Vulkanik kul - Volcanic ash

"Ash bulut" bu erga yo'naltiradi. Umumiy mavzu uchun qarang Ash. Boshqa maqsadlar uchun qarang Ash (ajralish).
Vulkanik kul atmosferaga tarqalganda uzun fan shaklida oqadi.
2008 yil otilishidan kul buluti Chaiten vulqoni, Chili bo'ylab cho'zilgan Patagoniya dan Tinch okeani uchun Atlantika okeani.
Kul shamasi ko'tarilmoqda Eyjafjallajökull 2010 yil 17 aprelda.
To'xtab turgan joyda vulkanik kul yotadi McDonnell-Duglas DC-10-30 1991 yil otilishi paytida Pinatubo tog'i, samolyotning dumida turishiga olib keladi. Yiqilgan kul xuddi shunga o'xshash tarzda o'zini tutadi qor, depozitlarning katta og'irligi binolar va transport vositalariga jiddiy zarar etkazishi mumkin, bu erda ko'rinib turganidek, konlar 120 tonnalik samolyotning tortishish markazining siljishiga olib keldi.

Vulkanik kul toshning parchalaridan iborat, minerallar va vulkanik shisha davomida yaratilgan vulkanik otilishlar va diametri 2 mm dan kam (0,079 dyuym).[1] Vulkanik kul atamasi ko'pincha barchaga murojaat qilish uchun erkin ishlatiladi portlovchi portlash mahsulotlar (to'g'ri deb nomlangan tefra ), shu jumladan 2 mm dan katta zarralar. Vulkanik kul tarkibida erigan gazlar paydo bo'lganda portlovchi vulkanik otilishi paytida hosil bo'ladi magma kengaytirish va atmosferaga zo'ravonlik bilan qochish. Gazlarning kuchi magmani parchalaydi va atmosferaga chiqarib yuboradi, u erda vulkanik tosh va shisha parchalariga aylanadi. Magma suv bilan aloqa qilganda ham kul hosil bo'ladi freatomagmatik portlashlar, magmaning parchalanishiga olib keladigan suvning portlashi natijasida bug 'chiqishi mumkin. Havoda bo'lganidan keyin kul shamol orqali minglab kilometr uzoqlikda tashiladi.

Keng tarqalishi tufayli kul jamiyatga bir qator ta'sir ko'rsatishi mumkin, shu jumladan hayvonlar va odamlar salomatligi, aviatsiyani to'xtatish, muhim infratuzilmani to'xtatish (masalan, elektr ta'minoti tizimlari, telekommunikatsiya, suv va chiqindi suv tarmoqlari, transport), asosiy sanoat tarmoqlari (masalan, qishloq xo'jaligi), binolar va inshootlar.

Shakllanish

454 million yillik vulkanik kul ohaktosh katakombalarida Buyuk Pyotrning dengiz qal'asi yilda Estoniya yaqin Laagri. Bu eng qadimgi birining qoldig'i katta portlashlar saqlanib qolgan. Qora kamera linzalari qopqog'ining diametri 58 mm (2,3 dyuym).

Vulkanik kul portlovchi vulkanik portlashlar, freatomagmatik portlashlar va piroklastik zichlikdagi oqimlarda tashish paytida hosil bo'ladi.

Magma sodir bo'lganda portlovchi portlashlar sodir bo'ladi dekompressiyalar u ko'tarilayotganda, eritishga imkon beradi uchuvchi (ustunlik bilan suv va karbonat angidrid ) gaz pufakchalarida eriydi.[2] Ko'pik pufakchalari ko'payib ketganda ko'pik hosil bo'ladi, bu esa kamayadi zichlik magmani, uni o'tkazgichni tezlashtiradi. Parchalanish pufakchalar otilib chiqadigan aralashmaning ~ 70-80 vol% foizini egallaganda sodir bo'ladi.[3] Parchalanish sodir bo'lganda, shiddat bilan kengayib boruvchi pufakchalar magmani parchalanib bo'laklarga ajratib yuboradi atmosfera bu erda ular kul zarralariga aylanadi. Parchalanish kul hosil bo'lishining juda samarali jarayonidir va suv qo'shilmasdan ham juda mayda kul hosil qilish qobiliyatiga ega.[4]

Vulkanik kul freatomagmatik portlashlar paytida ham hosil bo'ladi. Ushbu portlashlar paytida parchalanish magma suv havzalari bilan (masalan, dengiz, ko'llar va botqoqlar) er osti suvlari, qor yoki muz bilan aloqa qilganda paydo bo'ladi. Suvning qaynash nuqtasidan sezilarli darajada issiqroq bo'lgan magma suv bilan aloqa qilganda, izolyatsion bug 'plyonkasi hosil bo'ladi (Leydenfrost ta'siri ).[5] Oxir oqibat bu bug 'plyonkasi qulab tushadi, bu esa sovuq suv va issiq magmaning to'g'ridan-to'g'ri bog'lanishiga olib keladi. Bu issiqlik uzatilishini kuchaytiradi, bu esa suvning tez kengayishiga va keyinchalik vulqon shamolidan chiqariladigan magmaning kichik zarrachalarga bo'linishiga olib keladi. Parchalanish qayta aloqa mexanizmini yaratib, magma va suv o'rtasidagi aloqa maydonini ko'payishiga olib keladi,[5] mayda kul zarralarini yanada parchalanishiga va ishlab chiqarilishiga olib keladi.

Piroklastik zichlik oqimlari shuningdek, kul zarralarini hosil qilishi mumkin. Ular odatda tomonidan ishlab chiqariladi lava gumbazi qulashi yoki qulashi portlash ustuni.[6] Piroklastik zichlikdagi zarralar oqimlari ichida ishqalanish zarralar bir-biri bilan o'zaro ta'sirlashishi natijasida paydo bo'ladi, natijada don hajmi kamayadi va mayda donali kul zarralari hosil bo'ladi. Bundan tashqari, kulni pomza bo'laklari ikkilamchi parchalanishi paytida, oqim ichida issiqlik saqlanib qolishi tufayli hosil bo'lishi mumkin.[7] Ushbu jarayonlar ko'p miqdordagi juda mayda donli kulni hosil qiladi, ular piroklastik zichlik oqimlaridan birgalikda ignimbritli kul shilimshiqlarida tozalanadi.

Vulkanik kulning fizikaviy va kimyoviy xususiyatlari, avvalo, vulqon otilishi uslubi bilan boshqariladi.[8] Vulkanlar magma kimyosi, kristal tarkibi, harorati va otilib chiqqan magmaning erigan gazlari tomonidan boshqariladigan va ular yordamida tasniflanishi mumkin bo'lgan portlash uslublarini namoyish etadi. vulkanik portlash ko'rsatkichi (VEI). Effektiv portlashlar (VEI 1) ning bazaltika tarkibi <105 m3 juda portlovchi portlashlar (VEI 5+) riyolitik va datsitik tarkibi katta miqdorda kiritishi mumkin (> 10)9 m3) atmosferaga chiqarib tashlash. Ishlab chiqarilgan kul miqdorini nazorat qiluvchi yana bir parametr - bu otilish davomiyligi: otish qancha uzoq davom etsa, shuncha ko'p kul hosil bo'ladi. Masalan, ning ikkinchi bosqichi 2010 yil Eyjafjallajokullning otilishi 8 km balandlikdagi püskürtme ustuniga qaramay VEI 4 deb tasniflangan, ammo portlash bir oy davom etdi va bu atmosferaga katta miqdordagi kulni tashlashga imkon berdi.

