per kapita: $43,440
Tingkat buta huruf: 1%
Tingkat pengangguran: 4%
Anggaran belanja pendidikan per PDB: 5,3%

Masyarakat Swiss mendapat keuntungan dari kebijakan pemerintah yang sangat ramah bisnis. Ini membuat Swiss menjadi pusat investasi dan perbankan internasional. Kebijakan pajak yang sangat ringan juga membuat Swiss tumbuh bak surga bagi para pengusaha kaya dunia untuk menghamburkan uangnya. Sektor jasa makmur telah berkembang untuk memenuhi tuntutan kelompok tersebut. Negara ini juga mendapat keuntungan besar dari ekspor mesin industri dan bahan kimia.

10. Belanda
PNB per kapita: $40,940
Tingkat buta huruf: 1%
Tingkat pengangguran: 3%
Anggaran belanja pendidikan per PDB: 5,5%

Pemerintah Belanda memainkan peran aktif dalam mempertahankan standar hidup tinggi bagi warganya. Belanda adalah model kebijakan ekonomi sosial liberal dan laissez-faire. Belanda memiliki ekonomi pasar bebas, yang didukung kekuatan pasar penyulingan minyak bumi dan industri mesin listrik. Kebijakan sosial liberal juga mendatangkan keuntungan melalui sektor obat-obatan terlarang dan wisata seks


sumber : vivanews

Kamis, 03 Maret 2011

REOG Ponorogo

Reog adalah salah satu kesenian budaya yang berasal dari Jawa Timur bagian barat-laut dan Ponorogo dianggap sebagai kota asal Reog yang sebenarnya. Gerbang kota Ponorogo dihiasi oleh sosok warok dan gemblak, dua sosok yang ikut tampil pada saat reog dipertunjukkan. Reog adalah salah satu budaya daerah di Indonesia yang masih sangat kental dengan hal-hal yang berbau mistik dan ilmu kebatinan yang kuat.
Sejarah
Pertunjukan reog di Ponorogo tahun 1920. Selain reog, terdapat pula penari kuda kepang dan bujangganong.

Pada dasarnya ada lima versi cerita populer yang berkembang di masyarakat tentang asal-usul Reog dan Warok [1], namun salah satu cerita yang paling terkenal adalah cerita tentang pemberontakan Ki Ageng Kutu, seorang abdi kerajaan pada masa Bhre Kertabhumi, Raja Majapahit terakhir yang berkuasa pada abad ke-15. Ki Ageng Kutu murka akan pengaruh kuat dari pihak rekan Cina rajanya dalam pemerintahan dan prilaku raja yang korup, ia pun melihat bahwa kekuasaan Kerajaan Majapahit akan berakhir. Ia lalu meninggalkan sang raja dan mendirikan perguruan dimana ia mengajar anak-anak muda seni bela diri, ilmu kekebalan diri, dan ilmu kesempurnaan dengan harapan bahwa anak-anak muda ini akan menjadi bibit dari kebangkitan lagi kerajaan Majapahit kelak. Sadar bahwa pasukannya terlalu kecil untuk melawan pasukan kerajaan maka pesan politis Ki Ageng Kutu disampaikan melalui pertunjukan seni Reog, yang merupakan "sindiran" kepada Raja Bra Kertabumi dan kerajaannya. Pagelaran Reog menjadi cara Ki Ageng Kutu membangun perlawanan masyarakat lokal menggunakan kepopuleran Reog.

Dalam pertunjukan Reog ditampilkan topeng berbentuk kepala singa yang dikenal sebagai "Singa Barong", raja hutan, yang menjadi simbol untuk Kertabumi, dan diatasnya ditancapkan bulu-bulu merak hingga menyerupai kipas raksasa yang menyimbolkan pengaruh kuat para rekan Cinanya yang mengatur dari atas segala gerak-geriknya. Jatilan, yang diperankan oleh kelompok penari gemblak yang menunggangi kuda-kudaan menjadi simbol kekuatan pasukan Kerajaan Majapahit yang menjadi perbandingan kontras dengan kekuatan warok, yang berada dibalik topeng badut merah yang menjadi simbol untuk Ki Ageng Kutu, sendirian dan menopang berat topeng singabarong yang mencapai lebih dari 50kg hanya dengan menggunakan giginya [2]. Populernya Reog Ki Ageng Kutu akhirnya menyebabkan Kertabumi mengambil tindakan dan menyerang perguruannya, pemberontakan oleh warok dengan cepat diatasi, dan perguruan dilarang untuk melanjutkan pengajaran akan warok. Namun murid-murid Ki Ageng kutu tetap melanjutkannya secara diam-diam. Walaupun begitu, kesenian Reognya sendiri masih diperbolehkan untuk dipentaskan karena sudah menjadi pertunjukan populer diantara masyarakat, namun jalan ceritanya memiliki alur baru dimana ditambahkan karakter-karakter dari cerita rakyat Ponorogo yaitu Kelono Sewondono, Dewi Songgolangit, and Sri Genthayu.

Versi resmi alur cerita Reog Ponorogo kini adalah cerita tentang Raja Ponorogo yang berniat melamar putri Kediri, Dewi Ragil Kuning, namun ditengah perjalanan ia dicegat oleh Raja Singabarong dari Kediri. Pasukan Raja Singabarong terdiri dari merak dan singa, sedangkan dari pihak Kerajaan Ponorogo Raja Kelono dan Wakilnya Bujanganom, dikawal oleh warok (pria berpakaian hitam-hitam dalam tariannya), dan warok ini memiliki ilmu hitam mematikan. Seluruh tariannya merupakan tarian perang antara Kerajaan Kediri dan Kerajaan Ponorogo, dan mengadu ilmu hitam antara keduanya, para penari dalam keadaan 'kerasukan' saat mementaskan tariannya [3] .

Hingga kini masyarakat Ponorogo hanya mengikuti apa yang menjadi warisan leluhur mereka sebagai pewarisan budaya yang sangat kaya. Dalam pengalamannya Seni Reog merupakan cipta kreasi manusia yang terbentuk adanya aliran kepercayaan yang ada secara turun temurun dan terjaga. Upacaranya pun menggunakan syarat-syarat yang tidak mudah bagi orang awam untuk memenuhinya tanpa adanya garis keturunan yang jelas. mereka menganut garis keturunan Parental dan hukum adat yang masih berlaku.
[sunting] Pementasan Seni Reog
Reog Ponorogo

Reog modern biasanya dipentaskan dalam beberapa peristiwa seperti pernikahan, khitanan dan hari-hari besar Nasional. Seni Reog Ponorogo terdiri dari beberapa rangkaian 2 sampai 3 tarian pembukaan. Tarian pertama biasanya dibawakan oleh 6-8 pria gagah berani dengan pakaian serba hitam, dengan muka dipoles warna merah. Para penari ini menggambarkan sosok singa yang pemberani. Berikutnya adalah tarian yang dibawakan oleh 6-8 gadis yang menaiki kuda. Pada reog tradisionil, penari ini biasanya diperankan oleh penari laki-laki yang berpakaian wanita. Tarian ini dinamakan tari jaran kepang, yang harus dibedakan dengan seni tari lain yaitu tari kuda lumping. Tarian pembukaan lainnya jika ada biasanya berupa tarian oleh anak kecil yang membawakan adegan lucu.

Setelah tarian pembukaan selesai, baru ditampilkan adegan inti yang isinya bergantung kondisi dimana seni reog ditampilkan. Jika berhubungan dengan pernikahan maka yang ditampilkan adalah adegan percintaan. Untuk hajatan khitanan atau sunatan, biasanya cerita pendekar,

Adegan dalam seni reog biasanya tidak mengikuti skenario yang tersusun rapi. Disini selalu ada interaksi antara pemain dan dalang (biasanya pemimpin rombongan) dan kadang-kadang dengan penonton. Terkadang seorang pemain yang sedang pentas dapat digantikan oleh pemain lain bila pemain tersebut kelelahan. Yang lebih dipentingkan dalam pementasan seni reog adalah memberikan kepuasan kepada penontonnya.

Adegan terakhir adalah singa barong, dimana pelaku memakai topeng berbentuk kepala singa dengan mahkota yang terbuat dari bulu burung merak. Berat topeng ini bisa mencapai 50-60 kg. Topeng yang berat ini dibawa oleh penarinya dengan gigi. Kemampuan untuk membawakan topeng ini selain diperoleh dengan latihan yang berat, juga dipercaya diproleh dengan latihan spiritual seperti puasa dan tapa.
[sunting] Kontroversi
Foto tari Barongan di situs resmi Malaysia, yang memicu kontroversi.

Tarian sejenis Reog Ponorogo yang ditarikan di Malaysia dinamakan Tari Barongan[4]. Tarian ini juga menggunakan topeng dadak merak, yaitu topeng berkepala harimau yang di atasnya terdapat bulu-bulu merak. Deskripsi dan foto tarian ini ditampilkan dalam situs resmi Kementrian Kebudayaan Kesenian dan Warisan Malaysia.

