Answer the question in maximum 200 words. This question carries 11 marks. [MPPSC 2023] Describe the mountain classification based on geomorphological features.
Composition of the Upper Continental Crust Introduction The upper continental crust is a fundamental component of Earth's lithosphere and plays a crucial role in geology, including tectonics, resource distribution, and the study of Earth's history. Its composition is distinct from the oceanic crustRead more
Composition of the Upper Continental Crust
Introduction The upper continental crust is a fundamental component of Earth’s lithosphere and plays a crucial role in geology, including tectonics, resource distribution, and the study of Earth’s history. Its composition is distinct from the oceanic crust and varies significantly in different geological settings.
Basic Composition The upper continental crust is primarily composed of silicic (felsic) rocks, which include the following key components:
- Granite: Granite is one of the most common rocks found in the upper continental crust. It is a coarse-grained igneous rock primarily composed of quartz, feldspar, and mica. Granitic rocks are prevalent in continental shields and mountain ranges. For example, the Sierra Nevada Mountains in the United States are predominantly granitic.
- Sedimentary Rocks: The upper continental crust also includes a variety of sedimentary rocks, such as:
- Sandstone: Composed mainly of quartz grains, sandstone is commonly found in sedimentary basins. The Grand Canyon in the U.S. showcases significant sandstone layers.
- Shale: A fine-grained sedimentary rock formed from clay and silt, shale is prevalent in various sedimentary environments. Benton Shale in the U.S. is a notable example.
- Limestone: Formed from calcium carbonate, limestone is significant in regions with marine influences. The Karst landscape in China is famous for its limestone formations.
- Metamorphic Rocks: These are formed from the alteration of pre-existing rocks under pressure and temperature. Common metamorphic rocks in the upper continental crust include:
- Gneiss: A high-grade metamorphic rock with a banded structure, often derived from granite. The Adirondack Mountains in New York are known for their gneissic formations.
- Schist: Characterized by its schistosity or layering, schist is commonly found in orogenic belts. The Scottish Highlands contain significant schist deposits.
Recent Examples and Developments
- Himalayan Orogeny: The ongoing Himalayan mountain-building process provides insight into the upper continental crust’s composition and structure. The collision between the Indian Plate and the Eurasian Plate has resulted in extensive granitic and metamorphic rock formations in the Himalayas.
- Geological Surveys and Resource Exploration: Modern geological surveys, such as those conducted by the Geological Survey of India (GSI), have mapped various rock types in the Indian subcontinent, revealing diverse compositions of the upper continental crust across different regions.
- Continental Drilling Projects: Projects like the International Continental Scientific Drilling Program (ICDP) aim to drill into the continental crust to study its composition and structure. These projects have provided valuable data on the distribution of granite, metamorphic rocks, and sedimentary layers.
- Urban Development and Mining: Understanding the composition of the upper continental crust is crucial for urban planning and resource extraction. For instance, the extraction of granite for construction purposes and the exploration of sedimentary basins for fossil fuels are directly related to the crust’s composition.
Conclusion The upper continental crust is predominantly composed of granitic, sedimentary, and metamorphic rocks, reflecting its complex geological history and varying environmental conditions. Recent geological studies and projects continue to enhance our understanding of its composition, contributing to fields such as resource management, tectonics, and environmental science. The diverse composition of the upper continental crust underscores its significance in both scientific research and practical applications.
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Classification of Mountains Based on Geomorphological Characteristics Mountains are significant landforms that can be classified based on their geomorphological characteristics, which pertain to their origin, structure, and formation processes. Here’s a detailed classification along with recent examRead more
Classification of Mountains Based on Geomorphological Characteristics
Mountains are significant landforms that can be classified based on their geomorphological characteristics, which pertain to their origin, structure, and formation processes. Here’s a detailed classification along with recent examples:
1. Fold Mountains:
Definition: Fold mountains are formed primarily by the collision of tectonic plates, which causes the Earth’s crust to fold. These mountains are characterized by complex structures with numerous folds, including anticlines (upward folds) and synclines (downward folds).
Examples:
2. Block Mountains:
Definition: Block mountains, also known as fault-block mountains, are created by tectonic forces that cause the Earth’s crust to fracture into blocks. These blocks are then uplifted or down-dropped relative to each other along faults.
Examples:
3. Volcanic Mountains:
Definition: Volcanic mountains are formed by volcanic activity where magma from the Earth’s mantle erupts through the crust, creating cones or domes of volcanic material.
Examples:
4. Residual Mountains:
Definition: Residual mountains, also known as denudation mountains, are formed through the process of erosion. They are typically old mountains that have been worn down over time, leaving behind remnants of their original structure.
Examples:
5. Dome Mountains:
Definition: Dome mountains are formed when magma pushes the Earth’s crust upwards without erupting. The uplifted rock forms a dome shape, which may later be eroded to expose the underlying structure.
Examples:
Conclusion
The classification of mountains based on geomorphological characteristics provides insight into their formation processes and structural features. Recent geological activities and studies in regions like the Himalayas, Sierra Nevada, and Kilauea enhance our understanding of these diverse mountain types.
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