Xususiyatlari

Kimyoviy

Vulqon kulida mavjud bo'lgan minerallarning turlari u chiqadigan magmaning kimyosiga bog'liq. Eng ko'p topilgan elementlarni hisobga olgan holda silikat magma mavjud kremniy va kislorod, vulqon otilishi paytida hosil bo'lgan magmaning (va shu sababli kulning) har xil turlari eng ko'p ularning tarkibidagi kremniy tarkibiga qarab izohlanadi. Kam energiya otilishi bazalt ~ 45-55% kremniy o'z ichiga olgan, odatda boy bo'lgan xarakterli quyuq rangli kulni hosil qiling temir (Fe) va magniy (Mg). Eng portlovchi riyolit otilishlar hosil qiladi a zararli kremniy tarkibida yuqori bo'lgan kul (> 69%), boshqa oraliq tarkibli kul turlari esa (masalan, andezit yoki datsit ) kremniy tarkibida 55-69% gacha.

Asosiy gazlar vulkanik faollik paytida ajralib chiqadi suv, karbonat angidrid, oltingugurt dioksidi, vodorod, vodorod sulfidi, uglerod oksidi va vodorod xlorid.[9] Bular oltingugurt va halogen gazlar va metallar atmosferadan kimyoviy reaksiya, quruq va ho'l cho'kma jarayonlari va shu bilan tozalanadi adsorbsiya vulkanik kul yuzasiga

Bu uzoq vaqtdan beri tan olingan sulfat va haloid (birinchi navbatda xlorid va ftor ) yangi vulkanik kuldan aralashmalar osongina safarbar qilinadi.;[10][11][12] Ushbu tuzlar tezkorlik natijasida hosil bo'lishi ehtimoldan yiroq emas kislota eritmasi bilan ta'minlangan deb hisoblanadigan portlash plyusidagi kul zarralari kationlar sulfat va galogenid yotqizilishida ishtirok etadi tuzlar.

55 ga yaqin ion turlari yangi kulda bo'lganligi haqida xabar berilgan suv oqimi,[9] odatda eng ko'p uchraydigan turlar kationlardir Na+, K+, Ca2+ va Mg2+ va anionlar Cl, F va SO42−.[9][12] Suyuq suvlarda mavjud bo'lgan ionlar orasidagi molyar nisbatlar shuni ko'rsatadiki, ko'p hollarda bu elementlar oddiy tuzlar kabi mavjud NaCl va CaSO4.[9][13][14][15] Dan kulga ketma-ket yuvib tashlash tajribasida 1980 yilda Sent-Xelen tog'ining otilishi, xlorid tuzlari eng oson eruvchan deb topildi, keyin esa sulfat tuzlari[13] Ftor birikmalar umuman ozgina eriydi (masalan, CaF2, MgF2 ) ning florid tuzlari bundan mustasno gidroksidi metallar kabi birikmalar kaltsiy geksaflorosilikat (CaSiF6).[16] The pH kislotali gaz kondensati mavjudligiga qarab (birinchi navbatda gazlar natijasida) yangi kul oqimi juda o'zgaruvchan SO2, HCl va HF püskürme plumunda) kul yuzasida.

The kristalli qattiq tuzilish tuzlari ko'proq izolyator a ga qaraganda dirijyor.[17][18][19][20] Biroq, tuzlar bir marta eritilgan namlik manbai eritmasiga (masalan, tuman, tuman, ozgina yomg'ir va boshqalar), kul korroziv va elektr o'tkazuvchan bo'lishi mumkin. Yaqinda o'tkazilgan bir tadqiqot shuni ko'rsatdiki, vulkanik kulning elektr o'tkazuvchanligi (1) namlik miqdori oshishi, (2) eruvchan tuz miqdori oshishi va (3) zichlashi (massa zichligi) ortishi bilan ortadi.[20] Vulkanik kulning elektr tokini o'tkazish qobiliyati elektr ta'minoti tizimlariga katta ta'sir ko'rsatadi.

Jismoniy

Komponentlar

Vulkanik kulning mayda zarrachasini yoping, uning ko'plab mayda quvurli teshiklarini ko'rsating.
Vulkanik kul zarrasi Sent-Xelen tog'i.

Magmatik portlashlar paytida paydo bo'lgan vulkanik kul zarralari turli fraktsiyalardan iborat shishasimon (shishasimon, kristall bo'lmagan), kristalli yoki litik (magmatik bo'lmagan) zarralar. Past haroratda hosil bo'lgan kul yopishqoqlik magmatik portlashlar (masalan, Gavayi va Stromboliy bazalt püskürmeleri) portlash jarayoniga bog'liq bo'lgan turli xil piroklastlarni hosil qiladi. Masalan, Gavayi lava favvoralaridan yig'ilgan kul tarkibiga kiradi sideromelan o'z ichiga olgan (och jigarrang bazaltik shisha) piroklastlar mikrolitlar (kichik söndürme kristallari, noyob mineral bilan aralashmaslik kerak mikrolit ) va fenokristlar. Bazaltning biroz yopishqoq püskürmeleri (masalan, Strombolyan), tartibsiz sideromelan tomchilaridan blokgacha turli xil piroklastlarni hosil qiladi. taxilit (qora rangdan to'q jigarranggacha bo'lgan mikrokristalli piroklastlar). Aksincha, yuqori silisli kul (masalan, riolit) ning ko'p qismi changlangan mahsulotlardan iborat pomza (vitrik parchalar), individual fenokristlar (kristalli fraktsiya) va ba'zi litik bo'laklar (ksenolitlar ).[21]

Freatik portlashlar paytida hosil bo'lgan kul, asosan, gil matritsada gidrotermik o'zgargan litik va mineral bo'laklardan iborat. Zarrachalar yuzalari ko'pincha qoplanadi agregatlar ning seolit piroklast turlarini aniqlash uchun faqat kristallar yoki gil va faqat reliktli to'qimalar qoladi.[21]

Morfologiya

Vashington shtatidagi Sent-Xelen tog'ining 1980 yil otilishi natijasida hosil bo'lgan kulning nurli mikroskopli tasviri.

Vulqon kulining morfologiyasi (shakli) turli xil portlashlar va kinematik jarayonlarning ko'pligi bilan boshqariladi.[21][22] Past viskoziteli magmalarning chiqishi (masalan, bazalt) odatda tomchi shaklidagi zarralarni hosil qiladi. Ushbu tomchi shakli qisman tomonidan boshqariladi sirt tarangligi, teshikdan chiqqandan keyin tomchilarning tezlashishi va havo ishqalanishi. Shakllar mukammal sharlardan silliq, suyuq yuzalarga ega bo'lgan har xil burama, uzun tomchilarga qadar.[22]

Yuqori viskoziteli magmalar (masalan, riolit, datsit va ba'zi andezitlar) otilishidan hosil bo'lgan kulning morfologiyasi asosan shaklga bog'liq. pufakchalar parchalanishdan oldin ko'tarilgan magmada. Magmatik qavatlanishidan oldin magmatik gazning kengayishi natijasida pufakchalar hosil bo'ladi. Kül zarralari turli darajadagi vesikulyarlikka ega va vesikulyar zarralar sirt nisbati bilan nisbati juda yuqori bo'lishi mumkin.[21] Donli yuzalarda kuzatilgan chuqurchalar, oluklar va naychalar pufak devorlari singanligi natijasidir.[22] Yuqori viskoziteli magma otilishidan kelib chiqadigan vitrik kul zarralari odatda burchakli, pufaksimon pumik bo'laklar yoki yupqa pufakchali devor bo'laklari bo'lib, vulkanik kuldagi litik bo'laklar odatda teng yoki yer ostiga burchakli bo'ladi. Kul tarkibidagi litik morfologiya odatda devor jinslarining mexanik xususiyatlari bilan boshqariladi chayqalish yoki magmaning sirtiga etib borishi bilan gazlarning portlovchi kengayishi.