Kontroversi timbul karena pada topeng dadak merak di situs resmi tersebut terdapat tulisan "Malaysia",[5][6] dan diakui sebagai warisan masyarakat dari Batu Pahat, Johor dan Selangor, Malaysia. Hal ini memicu protes berbagai pihak di Indonesia, termasuk seniman Reog asal Ponorogo yang menyatakan bahwa hak cipta kesenian Reog telah dicatatkan dengan nomor 026377 tertanggal 11 Februari 2004, dan dengan demikian diketahui oleh Menteri Hukum dan HAM Republik Indonesia.[7] Ditemukan pula informasi bahwa dadak merak yang terlihat di situs resmi tersebut adalah buatan pengrajin Ponorogo.[8] Ribuan seniman Reog sempat berdemonstrasi di depan Kedutaan Malaysia di Jakarta.[9] Pemerintah Indonesia menyatakan akan meneliti lebih lanjut hal tersebut.[7]

Pada akhir November 2007, Duta Besar Malaysia untuk Indonesia Datuk Zainal Abidin Muhammad Zain menyatakan bahwa Pemerintah Malaysia tidak pernah mengklaim Reog Ponorogo sebagai budaya asli negara itu. Reog yang disebut “Barongan” di Malaysia dapat dijumpai di Johor dan Selangor, karena dibawa oleh rakyat Jawa yang merantau ke negeri tersebut


sumber :

Minggu, 13 Februari 2011

10 Tempat Menakutkan di Dunia

1. Catacombs, Paris, Perancis.
Tempat teratas di duduki oleh catacombs di Perancis, kenapa bisa jadi no.1?
The Catacombs Paris atau Catacombes de Paris adalah kuburan bawah tanah yang terkenal di Paris, Perancis. Berada di dekat stasiun Denfert-Rochereau, Paris Metro. Dibuka dan di direnovasi bagian kota besar jaringan terowongan bawah tanah dan caverns di akhir abad 18, ia menjadi daya tarik turis dalam skala kecil, dari awal abad ke-19 dan telah terbuka untuk publik secara berkala dari 1867 . Nama resmi untuk catacombs adalah l’Ossuaire municipal.

Pemakaman ini mencakup dari Paris’ bekas tambang dekat Kiri Bank Denfert-Rochereau, di lokasi yang sama di luar gerbang kota sebelum Paris diperluas pada tahun 1860.
Sejarah catacombs dimulai ketika akhir abad ke 17 dimana banyak warga paris meninggal karena penyakit yang disebabkan oleh polusi akibat pembakaran tidak sempurna oleh pabrik-pabrik di perancis (ketika revolusi industri. Dikarenakan jumlah pemakaman yang tidak memadai lagi maka ide penggunaan tulang manusia yang telah mati pada terowongan untuk tempat pemakaman dicetuskan oleh Letnan Jenderal Polisi Alexandre Lenoir, catacombs didirikan pada tahun 1786 dan kemudian diteruskan oleh M. Thiroux de Crosne, Charles Axel Guillaumot, Inspektur Jenderal Quarries, dan Louis-Etienne Héricart de Thury.

2. Kota Berhantu New Orleans, Lousiana
Kota Berhantu New Orleans adalah tampat yang dianggap oleh masyarakat lokal, pengunjung dan Paranormal penyelidik di seluruh dunia sebagai yang paling benar-benar angker dan no.1 di seluruh Amerika Serikat. Dengan semua masa lalu dan kegiatan rohani mengambil tempat di pusat plot yang angker teramat seram, gelap, dan di antara dua dunia – yang kebanyakan saksi melihat Kota ini untuk semuanya berasal dari dunia gaib.
Dengan 200 tahun lamanya cerita tentang legenda Voodoo melibatkan kutukan, Spanyol oak moss draped dikelilingi duels, pembunuhan kejam, Cerita dari Revolutionary War Pirates dan Civil War prajurit, dan Jazz. New Orleans memiliki reputasi sebagai salah satu wisata kota paling angker. Cerita lainnya tentang hantu yang menghantui New Orleans, hantu tersebut adalah dari Laularie House. Delphine LaLaurie suami ketiganya, Leonard LaLaurie, mengambil tempat tinggal rumah di 1140 Royal Street pada tahun 1830-an.

3. Sedlec Ossuary, Republik Ceko
Kuburan Sedlec (Ceko: kostnice Sedlec) adalah gereja Katolik Roma kecil, yang terletak di bawah Cemetery Church of All Saints (Ceko: Hrbitovní kostel Všech Svatých) di Sedlec, sebuah suburban dari Kutná Hora di Republik Ceko. Kuburan yang berisi sekitar 40,000-70,000 tulang manusia telah disusun secara artistik untuk membentuk dekorasi dan perabot gereja.

4. Underground Vaults, Edinburgh, Scotland.
Jauh di bawah jalan-jalan yang sibuk yang modern terletak Edinburgh yang gelap, sudut kota yang dilupakan sejarah. Dibangun di pertengahan tahun 1980-an, Edinburgh Vaults telah ditinggalkan selama hampir dua ratus tahun. Terletak di bawah South Bridge, jalan utama Edinburgh yang besar, tempat yang digunakan sebagai cellars, lokakarya dan bahkan sebagai tempat tinggal oleh para pebisnis yang sibuk di atas jembatan.
Penyelidikan oleh paranormal telah dilakukan di vaults praktis sejak penemuan hingga sekarang. Menurut mereka, lokasi tersebut belum menggangu aktivitas ekonomi kota oleh hal-hal aneh. Baru-baru ini lokasi tersebut dikunjungi oleh para awak pesawat dari Inggris dan mereka memberi reputasi sebagai tempat terseram di Edinburgh & anggota tim sukarelawan itu tidak ada yang mau kembali kesana.

5. Coliseum, Rome, Italy
Dibalik keindahannya ternyata coliseum roma menyimpan sesuatu yang kelam. Pemandu wisata dan pengunjung sama-sama telah melaporkan adanya beberapa tempat terasa dingin tiba-tiba, yang menyentuh atau mendorong, mendengar kata-kata tak dpt dibedakan dengan berbisik ke telinga mereka; penjaga keamanan yang melakukan pengamanan disekitar coliseum melaporkan mendengar suara dari pedang yang beradu, suara tangis, & yg cukup aneh paling membingungkan adalah suara-suara hantu hewan seperti roars dari singa dan gajah. hantu tersebut oleh penduduk sekitar sudah terlihat di antara tempat duduk di stadion besar, terlihat prajurit Roma, siluet pada waktu malam hari merupakan pemandangan yang umum disini.

6. Walachia, Transylvania, Land of Dracul, Romania.
Dracula?? iya tempat ini diperkirakan dihuni oleh mr. dracula yang terkenal tersebut.

7. Auschwitz-Birkenau Concentration Camp, Oswiecim, Poland.
Auschwitz adalah kamp kematian dalam operasi dari Mei 1940 sampai dengan kemerdekaan oleh pasukan Soviet pada Januari 1945. Hal ini diperkirakan 2,1-2,5 juta orang meninggal di kamar gas pada waktu itu, 2 juta diantaranya adalah orang2 Yahudi dan sisanya adalah Poles, Gypsies dan POWs Soviet. Tapi perkiraan ini dianggap oleh sejarahwan menjadi sangat minimal, karena jumlah kematian di Auschwitz dan kamp Birkenau tidak pernah benar2 dapat diketahui.
Setiap orang yang telah mengunjungi Auschwitz-Birkenau terasuk oleh rasa sedih pengunjung diketahui menangis tanpa alasan jelas dan banyak harus meninggalkan tur kelompok tanpa pernah menyelesaikan wisata. Pengunjung tidak hanya terpengaruh oleh memori tempat yang menyeramkan, tetapi juga efek pada hari ini: burung masih menolak untuk menyanyi di atas pohon sekitar kamp kematian dan ada sedikit bukti yang berkembang alam lingkungan di mana saja di dekatnya. yaitu Kesunyian…

8. Whitechapel/Spittalfields, London East End, London, England.
The Whitechapel / Spittalfields kawasan Timur London telah aktif sejak menetap Roma kali.
Pada tahun 1888 di daerah Whitechapel London adalah tempat yang paling brutal dimana pembunuhan pernah tercatat: yang terkenal dengan kejahatan Jack the Ripper. Namun pembunuhan – dan identitas Jack – tetap belum diketahui, bahkan hari ini. Banyak menegaskan bahwa killer adalah seorang dokter atau entah bagaimana terhubung ke profesi medis; yang lain yakin killer adalah cucu ratu Victoria’s dan Pangeran Albert Victor, meskipun tidak banyak teori mendukung hal ini.
Lima perempuan, semuanya miskin dan pelacur, telah dipotong oleh Jack yang misterius dalam kurun waktu hanya empat bulan, secara kolektif dikenal sebagai "The Autumn of Terror." Empat perempuan – Maria Nicholls, Annie Chapman, Elizabeth stride, Catherine Eddowes — yang ditemukan di berbagai jalan dan gang sepanjang Whitechapel dengan potongan tubuh yang menyeramkan dan sadis. Yang kelima – Mary Kelly – adalah satu-satunya korban dibunuh di sebuah lokasi interior; tidak seperti yang lain dia dibunuh dengan cara yang paling sadis, kematian kematiannya seperti sesuatu yang berasal dari penjagalan.

9. Unit 731 Experimentation Camp, Harbin, Manchuria, China.
Tempat ini disebut-sebut sebagai Auschwitz di Asia, dalam hal kekejaman dan kengerian, ia menjamin pasti penjelasan ini. Namun tetap ada perbedaan yang mendasar dengan kejahatan perpetrated oleh Nazis terhadap orang-orang Yahudi: Meskipun Jerman telah menunjukkan penyesalan dan penyesalan mendalam, para pemimpin negara yang spawned kesusahanhari Unit 731 masih berjuang untuk berkelahi dengan apa yang terjadi. . . Pada akhirnya setidaknya 3000 tahanan, terutama Cina, dibunuh secara langsung, dengan lebih 250.000 Cina kiri mati melalui percobaan biologi peperangan.

10. Haunted Gettysburg, Pennsylvania.
peperangan dari perang sipil terjadi pada 1863 di kota kecil Gettysburg Pennsylvania, tempat ini meru[pakan tempat dengan korban jiwa terbanyak dalam peperangan tersebut dan masayarakat sekitar melihat, mendengar & merasakan sesuatu yang aneh di sekitar tempat itu.

