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Day 83 – Q 2. How is volcanic eruption responsible for developing various landforms? Illustrate with the help of suitable examples.

2. How is volcanic eruption responsible for developing various landforms? Illustrate with the help of suitable examples. 

ज्वालामुखी विस्फोट विभिन्न लैंडफॉर्म के विकास के लिए कैसे जिम्मेदार है? उपयुक्त उदाहरणों की सहायता से चित्रण करें।

Introduction:

Volcano is a rupture in the crust of a planetary-mass object, such as Earth, that allows hot lava, volcanic ash, and gases to escape from a magma chamber below the surface. The process is called Volcanism and has been ongoing on Earth since the initial stages of its evolution over 4 billion years ago.

Body

Volcanic landforms are divided into extrusive and intrusive landforms based on weather magma cools within the crust or above the crust. Rocks formed by either plutonic (cooling of magma within the crust) or volcanic (cooling of lava above the surface) are called ‘Igneous rocks’.

Extrusive Volcanic Landforms These are formed from material thrown out during volcanic activity. The materials thrown out during volcanic activity includes lava flows, pyroclastic debris, volcanic bombs, ash and dust and gases such as nitrogen compounds, sulphur compounds and minor amounts of chlorine, hydrogen and argon.

Various landforms associated with volcanic activities

    • Conical Vent and Fissure Vent
      • A conical vent is a narrow cylindrical vent through which magma flows out violently. Conical vents are common in andesitic (composite or strato volcano) volcanism.

  • Composite Cones or Strato volcanoes

  • They are conical or central type volcanic landforms.
  • Along with andesitic lava, large quantities of pyroclastic material and ashes find their way to the ground.
  • They are accumulated in the vicinity of the vent openings leading to formation of layers, and this makes the mounts appear as composite volcanoes.
  • Example: Vesuvius, Mt. Fuji, Stromboli (Lighthouse of the Mediterranean) etc.

  • Shield Volcanoes or Lava domes

    • These volcanoes are mostly made up of basalt, a type of lava that is very fluid when erupted. They are not steep.
    • They become explosive if somehow water gets into the vent; otherwise, they are less explosive.
    • Example: Mauna Loa (Hawaii).

  • Lava Plains and Basalt Plateaus

      • Sometimes, a very thin magma escapes through cracks and fissures in the earth’s surface and flows after intervals for a long time, spreading over a vast area, finally producing a layered, undulating (wave like), flat surface.
      • Example: Deccan traps (peninsular India), Snake Basin, U.S.A, Icelandic Shield, Canadian Shield etc.
    • Cinder cone (Tephra cones)
      • Cinder cones are small volume cones consisting predominantly of tephra that result from strombolian eruptions.
      • They usually consist of basaltic to andesitic material.

  • Calderas

      • After the eruption of magma has ceased from the cones, the crater frequently turns into a lake at a later time.
      • Water may collect in the crater. This lake is called a ‘caldera’.
      • Example: Lake Toba in Sumatra, Crater Lake in Oregon, USA.

  • Mid-Ocean Ridges

    • These volcanoes occur in the oceanic areas. There is a system of mid-ocean ridges more than 70,000 km long that stretches through all the ocean basins. The central portion of this ridge experiences frequent eruptions.
    • The lava is basaltic in nature.
    • Cools slowly and flows through longer distances.
    • The lava here is responsible for sea floor spreading.
    • Example: Mid-Atlantic ocean ridge; extension is seen in the Iceland.

Intrusive Volcanic Landforms: Intrusive landforms are formed when magma cools within the crust. The intrusive activity of volcanoes gives rise to various forms.

Batholiths

  • These are huge mass of igneous rocks, usually of granite.
  • These rock masses formed due to cooling down and solidification of hot magma inside the earth.
  • They appear on the surface only after the denudation processes remove the overlying materials and may be exposed on surface after erosion.
  • Example: Wicklow mountains of Ireland; the uplands of Brittany, France.

Laccoliths

  • These are large dome-shaped intrusive bodies connected by a pipe-like conduit from below.
  • These are basically intrusive counterparts of an exposed domelike batholith.
  • Example: The laccoliths of Henry mountains in the Utah, USA.
TLP Phase 1 – Day 83 Synopsis

TLP Phase 1 – Day 83 Synopsis

Lopolith

  • As and when the lava moves upwards, a portion of the same may tend to move in a horizontal direction wherever it finds a weak plane.
  • In case it develops into a saucer shape, concave to the sky body, it is called Lopolith.
  • Example: The Bushveld lopolith of Transvaal, South Africa.

Phacolith

  • A wavy mass of intrusive rocks, at times, is found at the base of synclines or at the top of anticline in folded igneous country.
  • Such wavy materials have a definite conduit to source beneath in the form of magma chambers (subsequently developed as batholiths). These are called the Phacoliths.
  • Example: Corndon hill in Shropshire, England.

Sills

  • These are solidified horizontal lava layers inside the earth.
  • The near horizontal bodies of the intrusive igneous rocks are called sill or sheet, depending on the thickness of the material.
  • The thinner ones are called sheets while the thick horizontal deposits are called sills.
  • Example: Great whin sill of NE England

Dykes

  • When the lava makes its way through cracks and the fissures developed in the land, it solidifies almost perpendicular to the ground.
  • It gets cooled in the same position to develop a wall-like structure. Such structures are called dykes.
  • These are the most commonly found intrusive forms in the western Maharashtra area. These are considered the feeders for the eruptions that led to the development of the Deccan traps. Cleveland Dyke of Yorkshire, England.

Conclusion

Volcanic activities have a profound influence on earth’s landforms. Solid, liquid or gaseous materials may find their way to the surface from some deep-seated reservoir beneath.

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