Freatomagmatik portlashlar natijasida hosil bo'lgan kul zarralarining morfologiyasi sovutilgan magma ichidagi stresslar bilan boshqariladi, natijada shisha mayda blokli yoki piramidal shisha kul zarralarini hosil qiladi.[21] Vezikula shakli va zichligi freatomagmatik portlashlarda don shaklini aniqlashda kichik rol o'ynaydi. Bunday portlashda ko'tarilayotgan magma er osti yoki er usti suvlari bilan aloqada tezda soviydi. "Söndürülmüş" magma ichidagi stresslar dominant piroklast shaklining beshta turiga bo'linishga olib keladi: (1) blokli va teng; (2) pufakchali va tekis yuzalar bilan tartibsiz; (3) moxga o'xshash va o'ralgan; (4) sferik yoki tomchiga o'xshash; va (5) plastinkaga o'xshash.

Zichlik

Ayrim zarrachalarning zichligi har xil otilishlar bilan farq qiladi. Vulkanik kulning zichligi 700–1200 kg / m orasida o'zgarib turadi3 pomza uchun 2350-250 kg / m3 shisha parchalari uchun, 2700-3300 kg / m3 kristallar uchun va 2600-300 kg / m3 litik zarralar uchun.[23] Dag'alroq va zichroq zarralar manbaga yaqin yotqizilganligi sababli, mayda shisha va pomza parchalari distal joylarda joylashgan kul tushadigan qatlamlarda nisbatan boyitilgan.[24] Yuqori zichlik va qattiqlik (~ 5 ga Mohs qattiqligining o'lchovi ) yuqori darajadagi burchakka ega bo'lgan holda, vulkanik kulning ba'zi turlarini (xususan, kremniy tarkibida yuqori bo'lganlarni) juda aşındırıcı holga keltiradi.

Don hajmi

Vulkanik kul donalarining o'lchamlari.

Vulkanik kul diametrlari <2 mm bo'lgan zarrachalardan (piroklastlardan) iborat (zarralar> 2 mm lapilli deb tasniflanadi),[1] va 1 mkmgacha mayda bo'lishi mumkin.[8] Kulning don miqdori bo'yicha taqsimlanishi har xil magma kompozitsiyalari bilan katta farq qilishi mumkin. Depozitning don xususiyatlarini uni hosil qilgan hodisa bilan taqqoslashga ozgina urinishlar qilingan, ammo ba'zi taxminlar qilish mumkin. Riyolitik magmalar, asosan, yopishqoqligi va shuning uchun portlash qobiliyati yuqori bo'lganligi sababli, bazalt magmalarga nisbatan mayda donador material hosil qiladi. Kremniy portlovchi portlashlar uchun mayda kulning nisbati yuqori bo'ladi, ehtimol püskürmeden oldin magmadagi pufakchalarning kattaligi mafik magmalarga qaraganda kichikroq.[1] Piroklastik oqimlar kommunikatsiya yo'li bilan yuqori miqdordagi mayda kul hosil bo'lishining yaxshi dalillari mavjud va ehtimol bu jarayon vulkanik kanallar ichida ham sodir bo'ladi va magma parchalanish yuzasi cho'qqining krateridan ancha past bo'lganida eng samarali bo'ladi.[1]

Tarqoqlik

1990 yil 21 aprelda portlashdan keyin Redubt tog'idan ko'tarilgan kul tuklari.
Qora kulning quyuq shamchasi vulqon konusidan paydo bo'ladi.
Kul shlaklari Klivlend tog'i, a stratovolkan ichida Aleut orollari.

Kül zarralari portlatish ustunlariga kiritiladi, chunki ular shamoldan yuqori tezlikda chiqariladi. Portlashdan dastlabki momentum ustunni yuqoriga ko'taradi. Havo kolonnaga tortilganda massa zichligi pasayadi va atmosferaga ko'tarila boshlaydi.[6] Ustunning massaviy zichligi atrofdagi atmosfera bilan bir xil bo'lgan joyda ustun ko'tarilishini to'xtatadi va yon tomon harakatlana boshlaydi. Yanal dispersiyani ustunlik qiladigan shamollar boshqaradi va kul otilishi ustun balandligi, kul zarralari kattaligi va iqlim sharoitiga (ayniqsa shamol yo'nalishi va kuchi va namligi) qarab, vulkandan yuzlab-minglab kilometr uzoqlikda cho'kishi mumkin.[25]

Kulning tushishi portlashdan so'ng darhol paydo bo'ladi va zarralar zichligi bilan boshqariladi. Dastlab, qo'pol zarralar manbaga yaqin tushadi. Buning ortidan tushish aktsionar lapilli, bu ustun ichidagi zarralar aglomeratsiyasining natijasidir.[26] Ustun shamolga qarab harakatlanayotganda so'nggi bosqichlarda kul tushishi kamroq konsentratsiyalangan. Buning natijasida vulkan masofasi oshgani sayin qalinligi va don hajmi eksponentsial ravishda pasayib ketadigan kul tushadigan kon paydo bo'ladi.[27] Nozik kul zarralari atmosferada bir necha kundan haftagacha saqlanib qolishi va baland balandlikdagi shamollar bilan tarqalishi mumkin. Ushbu zarralar aviatsiya sanoatiga ta'sir qilishi mumkin (ta'sirlar bo'limiga qarang) va gaz zarralari bilan birgalikda global iqlimga ta'sir qilishi mumkin.

Vulkanik kul shamlari piroklastik zichlikdagi oqimlar ustida paydo bo'lishi mumkin, bular ko-ignimbrit plumlari deb ataladi. Piroklastik zichlikdagi oqimlar vulqondan uzoqlashganda, kichikroq zarralar oqimdan chiqarib tashlanadi elutriatsiya va asosiy oqim ustida joylashgan kamroq zich zonani hosil qiladi. Keyinchalik bu zona atrofdagi havoni qamrab oladi va suzuvchi ko-ignimbrit plumasi hosil bo'ladi. Ushbu shlaklar piroklastik zichlik oqimi ichidagi aşınma tufayli magmatik portlash shilimshiqlariga nisbatan mayda kul zarralarining yuqori konsentratsiyasiga ega.[1]

Ta'sir

Kirish

Aholining ko'payishi shaharlarning rivojlanishini tobora xavf ostida bo'lgan hududlarga, vulqon markazlariga yaqinlashishiga olib keldi va odamlarning vulkanik kul hodisalariga ta'sirini oshirdi.