Earth Quake and Tsunami

An earthquake (also known as a quake, tremor or temblor) is the result of a sudden release of energy in the Earth's crust that creates seismic waves. The seismicity or seismic activity of an area refers to the frequency, type and size of earthquakes experienced over a period of time. Earthquakes are measured with a seismometer; a device which also records is known as a seismograph. The moment magnitude (or the related and mostly obsolete Richter magnitude) of an earthquake is conventionally reported, with magnitude 3 or lower earthquakes being mostly imperceptible and magnitude 7 causing serious damage over large areas. Intensity of shaking is measured on the modified Mercalli scale. The depth of the earthquake also matters: the more shallow the earthquake, the more damage to structures (all else being equal).[1]

At the Earth's surface, earthquakes manifest themselves by shaking and sometimes displacing the ground. When a large earthquake epicenter is located offshore, the seabed sometimes suffers sufficient displacement to cause a tsunami. The shaking in earthquakes can also trigger landslides and occasionally volcanic activity.

In its most generic sense, the word earthquake is used to describe any seismic event—whether a natural phenomenon or an event caused by humans—that generates seismic waves. Earthquakes are caused mostly by rupture of geological faults, but also by volcanic activity, landslides, mine blasts, and nuclear tests. An earthquake's point of initial rupture is called its focus or hypocenter. The term epicenter refers to the point at ground level directly above the hypocenter.
Naturally occurring earthquakes
Fault types

Tectonic earthquakes will occur anywhere within the earth where there is sufficient stored elastic strain energy to drive fracture propagation along a fault plane. In the case of transform or convergent type plate boundaries, which form the largest fault surfaces on earth, they will move past each other smoothly and aseismically only if there are no irregularities or asperities along the boundary that increase the frictional resistance. Most boundaries do have such asperities and this leads to a form of stick-slip behaviour. Once the boundary has locked, continued relative motion between the plates leads to increasing stress and therefore, stored strain energy in the volume around the fault surface. This continues until the stress has risen sufficiently to break through the asperity, suddenly allowing sliding over the locked portion of the fault, releasing the stored energy. This energy is released as a combination of radiated elastic strain seismic waves, frictional heating of the fault surface, and cracking of the rock, thus causing an earthquake. This process of gradual build-up of strain and stress punctuated by occasional sudden earthquake failure is referred to as the Elastic-rebound theory. It is estimated that only 10 percent or less of an earthquake's total energy is radiated as seismic energy. Most of the earthquake's energy is used to power the earthquake fracture growth or is converted into heat generated by friction. Therefore, earthquakes lower the Earth's available elastic potential energy and raise its temperature, though these changes are negligible compared to the conductive and convective flow of heat out from the Earth's deep interior.[2]
Earthquake fault types
Main article: Fault (geology)

There are three main types of fault that may cause an earthquake: normal, reverse (thrust) and strike-slip. Normal and reverse faulting are examples of dip-slip, where the displacement along the fault is in the direction of dip and movement on them involves a vertical component. Normal faults occur mainly in areas where the crust is being extended such as a divergent boundary. Reverse faults occur in areas where the crust is being shortened such as at a convergent boundary. Strike-slip faults are steep structures where the two sides of the fault slip horizontally past each other ; transform boundaries are a particular type of strike-slip fault. Many earthquakes are caused by movement on faults that have components of both dip-slip and strike-slip; this is known as oblique slip.
Earthquakes away from plate boundaries
Main article: Intraplate earthquake

Where plate boundaries occur within continental lithosphere, deformation is spread out over a much larger area than the plate boundary itself. In the case of the San Andreas fault continental transform, many earthquakes occur away from the plate boundary and are related to strains developed within the broader zone of deformation caused by major irregularities in the fault trace (e.g. the “Big bend” region). The Northridge earthquake was associated with movement on a blind thrust within such a zone. Another example is the strongly oblique convergent plate boundary between the Arabian and Eurasian plates where it runs through the northwestern part of the Zagros mountains. The deformation associated with this plate boundary is partitioned into nearly pure thrust sense movements perpendicular to the boundary over a wide zone to the southwest and nearly pure strike-slip motion along the Main Recent Fault close to the actual plate boundary itself. This is demonstrated by earthquake focal mechanisms.[3]

All tectonic plates have internal stress fields caused by their interactions with neighbouring plates and sedimentary loading or unloading (e.g. deglaciation[4]). These stresses may be sufficient to cause failure along existing fault planes, giving rise to intraplate earthquakes.[5]
Shallow-focus and deep-focus earthquakes

The majority of tectonic earthquakes originate at the ring of fire in depths not exceeding tens of kilometers. Earthquakes occurring at a depth of less than 70 km are classified as 'shallow-focus' earthquakes, while those with a focal-depth between 70 and 300 km are commonly termed 'mid-focus' or 'intermediate-depth' earthquakes. In subduction zones, where older and colder oceanic crust descends beneath another tectonic plate, deep-focus earthquakes may occur at much greater depths (ranging from 300 up to 700 kilometers).[6] These seismically active areas of subduction are known as Wadati-Benioff zones. Deep-focus earthquakes occur at a depth at which the subducted lithosphere should no longer be brittle, due to the high temperature and pressure. A possible mechanism for the generation of deep-focus earthquakes is faulting caused by olivine undergoing a phase transition into a spinel structure.[7]
Earthquakes and volcanic activity

Earthquakes often occur in volcanic regions and are caused there, both by tectonic faults and the movement of magma in volcanoes. Such earthquakes can serve as an early warning of volcanic eruptions, as during the Mount St. Helens eruption of 1980.[8] Earthquake swarms can serve as markers for the location of the flowing magma throughout the volcanoes. These swarms can be recorded by seismometers and tiltmeters (a device which measures the ground slope) and used as sensors to predict imminent or upcoming eruptions.[9]
Rupture dynamics

A tectonic earthquake begins by an initial rupture at a point on the fault surface, a process known as nucleation. The scale of the nucleation zone is uncertain, with some evidence, such as the rupture dimensions of the smallest earthquakes, suggesting that it is smaller than 100 m while other evidence, such as a slow component revealed by low-frequency spectra of some earthquakes, suggest that it is larger. The possibility that the nucleation involves some sort of preparation process is supported by the observation that about 40% of earthquakes are preceded by foreshocks. Once the rupture has initiated it begins to propagate along the fault surface. The mechanics of this process are poorly understood, partly because it is difficult to recreate the high sliding velocities in a laboratory. Also the effects of strong ground motion make it very difficult to record information close to a nucleation zone.[10]

Rupture propagation is generally modelled using a fracture mechanics approach, likening the rupture to a propagating mixed mode shear crack. The rupture velocity is a function of the fracture energy in the volume around the crack tip, increasing with decreasing fracture energy. The velocity of rupture propagation is orders of magnitude faster than the displacement velocity across the fault. Earthquake ruptures typically propagate at velocities that are in the range 70–90 % of the S-wave velocity and this is independent of earthquake size. A small subset of earthquake ruptures appear to have propagated at speeds greater than the S-wave velocity. These supershear earthquakes have all been observed during large strike-slip events. The unusually wide zone of coseismic damage caused by the 2001 Kunlun earthquake has been attributed to the effects of the sonic boom developed in such earthquakes. Some earthquake ruptures travel at unusually low velocities and are referred to as slow earthquakes. A particularly dangerous form of slow earthquake is the tsunami earthquake, observed where the relatively low felt intensities, caused by the slow propagation speed of some great earthquakes, fail to alert the population of the neighbouring coast, as in the 1896 Meiji-Sanriku earthquake.[10]
Earthquake clusters

Most earthquakes form part of a sequence, related to each other in terms of location and time.[11] Most earthquake clusters consist of small tremors which cause little to no damage, but there is a theory that earthquakes can recur in a regular pattern.[12]
Aftershocks
Main article: Aftershock

An aftershock is an earthquake that occurs after a previous earthquake, the mainshock. An aftershock is in the same region of the main shock but always of a smaller magnitude. If an aftershock is larger than the main shock, the aftershock is redesignated as the main shock and the original main shock is redesignated as a foreshock. Aftershocks are formed as the crust around the displaced fault plane adjusts to the effects of the main shock.[11]
Earthquake swarms
Main article: Earthquake swarm

Earthquake swarms are sequences of earthquakes striking in a specific area within a short period of time. They are different from earthquakes followed by a series of aftershocks by the fact that no single earthquake in the sequence is obviously the main shock, therefore none have notable higher magnitudes than the other. An example of an earthquake swarm is the 2004 activity at Yellowstone National Park.[13]
Earthquake storms
Main article: Earthquake storm

Sometimes a series of earthquakes occur in a sort of earthquake storm, where the earthquakes strike a fault in clusters, each triggered by the shaking or stress redistribution of the previous earthquakes. Similar to aftershocks but on adjacent segments of fault, these storms occur over the course of years, and with some of the later earthquakes as damaging as the early ones. Such a pattern was observed in the sequence of about a dozen earthquakes that struck the North Anatolian Fault in Turkey in the 20th century and has been inferred for older anomalous clusters of large earthquakes in the Middle East.[14][15]
Size and frequency of occurrence