Infratuzilma zamonaviy jamiyatlarni qo'llab-quvvatlash uchun juda muhimdir, ayniqsa shaharlarda, aholining zichligi xizmatlarga katta talab yaratadi. Ushbu infratuzilma tarmoqlari va tizimlari shahar hayotini qo'llab-quvvatlaydi va biz o'zimizga bog'liq bo'lgan hayot xizmatlarini taqdim etadi sog'liq, ta'lim, transport va ijtimoiy tarmoq. Infratuzilma tarmoqlari va xizmatlari turli sohalarda turli xil ob'ektlarni qo'llab-quvvatlaydi.[28]

Vulkanik kulning qulashi hodisalari jamiyat bog'liq bo'lgan infratuzilmani buzishi yoki buzishi mumkin. Yaqinda sodir bo'lgan bir nechta portlashlar zaifligini tasvirlab berdi shahar hududlari atigi bir necha millimetr yoki santimetr vulqon kulini olgan.[29][30][31][32][33][34][35] Bu transportni to'xtatish uchun etarli bo'ldi, elektr energiyasi, suv, kanalizatsiya va bo'ronli suv tizimlar. Xarajatlar biznesni to'xtatish, shikastlangan qismlarni almashtirish va sug'urtalangan zararlardan kelib chiqqan. Muhim infratuzilmaga kul tushishi ta'sirlari, shuningdek, turli xil sohalar va xizmatlarni buzishi mumkin bo'lgan bir nechta ta'sirlarni keltirib chiqarishi mumkin.

Vulqon kulining tushishi jismoniy, ijtimoiy va iqtisodiy jihatdan buziladi. Vulqon kullari proksimal zonalarga ham, manbadan yuzlab kilometr uzoqlikdagi hududlarga ham ta'sir qilishi mumkin va turli xil infratuzilma tarmoqlarida turli xil buzilishlar va yo'qotishlarga olib keladi. Ta'sirlar quyidagilarga bog'liq: kul tushish qalinligi; kulning tushishi davomiyligi; donning kattaligi va kulning kimyosi; kul nam yoki quruq bo'ladimi; va har qanday tayyorlik, boshqaruv va oldini olish (yumshatish) kulning tushishini ta'sirini kamaytirish uchun qo'llaniladigan choralar. Infratuzilma va jamiyatning turli sohalariga turli xil ta'sir ko'rsatmoqda va ta'sir ko'rsatmoqda zaif bir qator ta'sirlarga yoki oqibatlarga. Bular keyingi bo'limlarda muhokama qilinadi.

Infratuzilma sohalari

Elektr

Vulqon vulkanining ifloslanishi natijasida elektr izolyatorining yonishi.

Vulkanik kul elektr energiyasini ishlab chiqarish, o'zgartirish, uzatish va taqsimlashning barcha darajalarida elektr ta'minoti tizimlarida uzilishlarga olib kelishi mumkin. Elektr energiyasini etkazib berish jarayonida ishlatiladigan asboblarning kul bilan ifloslanishidan kelib chiqadigan to'rtta asosiy ta'sir mavjud:[36]

  • Yuqori kuchlanishdagi nam kul qatlamlari izolyatorlar qochqin oqimini boshlashi mumkin (izolyator yuzasida oz miqdordagi oqim oqimi), agar etarli oqimga erishilsa, u "yonib ketishiga" olib kelishi mumkin (izolyatsiya materialining atrofida yoki yuzasida kutilmagan elektr zaryadsizlanishi).

Natijada bo'lsa qisqa tutashuv oqim uchish uchun etarlicha yuqori elektron to'sar shunda xizmatning buzilishi sodir bo'ladi. Transformator yalıtımındaki (vintlardek) kul bilan chaqnash, izolyatsiyani tuzatib bo'lmaydigan darajada kuyishi, yorilishi yoki yorilishi mumkin va elektr ta'minotining uzilishiga olib keladi.

  • Vulkanik kul metall apparatlarni, xususan, suv va shamol turbinalari, shuningdek, transformatorlar yoki issiqlik elektr stantsiyalaridagi sovutish vantilatorlari kabi harakatlanuvchi qismlarni yemirishi, qazishi va tozalashi mumkin.
  • Ba'zi kul yotqiziqlarining katta miqdordagi zichligi chiziqning uzilishiga va kul yuklanishi sababli po'lat minoralar va yog'och ustunlarga zarar etkazishi mumkin. Bu kul va / yoki chiziqlar va inshootlar nam bo'lganida (masalan, yog'ingarchilik paytida) va -10 mm kul tushganda xavfli hisoblanadi. Nozik donali kul (masalan, <0,5 mm diametrli) chiziqlar va tuzilmalarga osonlikcha yopishadi. Vulkanik kul, shuningdek, o'sib chiqadigan o'simliklarga ham yuk tushishi va uning chiziqlarga tushishiga olib kelishi mumkin. Chiziqlardagi qor va muzning to'planib qolishi va o'sib chiqadigan o'simlik qatlamlari va boshqa texnik vositalarning sinishi va qulashi xavfini yanada oshiradi.
  • Zaif ulanish nuqtalarining boshqariladigan uzilishlari (masalan, podstansiyalar ) yoki kul tushguniga qadar sxemalar yoki uskunani kuchsiz tozalash uchun.

Ichimlik suvi ta'minoti

Portlashdan so'ng, suv ta'minotining kimyoviy ifloslanishidan qo'rqadigan jamoatchilik juda keng tarqalgan. Ammo, umuman olganda, qulashning fizik ta'sirlari yangi vulqon kulidan kimyoviy ifloslantiruvchi moddalar chiqarilishi natijasida yuzaga keladigan muammolarni engib chiqishga moyil bo'ladi. Ta'sir davolash tizimining turiga qarab farq qiladi.

Katta suv tozalash inshootlari
Dan suv turbinasi Agoyan Vulkanik kul bilan to'ldirilgan suv bilan yemirilgan gidroelektrostantsiya.

Er osti suvlari bilan oziqlanadigan tizimlar, qulab tushadigan zarbalarga chidamli, garchi havoga chiqadigan kul quduqli nasoslarning ishlashiga xalaqit berishi mumkin. Zaxira hosil bo'lmaganda, qulab tushishi natijasida elektr energiyasining uzilishi elektr bilan ishlaydigan nasoslarni ham buzishi mumkin.

Ko'llar va suv omborlari kabi er usti suv manbalari uchun kuldan yuvilgan ion turlarini suyultirish uchun mavjud bo'lgan hajm odatda katta. Kulli eritmalarning eng ko'p tarkib topgan qismlari (Ca, Na, Mg, K, Cl, F va SO4) tabiiy ravishda aksariyat er usti suvlarida sezilarli kontsentratsiyalarda yuzaga keladi va shuning uchun vulkanik qulashdan kelib chiqadigan moddalar katta ta'sir ko'rsatmaydi va ichimlik suvida kam xavotirga ega, bundan tashqari ftor. Elementlar temir, marganets va alyuminiy odatda vulkanik qulash bilan fon darajasida boyitiladi. Ushbu elementlar suvga metall ta'mini keltirib chiqarishi va oq idishlarni qizil, jigarrang yoki qora ranglarda bo'yashiga olib kelishi mumkin, ammo sog'liq uchun xavfli hisoblanadi. Vulkanik toshqini kabi zaharli mikroelementlar uchun suv ta'minotida muammolarni keltirib chiqargani ma'lum emas simob (Hg) va qo'rg'oshin (Pb), bu kul oqishida juda past darajada bo'ladi.

Shuni ta'kidlash kerak bo'lgan yana bir narsa shundaki, ichimlik suvini tozalash odatda kimyoviy tozalash vositalarini qo'shishni o'z ichiga oladi alyuminiy sulfat yoki temir xlorid kabi flokulyantlar, pH qiymatini sozlash uchun ohak, dezinfektsiya uchun xlor va tish sog'lig'i uchun ftorli birikmalar.

Yiqilishning jismoniy ta'siri suv tozalash inshootlarining ishlashiga ta'sir qilishi mumkin. Ash, qabul qilish inshootlarini to'sib qo'yishi, nasos pervanelerinin aşınmasına jiddiy zarar etkazishi va nasosi motorlarının haddan tashqari yuklanishi mumkin. Ko'pgina suv tozalash inshootlarida dastlabki koagulyatsiya / flokulyatsiya bosqichi mavjud bo'lib, u avtomatik ravishda o'rnatiladi loyqalik (osilgan qattiq moddalar darajasi, o'lchanadi loyqalik birliklari ) keladigan suvda. Ko'pgina hollarda, to'xtatilgan kul zarralari ta'sirida loyqalikdagi o'zgarishlar zavodning normal ishlash doirasiga kiradi va koagulant qo'shilishini sozlash orqali qoniqarli tarzda boshqarilishi mumkin. Ashfalls yuqori loyqalik uchun mo'ljallanmagan va koagulyatsiya / flokulyatsiya bilan davolashni qoldirib yuboradigan o'simliklar uchun muammo tug'dirishi mumkin. Ash to'g'ridan-to'g'ri tushish yo'li bilan va suv olish orqali ochiq qum filtrlari kabi filtrlash tizimlariga kirishi mumkin. Ko'pgina hollarda, qulab tushish oqibatlarini boshqarish uchun texnik xizmatni oshirish talab etiladi, ammo xizmat ko'rsatishda uzilishlar bo'lmaydi.

Ichimlik suvini tozalashning oxirgi bosqichi dezinfektsiya bo'lib, oxirgi ichimlik suvi yuqumli mikroorganizmlardan xoli bo'lishini ta'minlaydi. To'xtatilgan zarralar (loyqalik) mikroorganizmlar uchun o'sish substratini ta'minlashi va ularni dezinfeksiya bilan davolashdan himoya qilishi mumkinligi sababli, suvni tozalash jarayonida to'xtatilgan zarrachalarni olib tashlashning yaxshi darajasiga erishish juda muhimdir.

Kichik tozalash tizimlari

Ko'pgina kichik jamoalar ichimlik suvini turli manbalardan (ko'llar, soylar, buloqlar va er osti quduqlari) oladi. Davolash darajasi qo'pol skrining yoki dezinfeksiya (odatda xlorlash) bilan boshlang'ich tizimlardan tortib filtrlash pog'onasidan foydalangan holda yanada murakkab tizimlarga qadar keng farq qiladi. Xavfsiz er osti suvlari kabi yuqori sifatli manba ishlatilmasa, faqat dezinfektsiya qilish ichimlik suvi protozoa kabi xavfsizligini kafolatlashi mumkin emas. Giardiya va Kriptosporidiy, standart dezinfektsiyalovchi vositalarga nisbatan nisbatan chidamli va filtrlash kabi qo'shimcha olib tashlash bosqichlarini talab qiladi.

Vulkanik qulash ushbu tizimlarga katta ta'sir ko'rsatishi mumkin. Ash suv olish inshootlarini to'sib qo'yadi, nasoslar va blokirovka qilingan quvurlarni ishqalanishiga olib keladi, suv havzalari va ochiq filtrlar. Loyqalikning yuqori darajasi dezinfektsiyani davolashga xalaqit berishi ehtimoldan xoli emas va uning o'rnini qoplash uchun dozalarini o'zgartirish kerak bo'lishi mumkin. Tarqatish tizimidagi xlor qoldiqlarini kuzatib borish juda muhimdir.

Yomg'ir suvi bilan ta'minlanadigan materiallar

Ko'plab uy xo'jaliklari va ayrim kichik jamoalar ichimlik suvi ta'minotida yomg'ir suviga ishonadilar. Uyingizda oziqlanadigan tizimlar kul tushishi bilan ifloslanishiga juda zaifdir, chunki ular saqlash ombori hajmiga nisbatan katta sirt maydoniga ega. Bunday hollarda, kimyoviy ifloslantiruvchi moddalarni kuldan tozalash sog'liq uchun xavf tug'dirishi mumkin va suv ichish tavsiya etilmaydi. Yiqilishdan oldin tankdagi suv himoyalangan bo'lishi uchun truboprovodlarni ajratib qo'yish kerak. Yana bir muammo shundaki, yangi vulkanik kulning sirt qoplamasi kislotali bo'lishi mumkin. Ko'pgina er usti suvlaridan farqli o'laroq, yomg'ir suvlari odatda juda kam gidroksidi (kislota neytrallash qobiliyati) ga ega va shuning uchun kul tushishi tank suvlarini kislotalashi mumkin. Bu bilan bog'liq muammolarga olib kelishi mumkin plumbosolventsiya, shu bilan suv u bilan aloqa qiladigan materiallarga nisbatan ko'proq tajovuzkor bo'ladi. Uyingizda qo'rg'oshin tirnoqlari yoki qo'rg'oshin miltillovchi joylari, mis quvurlari va boshqa metall sanitariya-tesisat buyumlari uchun ishlatilsa, bu alohida muammo bo'lishi mumkin.

Suvga talab

Oqish hodisalari paytida suvni tozalash uchun odatda katta talablar qo'yiladi va etishmovchilik paydo bo'lishi mumkin. Kamchiliklar yong'inni o'chirish kabi asosiy xizmatlarga zarar etkazadi va gigiena, sanitariya va ichimlik suvi etishmasligiga olib kelishi mumkin. Shahar hokimiyati ushbu suv talabini sinchkovlik bilan kuzatishi va boshqarishi kerak va jamoatchilikka suv ishlatmaydigan tozalash usullaridan foydalanishni maslahat berishi kerak (masalan, shlanglar bilan emas, balki supurgi bilan tozalash).

Atıksu tozalash

Chiqindi suv tarmoqlari suv ta'minoti tarmoqlariga o'xshash zarar etkazishi mumkin. Kanalizatsiya tizimidan kulni chiqarib tashlash juda qiyin. Yomg'ir suvi / kanalizatsiya tarmoqlarini birlashtirgan tizimlar xavf ostida. Ash kanalizatsiya liniyalariga noqonuniy ulanishlar (masalan, tomning pastki trubalaridan), o'zaro bog'liqlik, kanalizatsiya quvurlari teshiklari va yoriqlari orqali yomg'ir suvi bilan oqim / infiltratsiya mavjud bo'lgan joylarga kiradi.

Tozalash inshootlariga kiradigan kul bilan to'ldirilgan kanalizatsiya pog'onali ekranlar yoki aylanuvchi ekranlar kabi mexanik oldindan tozalash uskunalarining ishdan chiqishiga olib kelishi mumkin. Tizimga ko'proq kirib boradigan kul cho'kadi va biologik reaktorlarning quvvatini pasaytiradi, shuningdek loy hajmini oshiradi va uning tarkibini o'zgartiradi.

Samolyot

Asosiy maqola: Vulkanik kul va aviatsiya xavfsizligi

Vulqonli kul bulutiga uchayotgan samolyotlarning asosiy zarari oldinga qaragan yuzalar, masalan, old oyna va qanotlarning etakchi qirralari bilan ishqalanish va kulning sirt teshiklarida, shu jumladan dvigatellarda to'planishi. Shisha va qo'nish chiroqlarini aşınması ko'rinishni kamaytiradi, uchuvchilarni asboblariga ishonishga majbur qiladi. Biroq, ba'zi asboblar datchik sifatida noto'g'ri o'qishni ta'minlashi mumkin (masalan, pitot naychalari ) kul bilan to'sib qo'yilishi mumkin. Dvigatellarga kulni yutish kompressor fanatlarining pichoqlarini aşınmasına olib keladi. Kul kompressorda o'tkir pichoqlarni emiradi va uning samaradorligini pasaytiradi. Kul yonish kamerasida eriydi va eritilgan oynani hosil qiladi. Keyin kul turbinalar pichoqlarida qotib qoladi va havo oqimini to'sib qo'yadi va dvigatel to'xtab qoladi.