There are around 500,000 earthquakes each year. About 100,000 of these can actually be felt.[16][17] Minor earthquakes occur nearly constantly around the world in places like California and Alaska in the U.S., as well as in Guatemala. Chile, Peru, Indonesia, Iran, Pakistan, the Azores in Portugal, Turkey, New Zealand, Greece, Italy, and Japan, but earthquakes can occur almost anywhere, including New York City, London, and Australia.[18] Larger earthquakes occur less frequently, the relationship being exponential; for example, roughly ten times as many earthquakes larger than magnitude 4 occur in a particular time period than earthquakes larger than magnitude 5. In the (low seismicity) United Kingdom, for example, it has been calculated that the average recurrences are: an earthquake of 3.7 - 4.6 every year, an earthquake of 4.7 - 5.5 every 10 years, and an earthquake of 5.6 or larger every 100 years.[19] This is an example of the Gutenberg-Richter law.
The Messina earthquake and tsunami took as many as 200,000 lives on December 28, 1908 in Sicily and Calabria.[20]

The number of seismic stations has increased from about 350 in 1931 to many thousands today. As a result, many more earthquakes are reported than in the past, but this is because of the vast improvement in instrumentation, rather than an increase in the number of earthquakes. The USGS estimates that, since 1900, there have been an average of 18 major earthquakes (magnitude 7.0-7.9) and one great earthquake (magnitude 8.0 or greater) per year, and that this average has been relatively stable.[21] In recent years, the number of major earthquakes per year has decreased, although this is thought likely to be a statistical fluctuation rather than a systematic trend. More detailed statistics on the size and frequency of earthquakes is available from the USGS.[22]

Most of the world's earthquakes (90%, and 81% of the largest) take place in the 40,000-km-long, horseshoe-shaped zone called the circum-Pacific seismic belt, known as the Pacific Ring of Fire, which for the most part bounds the Pacific Plate.[23][24] Massive earthquakes tend to occur along other plate boundaries, too, such as along the Himalayan Mountains.

With the rapid growth of mega-cities such as Mexico City, Tokyo and Tehran, in areas of high seismic risk, some seismologists are warning that a single quake may claim the lives of up to 3 million people.[25]
Induced seismicity
Main article: Induced seismicity

While most earthquakes are caused by movement of the Earth's tectonic plates, human activity can also produce earthquakes. Four main activities contribute to this phenomenon: constructing large dams and buildings, drilling and injecting liquid into wells, and by coal mining and oil drilling.[26] Perhaps the best known example is the 2008 Sichuan earthquake in China's Sichuan Province in May; this tremor resulted in 69,227 fatalities and is the 19th deadliest earthquake of all time. The Zipingpu Dam is believed to have fluctuated the pressure of the fault 1,650 feet (503 m) away; this pressure probably increased the power of the earthquake and accelerated the rate of movement for the fault.[27] The greatest earthquake in Australia's history was also induced by humanity, through coal mining. The city of Newcastle was built over a large sector of coal mining areas. The earthquake was spawned from a fault which reactivated due to the millions of tonnes of rock removed in the mining process.[28]
Measuring and locating earthquakes
Main article: Seismology

Earthquakes can be recorded by seismometers up to great distances, because seismic waves travel through the whole Earth's interior. The absolute magnitude of a quake is conventionally reported by numbers on the Moment magnitude scale (formerly Richter scale, magnitude 7 causing serious damage over large areas), whereas the felt magnitude is reported using the modified Mercalli intensity scale (intensity II-XII).

Every tremor produces different types of seismic waves which travel through rock with different velocities: the longitudinal P-waves (shock- or pressure waves), the transverse S-waves (both body waves) and several surface waves (Rayleigh and Love waves). The propagation velocity of the seismic waves ranges from approx. 3 km/s up to 13 km/s, depending on the density and elasticity of the medium. In the Earth's interior the shock- or P waves travel much faster than the S waves (approx. relation 1.7 : 1). The differences in travel time from the epicentre to the observatory are a measure of the distance and can be used to image both sources of quakes and structures within the Earth. Also the depth of the hypocenter can be computed roughly.

In solid rock P-waves travel at about 6 to 7 km per second; the velocity increases within the deep mantle to ~13 km/s. The velocity of S-waves ranges from 2–3 km/s in light sediments and 4–5 km/s in the Earth's crust up to 7 km/s in the deep mantle. As a consequence, the first waves of a distant earth quake arrive at an observatory via the Earth's mantle.

Rule of thumb: On the average, the kilometer distance to the earthquake is the number of seconds between the P and S wave times 8.[29] Slight deviations are caused by inhomogeneities of subsurface structure. By such analyses of seismograms the Earth's core was located in 1913 by Beno Gutenberg.

Earthquakes are not only categorized by their magnitude but also by the place where they occur. The world is divided into 754 Flinn-Engdahl regions (F-E regions), which are based on political and geographical boundaries as well as seismic activity. More active zones are divided into smaller F-E regions whereas less active zones belong to larger F-E regions.
Effects/impacts of earthquakes
1755 copper engraving depicting Lisbon in ruins and in flames after the 1755 Lisbon earthquake, which killed an estimated 60,000 people. A tsunami overwhelms the ships in the harbor.

The effects of earthquakes include, but are not limited to, the following:
Shaking and ground rupture

Shaking and ground rupture are the main effects created by earthquakes, principally resulting in more or less severe damage to buildings and other rigid structures. The severity of the local effects depends on the complex combination of the earthquake magnitude, the distance from the epicenter, and the local geological and geomorphological conditions, which may amplify or reduce wave propagation.[30] The ground-shaking is measured by ground acceleration.

Specific local geological, geomorphological, and geostructural features can induce high levels of shaking on the ground surface even from low-intensity earthquakes. This effect is called site or local amplification. It is principally due to the transfer of the seismic motion from hard deep soils to soft superficial soils and to effects of seismic energy focalization owing to typical geometrical setting of the deposits.

Ground rupture is a visible breaking and displacement of the Earth's surface along the trace of the fault, which may be of the order of several metres in the case of major earthquakes. Ground rupture is a major risk for large engineering structures such as dams, bridges and nuclear power stations and requires careful mapping of existing faults to identify any likely to break the ground surface within the life of the structure.[31]
Landslides and avalanches
Main article: Landslide

Earthquakes, along with severe storms, volcanic activity, coastal wave attack, and wildfires, can produce slope instability leading to landslides, a major geological hazard. Landslide danger may persist while emergency personnel are attempting rescue.[32]
Fires
Fires of the 1906 San Francisco earthquake

Earthquakes can cause fires by damaging electrical power or gas lines. In the event of water mains rupturing and a loss of pressure, it may also become difficult to stop the spread of a fire once it has started. For example, more deaths in the 1906 San Francisco earthquake were caused by fire than by the earthquake itself.[33]
Soil liquefaction
Main article: Soil liquefaction

Soil liquefaction occurs when, because of the shaking, water-saturated granular material (such as sand) temporarily loses its strength and transforms from a solid to a liquid. Soil liquefaction may cause rigid structures, like buildings and bridges, to tilt or sink into the liquefied deposits. This can be a devastating effect of earthquakes. For example, in the 1964 Alaska earthquake, soil liquefaction caused many buildings to sink into the ground, eventually collapsing upon themselves.[34]
Tsunami
Main article: Tsunami
The tsunami of the 2004 Indian Ocean earthquake

Tsunamis are long-wavelength, long-period sea waves produced by the sudden or abrupt movement of large volumes of water. In the open ocean the distance between wave crests can surpass 100 kilometers (62 miles), and the wave periods can vary from five minutes to one hour. Such tsunamis travel 600-800 kilometers per hour (373–497 miles per hour), depending on water depth. Large waves produced by an earthquake or a submarine landslide can overrun nearby coastal areas in a matter of minutes. Tsunamis can also travel thousands of kilometers across open ocean and wreak destruction on far shores hours after the earthquake that generated them.[35]

Ordinarily, subduction earthquakes under magnitude 7.5 on the Richter scale do not cause tsunamis, although some instances of this have been recorded. Most destructive tsunamis are caused by earthquakes of magnitude 7.5 or more.[35]
Floods
Main article: Flood

A flood is an overflow of any amount of water that reaches land.[36] Floods occur usually when the volume of water within a body of water, such as a river or lake, exceeds the total capacity of the formation, and as a result some of the water flows or sits outside of the normal perimeter of the body. However, floods may be secondary effects of earthquakes, if dams are damaged. Earthquakes may cause landslips to dam rivers, which then collapse and cause floods.[37]

The terrain below the Sarez Lake in Tajikistan is in danger of catastrophic flood if the landslide dam formed by the earthquake, known as the Usoi Dam, were to fail during a future earthquake. Impact projections suggest the flood could affect roughly 5 million people.[38]
Tidal forces

Research work has shown a robust correlation between small tidally induced forces and non-volcanic tremor activity.[39][40][41][42]
Human impacts
Damaged infrastructure, one week after the 2007 Peru earthquake

Earthquakes may lead to disease, lack of basic necessities, loss of life, higher insurance premiums, general property damage, road and bridge damage, and collapse or destabilization (potentially leading to future collapse) of buildings. Earthquakes can also precede volcanic eruptions, which cause further problems; for example, substantial crop damage, as in the "Year Without a Summer" (1816).[43]
Major earthquakes
Main article: List of earthquakes

The largest earthquake that has been measured on a seismograph reached 9.5 magnitude, occurring on 22 May 1960.[16][17] Its epicenter was near Cañete, Chile. The energy released was approximately twice that of the next most powerful earthquake, the Good Friday Earthquake, which was centered in Prince William Sound, Alaska.[44][45] The ten largest recorded earthquakes have all been megathrust earthquakes; however, of these ten, only the 2004 Indian Ocean earthquake is simultaneously one of the deadliest earthquakes in history.