Ko'p kulning tarkibi shuki, uning erish harorati ish harorati (> 1000 ° C) zamonaviy katta reaktiv dvigatellar.[37] Ta'sir darajasi plumdagi kul kontsentratsiyasiga, samolyot shlyuz ichida qancha vaqt o'tkazganiga va uchuvchilar tomonidan qilingan harakatlarga bog'liq. Kritik ravishda, kulning, xususan, vulqon shishasining erishi, turbinali shtutserning yo'naltiruvchi qanotlarida rezolyutsiyalangan kul to'planib qolishiga olib kelishi mumkin. kompressor rastasi va dvigatel kuchini to'liq yo'qotish.[38] Mumkin bo'lgan to'xtash joyini aniqlaganda, dvigatelni boshqarish tizimining standart protsedurasi bu muammoni yanada kuchaytiradigan quvvatni oshirishdir. Uchuvchilarga dvigatel kuchini kamaytirish va 180 ° pastga burilish orqali bulutdan tezda chiqib ketish tavsiya etiladi.[38] Kul bulutlari tarkibida bo'lgan vulkanik gazlar dvigatellarga va akril oynalarga ham zarar etkazishi mumkin, ammo bu zarar ko'p yillar davomida yuzaga chiqmasligi mumkin.

Hodisa

Kul bilan to'qnashuv natijasida reaktiv samolyotlarga zarar etkazish hollari ko'p. 1982 yil 24 iyunda a British Airways Boeing 747-236B (9-reys ) otilishi natijasida kul buluti orqali uchib o'tdi Galunggung tog'i, Indoneziya natijada barcha to'rt dvigatelning ishdan chiqishi. Dvigatellar qayta ishga tushgunga qadar samolyot 16 daqiqada 2400 fut (7300 m) pastga tushdi va samolyot favqulodda qo'nishga imkon berdi. 1989 yil 15-dekabrda a KLM Boeing 747-400 (867-reys ) shuningdek, kul bulutiga uchib ketganidan keyin to'rtta dvigatelning kuchini yo'qotdi Redubt tog'i, Alyaska. To'rt daqiqada 1400 metr (4500 m) pastga tushgandan so'ng, dvigatellar zarbadan 1-2 daqiqa oldin ishga tushirildi. Umumiy zarar 80 million AQSh dollarini tashkil etdi va samolyotni ta'mirlash uchun 3 oylik ish olib borildi.[37] 1990-yillarda 1991 yildagi portlash natijasida tijorat samolyotlari (ba'zilari havoda, boshqalari yerda) tomonidan 100 million AQSh dollarlik zarar ko'rdi. Pinatubo tog'i ichida Filippinlar.[37]

2010 yil aprel oyida, havo maydoni Hamma joyda Evropa ta'sir ko'rsatdi, ko'plab reyslar bekor qilindi - bu misli ko'rilmagan edi - atmosferaning yuqori qismida vulkanik kul borligi sababli Islandiyaning Eyjafjallajökull vulqoni otilishi.[39] 2010 yil 15 aprelda Finlyandiya havo kuchlari Boeing-dan biri dvigatellari tomonidan vulkanik changni yutishi natijasida zarar aniqlanganda o'quv reyslari to'xtatildi F-18 hornet jangchilar.[40] 2010 yil 22 aprelda, Buyuk Britaniya RAF Tayfun reaktiv dvigatellarida vulkanik kul konlari topilganidan keyin o'quv reyslari ham vaqtincha to'xtatildi.[41] 2011 yil iyun oyida Chili, Argentina, Braziliya, Avstraliya va Yangi Zelandiyada havo maydonlarining yopilishi sodir bo'lgan. Puyehue-Kordon Koll, Chili.

Aniqlash
Dunyo bo'ylab to'qqizta VAACni qamrab olish
AIRBUS A340 sinov samolyotining fyuzelyajiga o'rnatilgan AVOID vositasi.

Vulkanik kul bulutlarini samolyotdan aniqlash juda qiyin, chunki ularni aniqlash uchun samolyotda kokpit asboblari mavjud emas. Ammo yaqinda doktor Fred Prata tomonidan Havodagi vulkanik ob'ekt infraqizil detektori (AVOID) deb nomlangan yangi tizim ishlab chiqildi[42] CSIRO Avstraliyada ishlayotganda[43] va Norvegiya Havo tadqiqotlari instituti Bu uchuvchilarga 60 km (37 milya) gacha bo'lgan kul uchqunlarini aniqlash va ular atrofida xavfsiz uchish imkonini beradi.[44] Tizimda vulkanik kulni aniqlash uchun sozlangan, oldinga qaragan yuzaga o'rnatilgan ikkita tezkor namuna oladigan infraqizil kameralar ishlatiladi. Ushbu tizim <1 mg / m kul kontsentratsiyasini aniqlay oladi3 > 50 mg / m gacha3, uchuvchilarga taxminan 7-10 daqiqa ogohlantirish berish.[44] Kamera sinovdan o'tkazildi[45][46] tomonidan easyJet aviakompaniya,[47] AIRBUS va Nicarnica Aviation (doktor Fred Prata hammuallifi). Natijalar tizimning ~ 60 km va 10000 futgacha bo'lgan masofada ishlashini ko'rsatdi [48] ammo ba'zi bir muhim o'zgartirishlarsiz undan yuqori emas.

Bundan tashqari, er usti va sun'iy yo'ldoshga asoslangan tasvirlar, radar va lidar kul bulutlarini aniqlash uchun ishlatilishi mumkin. Ushbu ma'lumotlar meteorologik idoralar, vulqon rasadxonalari va aviakompaniyalar o'rtasida uzatiladi Vulqonli kulga oid maslahat markazlari (VAAC). Dunyoning to'qqiz mintaqasining har biri uchun bitta VAAC mavjud. VAAClar kul bulutining hozirgi va kelajakdagi hajmini tavsiflovchi tavsiyalar berishi mumkin.

Aeroport tizimlari

Vulkanik kul nafaqat parvoz paytida, balki aeroportdagi quruqlikdagi ishlarga ham ta'sir qilishi mumkin. Kichik miqdordagi kul birikmasi ko'rinishni pasaytirishi, silliq uchish-qo'nish yo'laklari va avtoulov yo'llarini yaratishi, aloqa va elektr tizimlariga kirib borishi, er xizmatlarini to'xtatishi, binolar va to'xtab turgan samolyotlarga zarar etkazishi mumkin.[49] Bir necha millimetrdan ko'proq kul to'planishi aeroportlar to'liq ish boshlashi uchun olib tashlashni talab qiladi. Ash yo'q bo'lib ketmaydi (qor yog'ishidan farqli o'laroq) va uni shamol va samolyotlar yordamida qayta tiklashga imkon bermaydigan tarzda yo'q qilish kerak.