The earthquakes with the greatest amount of loss of life, while powerful, were deadly because of their proximity to either heavily populated areas or the ocean, where earthquakes can potentially create tsunamis which can devastate communities thousands of miles away. Regions that are most at risk for great loss of life include those where earthquakes are relatively rare but powerful, and poor regions with lax, unenforced, or nonexistent seismic building codes.
Preparation

In order to determine the likelihood of future seismic activity, geologists and other scientists examine the rock of an area to determine if the rock appears to be "strained". Studying the faults of an area to study the buildup time it takes for the fault to build up stress sufficient for an earthquake also serves as an effective prediction technique.[46] Measurements of the amount of accumulated strain energy on the fault each year, time passed since the last major temblor, and the energy and power of the last earthquake are made.[46] Together the facts allow scientists to determine how much pressure it takes for the fault to generate an earthquake. Though this method is useful, it has only been implemented on California's San Andreas Fault.[46]

Today, there are ways to protect and prepare possible sites of earthquakes from severe damage, through the following processes: earthquake engineering, earthquake preparedness, household seismic safety, seismic retrofit (including special fasteners, materials, and techniques), seismic hazard, mitigation of seismic motion, and earthquake prediction. Seismic retrofitting is the modification of existing structures to make them more resistant to seismic activity, ground motion, or soil failure due to earthquakes. With better understanding of seismic demand on structures and with our recent experiences with large earthquakes near urban centers, the need of seismic retrofitting is well acknowledged. Prior to the introduction of modern seismic codes in the late 1960s for developed countries (US, Japan etc.) and late 1970s for many other parts of the world (Turkey, China etc.),[47] many structures were designed without adequate detailing and reinforcement for seismic protection. In view of the imminent problem, various research work has been carried out. Furthermore, state-of-the-art technical guidelines for seismic assessment, retrofit and rehabilitation have been published around the world - such as the ASCE-SEI 41[48] and the New Zealand Society for Earthquake Engineering (NZSEE)'s guidelines.[49]
History
An image from a 1557 book
Pre-Middle Ages

From the lifetime of the Greek philosopher Anaxagoras in the 5th century BCE to the 14th century CE, earthquakes were usually attributed to "air (vapors) in the cavities of the Earth".[50] Thales of Miletus, who lived from 625-547 (BCE) was the only documented person who believed that earthquakes were caused by tension between the earth and water.[50] Other theories existed, including the Greek philosopher Anaxamines' (585-526 BCE) beliefs that short incline episodes of dryness and wetness caused seismic activity. The Greek philosopher Democritus (460-371BCE) blamed water in general for earthquakes.[50] Pliny the Elder called earthquakes "underground thunderstorms".[50]
Earthquakes in culture
Mythology and religion

In Norse mythology, earthquakes were explained as the violent struggling of the god Loki. When Loki, god of mischief and strife, murdered Baldr, god of beauty and light, he was punished by being bound in a cave with a poisonous serpent placed above his head dripping venom. Loki's wife Sigyn stood by him with a bowl to catch the poison, but whenever she had to empty the bowl the poison would drip on Loki's face, forcing him to jerk his head away and thrash against his bonds, causing the earth to tremble.[51]

In Greek mythology, Poseidon was the cause and god of earthquakes. When he was in a bad mood, he would strike the ground with a trident, causing this and other calamities. He also used earthquakes to punish and inflict fear upon people as revenge.[52]

In Japanese mythology, Namazu (鯰) is a giant catfish who causes earthquakes. Namazu lives in the mud beneath the earth, and is guarded by the god Kashima who restrains the fish with a stone. When Kashima lets his guard fall, Namazu thrashes about, causing violent earthquakes.
Popular culture

In modern popular culture, the portrayal of earthquakes is shaped by the memory of great cities laid waste, such as Kobe in 1995 or San Francisco in 1906.[53] Fictional earthquakes tend to strike suddenly and without warning.[53] For this reason, stories about earthquakes generally begin with the disaster and focus on its immediate aftermath, as in Short Walk to Daylight (1972), The Ragged Edge (1968) or Aftershock: Earthquake in New York (1998).[53] A notable example is Heinrich von Kleist's classic novella, The Earthquake in Chile, which describes the destruction of Santiago in 1647. Haruki Murakami's short fiction collection, After the Quake, depicts the consequences of the Kobe earthquake of 1995.

The most popular single earthquake in fiction is the hypothetical "Big One" expected of California's San Andreas Fault someday, as depicted in the novels Richter 10 (1996) and Goodbye California (1977) among other works.[53] Jacob M. Appel's widely anthologized short story, A Comparative Seismology, features a con artist who convinces an elderly woman that an apocalyptic earthquake is imminent.[54] In Pleasure Boating in Lituya Bay, one of the stories in Jim Shepard's Like You'd Understand, Anyway, the "Big One" leads to an even more devastating tsunami.

In the film 2012 (2009), solar flares (geologically implausibly) affecting the Earth's core caused massive destabilization of the Earth's crust layers. This created destruction planet-wide with earthquakes and tsunamis, foreseen by the Mayan culture and myth surrounding the last year noted in the Mesoamerican calendar - 2012.

Contemporary depictions of earthquakes in film are variable in the manner in which they reflect human psychological reactions to the actual trauma that can be caused to directly afflicted families and their loved ones.[55] Disaster mental health response research emphasizes the need to be aware of the different roles of loss of family and key community members, loss of home and familiar surroundings, loss of essential supplies and services to maintain survival.[56][57] Particularly for children, the clear availability of caregiving adults who are able to protect, nourish, and clothe them in the aftermath of the earthquake, and to help them make sense of what has befallen them has been shown to be even more important to their emotional and physical health than the simple giving of provisions.[58] As was observed after other disasters involving destruction and loss of life and their media depictions, such as those of the 2001 World Trade Center Attacks or Hurricane Katrina—and has been recently observed in the 2010 Haiti Earthquake, it is also important not to pathologize the reactions to loss and displacement or disruption of governmental administration and services, but rather to validate these reactions, to support constructive problem-solving and reflection as to how one might improve the conditions of those affected.[59]




Tsunami striking Thailand on December 26, 2004
A tsunami (Japanese: 津波 [tsɯnami], lit. 'harbor wave';[1] English pronunciation: /suːˈnɑːmi/ soo-NAH-mee) or tidal wave is a series of water waves (called a tsunami wave train[2]) caused by the displacement of a large volume of a body of water, usually an ocean, but can occur in large lakes. Tsunamis are a frequent occurrence in Japan; approximately 195 events have been recorded.[3] Due to the immense volumes of water and energy involved, tsunamis can devastate coastal regions.
Earthquakes, volcanic eruptions and other underwater explosions (including detonations of underwater nuclear devices), landslides and other mass movements, meteorite ocean impacts or similar impact events, and other disturbances above or below water all have the potential to generate a tsunami.
The Greek historian Thucydides was the first to relate tsunami to submarine earthquakes,[4][5] but understanding of tsunami's nature remained slim until the 20th century and is the subject of ongoing research. Many early geological, geographical, and oceanographic texts refer to tsunamis as "seismic sea waves."
Some meteorological conditions, such as deep depressions that cause tropical cyclones, can generate a storm surge, called a meteotsunami, which can raise tides several metres above normal levels. The displacement comes from low atmospheric pressure within the centre of the depression. As these storm surges reach shore, they may resemble (though are not) tsunamis, inundating vast areas of land. Such a storm surge inundated Burma in May 2008.

Etymology

Lisbon earthquake and tsunami in 1775.

The Russians of Pavel Lebedev-Lastochkin in Japan, with their ships tossed inland by a tsunami, meeting some Japanese in 1779.
The term tsunami comes from the Japanese, meaning "harbor" (tsu, 津) and "wave" (nami, 波). (For the plural, one can either follow ordinary English practice and add an s, or use an invariable plural as in the Japanese.[6])
Tsunami are sometimes referred to as tidal waves. In recent years, this term has fallen out of favor, especially in the scientific community, because tsunami actually have nothing to do with tides. The once-popular term derives from their most common appearance, which is that of an extraordinarily high tidal bore. Tsunami and tides both produce waves of water that move inland, but in the case of tsunami the inland movement of water is much greater and lasts for a longer period, giving the impression of an incredibly high tide. Although the meanings of "tidal" include "resembling"[7] or "having the form or character of"[8] the tides, and the term tsunami is no more accurate because tsunami are not limited to harbours, use of the term tidal wave is discouraged by geologists and oceanographers.
There are only a few other languages that have a native word for this disastrous wave. In the Tamil language, the word is aazhi peralai. In the Acehnese language, it is ië beuna or alôn buluëk[9] (Depending on the dialect. Note that in the fellow Austronesian language of Tagalog, a major language in the Philippines, alon means "wave".) On Simeulue island, off the western coast of Sumatra in Indonesia, in the Defayan language the word is smong, while in the Sigulai language it is emong.[10]
Generation mechanisms
The principal generation mechanism (or cause) of a tsunami is the displacement of a substantial volume of water or perturbation of the sea.[11] This displacement of water is usually attributed to either earthquakes, landslides, volcanic eruptions, or more rarely by meteorites and nuclear tests.[12][13] The waves formed in this way are then sustained by gravity. It is important to note that tides do not play any part in the generation of tsunamis, hence referring to tsunamis as 'tidal waves' is inaccurate.
Seismicity generated tsunamis
Tsunamis can be generated when the sea floor abruptly deforms and vertically displaces the overlying water. Tectonic earthquakes are a particular kind of earthquake that are associated with the earth's crustal deformation; when these earthquakes occur beneath the sea, the water above the deformed area is displaced from its equilibrium position.[14] More specifically, a tsunami can be generated when thrust faults associated with convergent or destructive plate boundaries move abruptly, resulting in water displacement, due to the vertical component of movement involved. Movement on normal faults will also cause displacement of the seabed, but the size of the largest of such events is normally too small to give rise to a significant tsunami.
Drawing of tectonic plate boundary before earthquake.

Overriding plate bulges under strain, causing tectonic uplift.

Plate slips, causing subsidence and releasing energy into water.

The energy released produces tsunami waves.
Tsunamis have a small amplitude (wave height) offshore, and a very long wavelength (often hundreds of kilometers long), which is why they generally pass unnoticed at sea, forming only a slight swell usually about 300 millimetres (12 in) above the normal sea surface. They grow in height when they reach shallower water, in a wave shoaling process described below. A tsunami can occur in any tidal state and even at low tide can still inundate coastal areas.
On April 1, 1946, a magnitude-7.8 (Richter Scale) earthquake occurred near the Aleutian Islands, Alaska. It generated a tsunami which inundated Hilo on the island of Hawai'i with a 14 metres (46 ft) high surge. The area where the earthquake occurred is where the Pacific Ocean floor is subducting (or being pushed downwards) under Alaska.
Examples of tsunami at locations away from convergent boundaries include Storegga about 8,000 years ago, Grand Banks 1929, Papua New Guinea 1998 (Tappin, 2001). The Grand Banks and Papua New Guinea tsunamis came from earthquakes which destabilized sediments, causing them to flow into the ocean and generate a tsunami. They dissipated before traveling transoceanic distances.
The cause of the Storegga sediment failure is unknown. Possibilities include an overloading of the sediments, an earthquake or a release of gas hydrates (methane etc.)
The 1960 Valdivia earthquake (Mw 9.5) (19:11 hrs UTC), 1964 Alaska earthquake (Mw 9.2), and 2004 Indian Ocean earthquake (Mw 9.2) (00:58:53 UTC) are recent examples of powerful megathrust earthquakes that generated tsunamis (known as teletsunamis) that can cross entire oceans. Smaller (Mw 4.2) earthquakes in Japan can trigger tsunamis (called local and regional tsunamis) that can only devastate nearby coasts, but can do so in only a few minutes.
In the 1950s, it was discovered that larger tsunamis than had previously been believed possible could be caused by giant landslides. These phenomena rapidly displace large water volumes, as energy from falling debris or expansion transfers to the water at a rate faster than the water can absorb. Their existence was confirmed in 1958, when a giant landslide in Lituya Bay, Alaska, caused the highest wave ever recorded, which had a height of 524 metres (over 1700 feet). The wave didn't travel far, as it struck land almost immediately. Two people fishing in the bay were killed, but another boat amazingly managed to ride the wave. Scientists named these waves megatsunami.
Scientists discovered that extremely large landslides from volcanic island collapses can generate megatsunami, that can travel trans-oceanic distances.

Characteristics

When the wave enters shallow water, it slows down and its amplitude (height) increases.

The wave further slows and amplifies as it hits land. Only the largest waves crest.
While everyday wind waves have a wavelength (from crest to crest) of about 100 metres (330 ft) and a height of roughly 2 metres (6.6 ft), a tsunami in the deep ocean has a wavelength of about 200 kilometres (120 mi). Such a wave travels at well over 800 kilometres per hour (500 mph), but due to the enormous wavelength the wave oscillation at any given point takes 20 or 30 minutes to complete a cycle and has an amplitude of only about 1 metre (3.3 ft).[15] This makes tsunamis difficult to detect over deep water. Ships rarely notice their passage.
As the tsunami approaches the coast and the waters become shallow, wave shoaling compresses the wave and its velocity slows below 80 kilometres per hour (50 mph). Its wavelength diminishes to less than 20 kilometres (12 mi) and its amplitude grows enormously, producing a distinctly visible wave. Since the wave still has such a long wavelength, the tsunami may take minutes to reach full height. Except for the very largest tsunamis, the approaching wave does not break (like a surf break), but rather appears like a fast moving tidal bore.[16] Open bays and coastlines adjacent to very deep water may shape the tsunami further into a step-like wave with a steep-breaking front.
When the tsunami's wave peak reaches the shore, the resulting temporary rise in sea level is termed 'run up'. Run up is measured in metres above a reference sea level.[16] A large tsunami may feature multiple waves arriving over a period of hours, with significant time between the wave crests. The first wave to reach the shore may not have the highest run up.[17]
About 80% of tsunamis occur in the Pacific Ocean, but are possible wherever there are large bodies of water, including lakes. They are caused by earthquakes, landslides, volcanic explosions, and bolides.
Drawback
If the first part of a tsunami to reach land is a trough—called a drawback—rather than a wave crest, the water along the shoreline recedes dramatically, exposing normally submerged areas.
A drawback occurs because the water propagates outwards with the trough of the wave at its front. Drawback begins before the wave arrives at an interval equal to half of the wave's period. Drawback can exceed hundreds of metres, and people unaware of the danger sometimes remain near the shore to satisfy their curiosity or to collect fish from the exposed seabed. During the Indian Ocean tsunami, the sea withdrew and many people went onto the exposed sea bed to investigate.[citation needed] Photos show people walking on the normally submerged areas with the advancing wave in the background.[citation needed] Few survived.[citation needed]
Scales of intensity and magnitude
As with earthquakes, several attempts have been made to set up scales of tsunami intensity or magnitude to allow comparison between different events.[18]
Intensity scales
The first scales used routinely to measure the intensity of tsunami were the Sieberg-Ambraseys scale, used in the Mediterranean Sea and the Imamura-Iida intensity scale, used in the Pacific Ocean. The latter scale was modified by Soloviev, who calculated the Tsunami intensity I according to the formula

\,\mathit{I} = \frac{1}{2} + \log_{2} \mathit{H}_{av}

where Hav is the average wave height along the nearest coast. This scale, known as the Soloviev-Imamura tsunami intensity scale, is used in the global tsunami catalogues compiled by the NGDC/NOAA and the Novosibirsk Tsunami Laboratory as the main parameter for the size of the tsunami.
Magnitude scales
The first scale that genuinely calculated a magnitude for a tsunami, rather than an intensity at a particular location was the ML scale proposed by Murty & Loomis based on the potential energy.[18] Difficulties in calculating the potential energy of the tsunami mean that this scale is rarely used. Abe introduced the tsunami magnitude scale Mt, calculated from,

\,\mathit{M}_{t} = {a} \log h + {b} \log R = \mathit{D}

where h is the maximum tsunami-wave amplitude (in m) measured by a tide gauge at a distance R from the epicenter, a, b & D are constants used to make the Mt scale match as closely as possible with the moment magnitude scale.[19]
Warnings and predictions
See also: Tsunami warning system

One of the deep water buoys used in the DART tsunami warning system
Drawbacks can serve as a brief warning. People who observe drawback (many survivors report an accompanying sucking sound), can survive only if they immediately run for high ground or seek the upper floors of nearby buildings. In 2004, ten-year old Tilly Smith of Surrey, England, was on Maikhao beach in Phuket, Thailand with her parents and sister, and having learned about tsunamis recently in school, told her family that a tsunami might be imminent. Her parents warned others minutes before the wave arrived, saving dozens of lives. She credited her geography teacher, Andrew Kearney.
In the 2004 Indian Ocean tsunami drawback was not reported on the African coast or any other eastern coasts it reached. This was because the wave moved downwards on the eastern side of the fault line and upwards on the western side. The western pulse hit coastal Africa and other western areas.
A tsunami cannot be precisely predicted, even if the magnitude and location of an earthquake is known. Geologists, oceanographers, and seismologists analyse each earthquake and based on many factors may or may not issue a tsunami warning. However, there are some warning signs of an impending tsunami, and automated systems can provide warnings immediately after an earthquake in time to save lives. One of the most successful systems uses bottom pressure sensors that are attached to buoys. The sensors constantly monitor the pressure of the overlying water column. This is deduced through the calculation:

\,\! P = \rho gh

where
P = the overlying pressure in newtons per metre square,
ρ = the density of the seawater= 1.1 x 103 kg/m3,
g = the acceleration due to gravity= 9.8 m/s2 and
h = the height of the water column in metres.
Hence for a water column of 5,000 m depth the overlying pressure is equal to

\,\! P = \rho gh=\left(1.1 \times 10^3 \ \frac{\mathrm{kg}}{\mathrm{m}^3}\right)\left(9.8 \ \frac{\mathrm{m}}{\mathrm{s}^2}\right)\left(5.0 \times 10^3 \ \mathrm{m}\right)=5.4 \times 10^7 \ \frac{\mathrm{N}}{\mathrm{m}^2}=54 \ \mathrm{MPa}

or about 5500 tonnes-force per square metre.
Regions with a high tsunami risk typically use tsunami warning systems to warn the population before the wave reaches land. On the west coast of the United States, which is prone to Pacific Ocean tsunami, warning signs indicate evacuation routes. In Japan, the community is well-educated about earthquakes and tsunamis, and along the Japanese shorelines the tsunami warning signs are reminders of the natural hazards together with a network of warning sirens, typically at the top of the cliff of surroundings hills.[20]
The Pacific Tsunami Warning System is based in Honolulu, Hawaiʻi. It monitors Pacific Ocean seismic activity. A sufficiently large earthquake magnitude and other information triggers a tsunami warning. While the subduction zones around the Pacific are seismically active, not all earthquakes generate tsunami. Computers assist in analysing the tsunami risk of every earthquake that occurs in the Pacific Ocean and the adjoining land masses.
Tsunami hazard sign at Bamfield, British Columbia

A tsunami warning sign on a seawall in Kamakura, Japan, 2004.