Yer transporti

Ash katta maydonlarda transport tizimlarini, shu jumladan avtomobil yo'llari va transport vositalari, temir yo'llar va portlar va yuk tashishni buzishi mumkin. Yiqilgan kul haydashni qiyinlashtiradigan va xavfli qiladigan ko'rinishni pasaytiradi.[23] Bundan tashqari, tez yuradigan avtoulovlar kulni qo'zg'atadi va bulutlarni yaratadi, bu esa doimiy ko'rinishga xavf tug'diradi. Kul birikmalari tortishni kamaytiradi, ayniqsa nam bo'lsa va yo'l belgilarini qoplaydi.[23] Yupqa donli kullar avtoulovlarning teshiklariga singib ketishi va aksariyat sirtlarni, ayniqsa, harakatlanuvchi qismlar orasida silliqlashi mumkin. Havo va yog 'filtrlari tez-tez almashtirishni talab qiladigan bloklanadi. Temir yo'l transporti kam himoyaga ega, buzilishlar asosan ko'rinishni pasayishi bilan bog'liq.[23]

Dengiz transportiga vulkanik kul ham ta'sir qilishi mumkin. Kulning tushishi havo va yog 'filtrlarini to'sib qo'yadi va dvigatellarga singdirilsa, harakatlanuvchi qismlarni maydalaydi. Navigatsiyaga kul tushishi paytida ko'rinishni pasayishi ta'sir qiladi. Vesikulyatsiyalangan kul (pomza va skoriya ) suv olish joylarini tezda to'sib qo'yishi mumkin bo'lgan "pomza raftlarida" suv sathida suzib yuradi, bu esa uskunani haddan tashqari qizib ketishiga olib keladi.[23]

Aloqa

Telekommunikatsiya va translyatsiya tarmoqlarga vulkanik kul quyidagi ta'sir ko'rsatishi mumkin: susayish va signal kuchini pasaytirish; uskunaning shikastlanishi; va foydalanuvchining talabiga binoan tarmoqni ortiqcha yuklash. Vulkanik kul tufayli signal susayishi yaxshi hujjatlashtirilmagan; ammo, 1969 yildan keyin aloqa uzilib qolganligi haqida xabarlar mavjud Surtsi otilishi va 1991 yil Pinatubo tog'ining otilishi. Tomonidan olib borilgan tadqiqotlar Yangi Zelandiya -based Auckland Engineering Lifelines Group determined theoretically that impacts on telecommunications signals from ash would be limited to past chastota services such as sun'iy yo'ldosh aloqasi.[34] Signal interference may also be caused by lightning, as this is frequently generated within volcanic eruption plumes.[50]

Telecommunication equipment may become damaged due to direct ash fall. Most modern equipment requires constant cooling from air conditioning units. These are susceptible to blockage by ash which reduces their cooling efficiency.[51] Heavy ash falls may cause telecommunication lines, masts, cables, aerials, antennae dishes and towers to collapse due to ash loading. Moist ash may also cause accelerated corrosion of metal components.[34]

Reports from recent eruptions suggest that the largest disruption to communication networks is overloading due to high user demand.[23] This is common of many natural disasters.

Kompyuterlar

Kompyuterlar may be impacted by volcanic ash, with their functionality and usability decreasing during ashfall, but it is unlikely they will completely fail.[52] The most vulnerable components are the mechanical components, such as cooling fans, cd drives, klaviatura, sichqonlar va touch pads. These components can become jammed with fine grained ash causing them to cease working; however, most can be restored to working order by cleaning with compressed air. Moist ash may cause electrical short circuits within desktop computers; however, will not affect laptop computers.[52]

Binolar va inshootlar

Damage to buildings and structures can range from complete or partial roof collapse to less catastrophic damage of exterior and internal materials. Impacts depend on the thickness of ash, whether it is wet or dry, the roof and building design and how much ash gets inside a building. The specific weight of ash can vary significantly and rain can increase this by 50–100%.[8] Problems associated with ash loading are similar to that of snow; however, ash is more severe as 1) the load from ash is generally much greater, 2) ash does not melt and 3) ash can clog and damage gutters, especially after rain fall. Impacts for ash loading depend on building design and construction, including roof slope, construction materials, roof span and support system, and age and maintenance of the building.[8] Generally flat roofs are more susceptible to damage and collapse than steeply pitched roofs. Roofs made of smooth materials (sheet metal or glass) are more likely to shed ash than roofs made with rough materials (thatch, asphalt or wood shingles). Roof collapse can lead to widespread injuries and deaths and property damage. For example, the collapse of roofs from ash during the 15 June 1991 Mount Pinatubo eruption killed about 300 people.[53]

Human and animal health

Ash particles of less than 10 µm diameter suspended in the air are known to be inhalable, and people exposed to ash falls have experienced respiratory discomfort, breathing difficulty, eye and skin irritation, and nose and throat symptoms.[54] Most of these effects are short-term and are not considered to pose a significant health risk to those without pre-existing nafas olish sharoitlari.[55] The health effects of volcanic ash depend on the grain size, mineralogical composition and chemical coatings on the surface of the ash particles.[55] Additional factors related to potential respiratory symptoms are the frequency and duration of exposure, the concentration of ash in the air and the respirable ash fraction; the proportion of ash with less than 10 µm diameter, known as Bosh vazir10. The social context may also be important.

Chronic health effects from volcanic ash fall are possible, as exposure to free crystalline silica is known to cause silikoz. Minerals associated with this include kvarts, kristobalit va tridymite, which may all be present in volcanic ash. These minerals are described as ‘free’ silica as the SiO2 is not attached to another element to create a new mineral. However, magmas containing less than 58% SiO2 are thought to be unlikely to contain crystalline silica.[55]

The exposure levels to free crystalline silica in the ash are commonly used to characterise the risk of silicosis in occupational studies (for people who work in mining, construction and other industries,) because it is classified as a human kanserogen tomonidan Xalqaro saraton tadqiqotlari agentligi. Guideline values have been created for exposure, but with unclear rationale; UK guidelines for particulates in air (PM10) are 50 µg/m3 and USA guidelines for exposure to crystalline silica are 50 µg/m3.[55] It is thought that the guidelines on exposure levels could be exceeded for short periods of time without significant health effects on the general population.[54]

There have been no documented cases of silicosis developed from exposure to volcanic ash. However, long-term studies necessary to evaluate these effects are lacking.[55]

Ingesting ash

Ingesting ash may be harmful to chorva mollari, causing abrasion of the teeth, and in cases of high ftor content, fluorine poisoning (toxic at levels of >100 µg/g) for grazing animals.[56] Bu ma'lum 1783 eruption of Laki in Iceland that fluorine poisoning occurred in humans and livestock as a result of the chemistry of the ash and gas, which contained high levels of Hydrogen Fluoride. Keyingi 1995/96 Mount Ruapehu eruptions in New Zealand, two thousand ewes and lambs died after being affected by fluorosis while grazing on land with only 1–3 mm of ash fall.[56] Symptoms of flourorsis among cattle exposed to ash include brown-yellow to green-black mottles in the teeth, and hypersensibility to pressure in the legs and back.[57] Ash ingestion may also cause gastrointestinal blockages.[34] Sheep that ingested ash from the 1991 Hudson tog'i volcanic eruption in Chile, suffered from diarrhoea and weakness.