The monument to the victims of tsunami at Laupahoehoe, Hawaii

Tsunami memorial in Kanyakumari beach
Photo of seawall with building in background
A seawall at Tsu, Japan
Photo of evacuation sign
Tsunami Evacuation Route signage along U.S. Route 101, in Washington
As a direct result of the Indian Ocean tsunami, a re-appraisal of the tsunami threat for all coastal areas is being undertaken by national governments and the United Nations Disaster Mitigation Committee. A tsunami warning system is being installed in the Indian Ocean.
Computer models can predict tsunami arrival, usually within minutes of the arrival time. Bottom pressure sensors relay information in real time. Based on these pressure readings and other seismic information and the seafloor's shape (bathymetry) and coastal topography, the models estimate the amplitude and surge height of the approaching tsunami. All Pacific Rim countries collaborate in the Tsunami Warning System and most regularly practice evacuation and other procedures. In Japan, such preparation is mandatory for government, local authorities, emergency services and the population.
Some zoologists hypothesise that some animal species have an ability to sense subsonic Rayleigh waves from an earthquake or a tsunami. If correct, monitoring their behavior could provide advance warning of earthquakes, tsunami etc. However, the evidence is controversial and is not widely accepted. There are unsubstantiated claims about the Lisbon quake that some animals escaped to higher ground, while many other animals in the same areas drowned. The phenomenon was also noted by media sources in Sri Lanka in the 2004 Indian Ocean earthquake.[21][22] It is possible that certain animals (e.g., elephants) may have heard the sounds of the tsunami as it approached the coast. The elephants' reaction was to move away from the approaching noise. By contrast, some humans went to the shore to investigate and many drowned as a result.
It is not possible to prevent a tsunami. However, in some tsunami-prone countries some earthquake engineering measures have been taken to reduce the damage caused on shore. Japan built many tsunami walls of up to 4.5 metres (15 ft) to protect populated coastal areas. Other localities have built floodgates and channels to redirect the water from incoming tsunami. However, their effectiveness has been questioned, as tsunami often overtop the barriers. For instance, the Okushiri, Hokkaidō tsunami which struck Okushiri Island of Hokkaidō within two to five minutes of the earthquake on July 12, 1993 created waves as much as 30 metres (100 ft) tall—as high as a 10-story building. The port town of Aonae was completely surrounded by a tsunami wall, but the waves washed right over the wall and destroyed all the wood-framed structures in the area. The wall may have succeeded in slowing down and moderating the height of the tsunami, but it did not prevent major destruction and loss of life.[23]
Natural factors such as shoreline tree cover can mitigate tsunami effects. Some locations in the path of the 2004 Indian Ocean tsunami escaped almost unscathed because trees such as coconut palms and mangroves absorbed the tsunami's energy. In one striking example, the village of Naluvedapathy in India's Tamil Nadu region suffered only minimal damage and few deaths because the wave broke against a forest of 80,244 trees planted along the shoreline in 2002 in a bid to enter the Guinness Book of Records.[24] Environmentalists have suggested tree planting along tsunami-prone seacoasts. Trees require years to grow to a useful size, but such plantations could offer a much cheaper and longer-lasting means of tsunami mitigation than artificial barriers


TSUNAMI



Photo showing four people in the foregound and the tsunami surge in the background.
Tsunami striking Thailand on December 26, 2004
A tsunami (Japanese: 津波 [tsɯnami], lit. 'harbor wave';[1] English pronunciation: /suːˈnɑːmi/ soo-NAH-mee) or tidal wave is a series of water waves (called a tsunami wave train[2]) caused by the displacement of a large volume of a body of water, usually an ocean, but can occur in large lakes. Tsunamis are a frequent occurrence in Japan; approximately 195 events have been recorded.[3] Due to the immense volumes of water and energy involved, tsunamis can devastate coastal regions.
Earthquakes, volcanic eruptions and other underwater explosions (including detonations of underwater nuclear devices), landslides and other mass movements, meteorite ocean impacts or similar impact events, and other disturbances above or below water all have the potential to generate a tsunami.
The Greek historian Thucydides was the first to relate tsunami to submarine earthquakes,[4][5] but understanding of tsunami's nature remained slim until the 20th century and is the subject of ongoing research. Many early geological, geographical, and oceanographic texts refer to tsunamis as "seismic sea waves."
Some meteorological conditions, such as deep depressions that cause tropical cyclones, can generate a storm surge, called a meteotsunami, which can raise tides several metres above normal levels. The displacement comes from low atmospheric pressure within the centre of the depression. As these storm surges reach shore, they may resemble (though are not) tsunamis, inundating vast areas of land. Such a storm surge inundated Burma in May 2008.

Etymology

Lisbon earthquake and tsunami in 1775.

The Russians of Pavel Lebedev-Lastochkin in Japan, with their ships tossed inland by a tsunami, meeting some Japanese in 1779.
The term tsunami comes from the Japanese, meaning "harbor" (tsu, 津) and "wave" (nami, 波). (For the plural, one can either follow ordinary English practice and add an s, or use an invariable plural as in the Japanese.[6])
Tsunami are sometimes referred to as tidal waves. In recent years, this term has fallen out of favor, especially in the scientific community, because tsunami actually have nothing to do with tides. The once-popular term derives from their most common appearance, which is that of an extraordinarily high tidal bore. Tsunami and tides both produce waves of water that move inland, but in the case of tsunami the inland movement of water is much greater and lasts for a longer period, giving the impression of an incredibly high tide. Although the meanings of "tidal" include "resembling"[7] or "having the form or character of"[8] the tides, and the term tsunami is no more accurate because tsunami are not limited to harbours, use of the term tidal wave is discouraged by geologists and oceanographers.
There are only a few other languages that have a native word for this disastrous wave. In the Tamil language, the word is aazhi peralai. In the Acehnese language, it is ië beuna or alôn buluëk[9] (Depending on the dialect. Note that in the fellow Austronesian language of Tagalog, a major language in the Philippines, alon means "wave".) On Simeulue island, off the western coast of Sumatra in Indonesia, in the Defayan language the word is smong, while in the Sigulai language it is emong.[10]
Generation mechanisms
The principal generation mechanism (or cause) of a tsunami is the displacement of a substantial volume of water or perturbation of the sea.[11] This displacement of water is usually attributed to either earthquakes, landslides, volcanic eruptions, or more rarely by meteorites and nuclear tests.[12][13] The waves formed in this way are then sustained by gravity. It is important to note that tides do not play any part in the generation of tsunamis, hence referring to tsunamis as 'tidal waves' is inaccurate.
Seismicity generated tsunamis
Tsunamis can be generated when the sea floor abruptly deforms and vertically displaces the overlying water. Tectonic earthquakes are a particular kind of earthquake that are associated with the earth's crustal deformation; when these earthquakes occur beneath the sea, the water above the deformed area is displaced from its equilibrium position.[14] More specifically, a tsunami can be generated when thrust faults associated with convergent or destructive plate boundaries move abruptly, resulting in water displacement, due to the vertical component of movement involved. Movement on normal faults will also cause displacement of the seabed, but the size of the largest of such events is normally too small to give rise to a significant tsunami.
Drawing of tectonic plate boundary before earthquake.

Overriding plate bulges under strain, causing tectonic uplift.

Plate slips, causing subsidence and releasing energy into water.

The energy released produces tsunami waves.
Tsunamis have a small amplitude (wave height) offshore, and a very long wavelength (often hundreds of kilometers long), which is why they generally pass unnoticed at sea, forming only a slight swell usually about 300 millimetres (12 in) above the normal sea surface. They grow in height when they reach shallower water, in a wave shoaling process described below. A tsunami can occur in any tidal state and even at low tide can still inundate coastal areas.
On April 1, 1946, a magnitude-7.8 (Richter Scale) earthquake occurred near the Aleutian Islands, Alaska. It generated a tsunami which inundated Hilo on the island of Hawai'i with a 14 metres (46 ft) high surge. The area where the earthquake occurred is where the Pacific Ocean floor is subducting (or being pushed downwards) under Alaska.
Examples of tsunami at locations away from convergent boundaries include Storegga about 8,000 years ago, Grand Banks 1929, Papua New Guinea 1998 (Tappin, 2001). The Grand Banks and Papua New Guinea tsunamis came from earthquakes which destabilized sediments, causing them to flow into the ocean and generate a tsunami. They dissipated before traveling transoceanic distances.
The cause of the Storegga sediment failure is unknown. Possibilities include an overloading of the sediments, an earthquake or a release of gas hydrates (methane etc.)
The 1960 Valdivia earthquake (Mw 9.5) (19:11 hrs UTC), 1964 Alaska earthquake (Mw 9.2), and 2004 Indian Ocean earthquake (Mw 9.2) (00:58:53 UTC) are recent examples of powerful megathrust earthquakes that generated tsunamis (known as teletsunamis) that can cross entire oceans. Smaller (Mw 4.2) earthquakes in Japan can trigger tsunamis (called local and regional tsunamis) that can only devastate nearby coasts, but can do so in only a few minutes.
In the 1950s, it was discovered that larger tsunamis than had previously been believed possible could be caused by giant landslides. These phenomena rapidly displace large water volumes, as energy from falling debris or expansion transfers to the water at a rate faster than the water can absorb. Their existence was confirmed in 1958, when a giant landslide in Lituya Bay, Alaska, caused the highest wave ever recorded, which had a height of 524 metres (over 1700 feet). The wave didn't travel far, as it struck land almost immediately. Two people fishing in the bay were killed, but another boat amazingly managed to ride the wave. Scientists named these waves megatsunami.
Scientists discovered that extremely large landslides from volcanic island collapses can generate megatsunami, that can travel trans-oceanic distances.

Characteristics

When the wave enters shallow water, it slows down and its amplitude (height) increases.

The wave further slows and amplifies as it hits land. Only the largest waves crest.
While everyday wind waves have a wavelength (from crest to crest) of about 100 metres (330 ft) and a height of roughly 2 metres (6.6 ft), a tsunami in the deep ocean has a wavelength of about 200 kilometres (120 mi). Such a wave travels at well over 800 kilometres per hour (500 mph), but due to the enormous wavelength the wave oscillation at any given point takes 20 or 30 minutes to complete a cycle and has an amplitude of only about 1 metre (3.3 ft).[15] This makes tsunamis difficult to detect over deep water. Ships rarely notice their passage.
As the tsunami approaches the coast and the waters become shallow, wave shoaling compresses the wave and its velocity slows below 80 kilometres per hour (50 mph). Its wavelength diminishes to less than 20 kilometres (12 mi) and its amplitude grows enormously, producing a distinctly visible wave. Since the wave still has such a long wavelength, the tsunami may take minutes to reach full height. Except for the very largest tsunamis, the approaching wave does not break (like a surf break), but rather appears like a fast moving tidal bore.[16] Open bays and coastlines adjacent to very deep water may shape the tsunami further into a step-like wave with a steep-breaking front.
When the tsunami's wave peak reaches the shore, the resulting temporary rise in sea level is termed 'run up'. Run up is measured in metres above a reference sea level.[16] A large tsunami may feature multiple waves arriving over a period of hours, with significant time between the wave crests. The first wave to reach the shore may not have the highest run up.[17]
About 80% of tsunamis occur in the Pacific Ocean, but are possible wherever there are large bodies of water, including lakes. They are caused by earthquakes, landslides, volcanic explosions, and bolides.
Drawback
If the first part of a tsunami to reach land is a trough—called a drawback—rather than a wave crest, the water along the shoreline recedes dramatically, exposing normally submerged areas.
A drawback occurs because the water propagates outwards with the trough of the wave at its front. Drawback begins before the wave arrives at an interval equal to half of the wave's period. Drawback can exceed hundreds of metres, and people unaware of the danger sometimes remain near the shore to satisfy their curiosity or to collect fish from the exposed seabed. During the Indian Ocean tsunami, the sea withdrew and many people went onto the exposed sea bed to investigate.[citation needed] Photos show people walking on the normally submerged areas with the advancing wave in the background.[citation needed] Few survived.[citation needed]
Scales of intensity and magnitude
As with earthquakes, several attempts have been made to set up scales of tsunami intensity or magnitude to allow comparison between different events.[18]
Intensity scales
The first scales used routinely to measure the intensity of tsunami were the Sieberg-Ambraseys scale, used in the Mediterranean Sea and the Imamura-Iida intensity scale, used in the Pacific Ocean. The latter scale was modified by Soloviev, who calculated the Tsunami intensity I according to the formula

\,\mathit{I} = \frac{1}{2} + \log_{2} \mathit{H}_{av}

where Hav is the average wave height along the nearest coast. This scale, known as the Soloviev-Imamura tsunami intensity scale, is used in the global tsunami catalogues compiled by the NGDC/NOAA and the Novosibirsk Tsunami Laboratory as the main parameter for the size of the tsunami.
Magnitude scales
The first scale that genuinely calculated a magnitude for a tsunami, rather than an intensity at a particular location was the ML scale proposed by Murty & Loomis based on the potential energy.[18] Difficulties in calculating the potential energy of the tsunami mean that this scale is rarely used. Abe introduced the tsunami magnitude scale Mt, calculated from,

\,\mathit{M}_{t} = {a} \log h + {b} \log R = \mathit{D}

where h is the maximum tsunami-wave amplitude (in m) measured by a tide gauge at a distance R from the epicenter, a, b & D are constants used to make the Mt scale match as closely as possible with the moment magnitude scale.[19]
Warnings and predictions
See also: Tsunami warning system

One of the deep water buoys used in the DART tsunami warning system
Drawbacks can serve as a brief warning. People who observe drawback (many survivors report an accompanying sucking sound), can survive only if they immediately run for high ground or seek the upper floors of nearby buildings. In 2004, ten-year old Tilly Smith of Surrey, England, was on Maikhao beach in Phuket, Thailand with her parents and sister, and having learned about tsunamis recently in school, told her family that a tsunami might be imminent. Her parents warned others minutes before the wave arrived, saving dozens of lives. She credited her geography teacher, Andrew Kearney.
In the 2004 Indian Ocean tsunami drawback was not reported on the African coast or any other eastern coasts it reached. This was because the wave moved downwards on the eastern side of the fault line and upwards on the western side. The western pulse hit coastal Africa and other western areas.
A tsunami cannot be precisely predicted, even if the magnitude and location of an earthquake is known. Geologists, oceanographers, and seismologists analyse each earthquake and based on many factors may or may not issue a tsunami warning. However, there are some warning signs of an impending tsunami, and automated systems can provide warnings immediately after an earthquake in time to save lives. One of the most successful systems uses bottom pressure sensors that are attached to buoys. The sensors constantly monitor the pressure of the overlying water column. This is deduced through the calculation:

\,\! P = \rho gh

where
P = the overlying pressure in newtons per metre square,
ρ = the density of the seawater= 1.1 x 103 kg/m3,
g = the acceleration due to gravity= 9.8 m/s2 and
h = the height of the water column in metres.
Hence for a water column of 5,000 m depth the overlying pressure is equal to

\,\! P = \rho gh=\left(1.1 \times 10^3 \ \frac{\mathrm{kg}}{\mathrm{m}^3}\right)\left(9.8 \ \frac{\mathrm{m}}{\mathrm{s}^2}\right)\left(5.0 \times 10^3 \ \mathrm{m}\right)=5.4 \times 10^7 \ \frac{\mathrm{N}}{\mathrm{m}^2}=54 \ \mathrm{MPa}

or about 5500 tonnes-force per square metre.
Regions with a high tsunami risk typically use tsunami warning systems to warn the population before the wave reaches land. On the west coast of the United States, which is prone to Pacific Ocean tsunami, warning signs indicate evacuation routes. In Japan, the community is well-educated about earthquakes and tsunamis, and along the Japanese shorelines the tsunami warning signs are reminders of the natural hazards together with a network of warning sirens, typically at the top of the cliff of surroundings hills.[20]
The Pacific Tsunami Warning System is based in Honolulu, Hawaiʻi. It monitors Pacific Ocean seismic activity. A sufficiently large earthquake magnitude and other information triggers a tsunami warning. While the subduction zones around the Pacific are seismically active, not all earthquakes generate tsunami. Computers assist in analysing the tsunami risk of every earthquake that occurs in the Pacific Ocean and the adjoining land masses.
Tsunami hazard sign at Bamfield, British Columbia

A tsunami warning sign on a seawall in Kamakura, Japan, 2004.

The monument to the victims of tsunami at Laupahoehoe, Hawaii

Tsunami memorial in Kanyakumari beach
Photo of seawall with building in background
A seawall at Tsu, Japan
Photo of evacuation sign
Tsunami Evacuation Route signage along U.S. Route 101, in Washington
As a direct result of the Indian Ocean tsunami, a re-appraisal of the tsunami threat for all coastal areas is being undertaken by national governments and the United Nations Disaster Mitigation Committee. A tsunami warning system is being installed in the Indian Ocean.
Computer models can predict tsunami arrival, usually within minutes of the arrival time. Bottom pressure sensors relay information in real time. Based on these pressure readings and other seismic information and the seafloor's shape (bathymetry) and coastal topography, the models estimate the amplitude and surge height of the approaching tsunami. All Pacific Rim countries collaborate in the Tsunami Warning System and most regularly practice evacuation and other procedures. In Japan, such preparation is mandatory for government, local authorities, emergency services and the population.
Some zoologists hypothesise that some animal species have an ability to sense subsonic Rayleigh waves from an earthquake or a tsunami. If correct, monitoring their behavior could provide advance warning of earthquakes, tsunami etc. However, the evidence is controversial and is not widely accepted. There are unsubstantiated claims about the Lisbon quake that some animals escaped to higher ground, while many other animals in the same areas drowned. The phenomenon was also noted by media sources in Sri Lanka in the 2004 Indian Ocean earthquake.[21][22] It is possible that certain animals (e.g., elephants) may have heard the sounds of the tsunami as it approached the coast. The elephants' reaction was to move away from the approaching noise. By contrast, some humans went to the shore to investigate and many drowned as a result.
It is not possible to prevent a tsunami. However, in some tsunami-prone countries some earthquake engineering measures have been taken to reduce the damage caused on shore. Japan built many tsunami walls of up to 4.5 metres (15 ft) to protect populated coastal areas. Other localities have built floodgates and channels to redirect the water from incoming tsunami. However, their effectiveness has been questioned, as tsunami often overtop the barriers. For instance, the Okushiri, Hokkaidō tsunami which struck Okushiri Island of Hokkaidō within two to five minutes of the earthquake on July 12, 1993 created waves as much as 30 metres (100 ft) tall—as high as a 10-story building. The port town of Aonae was completely surrounded by a tsunami wall, but the waves washed right over the wall and destroyed all the wood-framed structures in the area. The wall may have succeeded in slowing down and moderating the height of the tsunami, but it did not prevent major destruction and loss of life.[23]
Natural factors such as shoreline tree cover can mitigate tsunami effects. Some locations in the path of the 2004 Indian Ocean tsunami escaped almost unscathed because trees such as coconut palms and mangroves absorbed the tsunami's energy. In one striking example, the village of Naluvedapathy in India's Tamil Nadu region suffered only minimal damage and few deaths because the wave broke against a forest of 80,244 trees planted along the shoreline in 2002 in a bid to enter the Guinness Book of Records.[24] Environmentalists have suggested tree planting along tsunami-prone seacoasts. Trees require years to grow to a useful size, but such plantations could offer a much cheaper and longer-lasting means of tsunami mitigation than artificial barriers.


source : http://id.wikipedia.org/wiki/Tsunami

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