Other effects on livestock

Ash accumulating in the back jun of sheep may add significant weight, leading to fatigue and sheep that can not stand up. Rainfall may result in a significant burden as it adds weight to ash.[58] Pieces of wool may fall away and any remaining wool on sheep may be worthless as poor nutrition associated with volcanic eruptions impacts the quality of the fibre.[58] As the usual pastures and plants become covered in volcanic ash during eruption some livestock may resort to eat whatever is available including toxic plants.[59] There are reports of goats and sheep in Chile and Argentina having natural abortions in connection to volcanic eruptions.[60]

Environment and agriculture

Volcanic ash can have a detrimental impact on the environment which can be difficult to predict due to the large variety of environmental conditions that exist within the ash fall zone. Natural waterways can be impacted in the same way as urban water supply networks. Ash will increase water turbidity which can reduce the amount of light reaching lower depths, which can inhibit growth of submerged suv o'simliklari and consequently affect species which are dependent on them such as baliq va qisqichbaqalar. High turbidity can also affect the ability of baliq gillalari singdirmoq erigan kislorod. Acidification will also occur, which will reduce the pH of the water and impact the fauna and flora living in the environment. Fluoride contamination will occur if the ash contains high concentrations of fluoride.

Ash accumulation will also affect pasture, plants and trees which are part of the bog'dorchilik va qishloq xo'jaligi sanoat tarmoqlari. Thin ash falls (<20 mm) may put livestock off eating, and can inhibit transpiratsiya va fotosintez and alter growth. There may be an increase in pasture production due to a mulching effect and slight fertilizing effect, such as occurred following the 1980 Mount St. Helens and 1995/96 Mt Ruapehu eruptions.[61][62] Heavier falls will completely bury pastures and soil leading to death of pasture and sterilization of the soil due to oxygen deprivation. Plant survival is dependent on ash thickness, ash chemistry, compaction of ash, amount of rainfall, duration of burial and the length of plant stalks at the time of ash fall.[8] The acidic nature of ash will lead to elevated soil sulfur levels and lowered soil pH, which can reduce the availability of essential minerals and alter the soil's characteristics so that crops and plants will not survive. Ash will also impact upon haydaladigan crops, such as fruit, vegetables and grain. Ash can burn plant and crop tissue reducing quality, contaminate crops during harvest and damage plants from ash loading.

Young forests (trees <2 years old) are most at risk from ash falls and are likely to be destroyed by ash deposits >100 mm.[63] Ash fall is unlikely to kill mature trees, but ash loading may break large branches during heavy ash falls (>500 mm). Defoliation of trees may also occur, especially if there is a coarse ash component within the ash fall.[8]

Land rehabilitation after ash fall may be possible depending on the ash deposit thickness. Rehabilitation treatment may include: direct seeding of deposit; mixing of deposit with buried soil; scraping of ash deposit from land surface; and application of new topsoil over the ash deposit.[34]

Interdependence

Interdependency of volcanic ashfall impacts from the Eyjafjallajökull 2010 eruptions.

Critical infrastructure and infrastructure services are vital to the functionality of modern society, to provide: medical care, policing, favqulodda xizmatlar, and lifelines such as water, wastewater, and power and transportation links. Often critical facilities themselves are dependent on such lifelines for operability, which makes them vulnerable to both direct impacts from a hazard event and indirect effects from lifeline disruption.[64]

The impacts on lifelines may also be inter-dependent. The vulnerability of each lifeline may depend on: the type of hazard, the spatial density of its critical linkages, the dependency on critical linkages, susceptibility to damage and speed of service restoration, state of repair or age, and institutional characteristics or ownership.[28]

The 2010 eruption of Eyjafjallajokull in Iceland highlighted the impacts of volcanic ash fall in modern society and our dependence on the functionality of infrastructure services. During this event, the airline industry suffered business interruption losses of €1.5–2.5 billion from the closure of European airspace for six days in April 2010 and subsequent closures into May 2010.[65] Ash fall from this event is also known to have caused local crop losses in agricultural industries, losses in the tourism industry, destruction of roads and bridges in Iceland (in combination with glacial melt water), and costs associated with emergency response and clean-up. However, across Europe there were further losses associated with travel disruption, the insurance industry, the postal service, and imports and exports across Europe and worldwide. These consequences demonstrate the interdependency and diversity of impacts from a single event.[35]

Preparedness, mitigation and management

Qizil ko'ylak kiygan, supurayotgan odam
Shlangi ushlagan va vulqon kulini suv bilan sepayotgan odam
Two management methods during the 2014 eruptions of Kelud: sweeping (top) and spraying with water (bottom)

Preparedness for ashfalls should involve sealing buildings, protecting infrastructure and homes, and storing sufficient supplies of food and water to last until the ash fall is over and clean-up can begin. Chang maskalari can be worn to reduce inhalation of ash and mitigate against any respiratory health affects.[54] Goggles can be worn to protect against eye irritation.

The International Volcanic Ashfall Impacts Working Group ning IAVCEI maintains a regularly updated database of impacts and mitigations strategies.

At home, staying informed about volcanic activity, and having contingency plans in place for alternative shelter locations, constitutes good preparedness for an ash fall event. This can prevent some impacts associated with ash fall, reduce the effects, and increase the human capacity to cope with such events. A few items such as a flashlight, plastic sheeting to protect electronic equipment from ash ingress, and battery operated radios, are extremely useful during ash fall events.[8]

The protection of infrastructure must also be considered within emergency preparedness. Critical facilities that need to remain operable should be identified, and all others should be shut down to reduce damage. It is also important to keep ash out of buildings, machinery and lifeline networks (in particular water and wastewater systems,) to prevent some of the damage caused by ash particles. Windows and doors should be closed and shuttered if possible, to prevent ingress of ash into buildings.

Communication plans should be made beforehand to inform of mitigation actions being undertaken. Spare parts and back-up systems should be in place prior to ash fall events to reduce service disruption and return functionality as quickly as possible. Good preparedness also includes the identification of ash disposal sites, before ash fall occurs, to avoid further movement of ash and to aid clean-up.[66] Himoya vositalari such as eye protection and dust masks should be deployed for clean-up teams in advance of ash fall events.

Some effective techniques for the management of ash have been developed including cleaning methods and cleaning apparatus, and actions to mitigate or limit damage. The latter include covering of openings such as: air and water intakes, aircraft engines and windows during ash fall events. Roads may be closed to allow clean-up of ash falls, or speed restrictions may be put in place, in order to prevent motorists from developing motor problems and becoming stranded following an ash fall.[67] To prevent further effects on underground water systems or waste water networks, drains and culverts should be unblocked and ash prevented from entering the system.[66] Ash can be moistened (but not saturated) by sprinkling with water, to prevent remobilisation of ash and to aid clean-up.[67] Prioritisation of clean-up operations for critical facilities and coordination of clean-up efforts also constitute good management practice.[66][67][68]

It is recommended to evacuate livestock in areas where ashfall may reach 5 cm or more.[69]

Volcanic ash soils

Volcanic ash's primary use is that of a soil enricher. Once the minerals in ash are washed into the soil by rain or other natural processes, it mixes with the soil to create an andisol qatlam. This layer is highly rich in nutrients and is very good for agricultural use; the presence of lush forests on volcanic islands is often as a result of trees growing and flourishing in the fosfor va azot -rich andisol.[70] Volcanic ash can also be used as a replacement for sand.[71]

Shuningdek qarang

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Bibliografiya

  • Araya Valenzuela, Oscar (2015). Erupciones volcánicas: Efectos sobre la ganadería. Collección Austral Universitaria de Ciencias Silvoagropecuarias (in Spanish). Ediciones UACh. ISBN  978-956-9412-20-2.

Tashqi havolalar