Intrusive Igneous Rocks
The intrusive rock is also known as plutonic rock. Intrusive rock is also an igneous rock like granite or diorite. When the igneous rock formed from magma is forced down into the older rocks at the depth of the Earth’s surface which then slowly solidifies below the surface of the Earth, it forms intrusive igneous rocks. The intrusive igneous rocks are exposed later on due to processes of erosion. There are many types of intrusive igneous rocks. Examples of intrusive igneous rocks include granites, dikes, sills, etc.
Formation of Intrusive Rock
The intrusive rock definition clearly states the process of formation of the intrusive rock. The intrusive igneous rock definition tells us that when the magma penetrates some of the existing rock structures, it crystallizes and solidifies below the surface to form intrusions and hence the intrusive rocks. Examples of intrusive igneous rocks include the intrusions such as dikes, sills, volcanic necks, batholith and laccolith. Contrary to this, an extrusive rock is the one that is formed when the magma from the inside of the Earth is thrown out by a volcanic eruption and it solidifies to form pyroclastics or tuff. The major similarity between intrusive and extrusive rocks is that they are both igneous rocks formed by the cooling and solidifying of the magma.
Thus, there are two ways in which igneous rocks are formed which are the intrusion and extrusion of magma. When the magma passes through the intrusions inside the Earth’s crust it forms the rocks that are intrusive and extrusive rocks are formed when the magma is exploded out of the Earth’s crust into the atmosphere and solidified. Out of the many differences, one particular difference between the formation of intrusive and extrusive rocks is the time taken by them to solidify. Since the intrusive forms are the ones that are solidified inside the Earth’s crust they take a longer time to cool down as compared to the extrusive forms which are solidified above the crust and so they cool down faster due to the open-air or seawater. Thus, these are some of the matters of significance in the formation of intrusive and extrusive rocks.
The intrusive igneous rocks are also referred to as plutonic rocks by some geologists. The ones that do not consider the intrusive rock and the plutonic rock to be the same, subdivide the intrusive rocks by the size of the crystal. The subdivisions are the coarse-grained plutonic rock which is generally formed very deep into the Earth’s crust and the medium-grained subvolcanic or hypabyssal rock which are typically formed higher than the plutonic rock level such as in the case of dikes and sills. In either of the cases, when the surrounding layer of Earth’s crust weathers away due to erosive activities, the intrusive rock lay exposed on the surface. A diagram showing the different types of intrusive volcanic features is given below:
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Intrusive Rock Characteristics
The intrusive igneous rocks are largely characterized by the size, shape and texture of the crystals. Different types of intrusive igneous rocks are also classified as well based on the size of the crystal. For example, when individual crystals are visible then the rock is said to be phaneritic. Although solidified, there are some indications of flow in the intrusive rocks as the texture and structure of such rocks develops during the final stages of crystallization which is when the flow has ended. Sometimes, there are large and well-shaped crystals found in the intrusive rocks lined along the cavities formed by the gases that are trapped and contained within the rocks. Such a texture is described as miarolitic and it is a common occurrence in granites. An interesting fact about such rocks is that the crystals inside such intrusive igneous rocks are roughly of the same size and hence, such igneous rocks are known as equiangular.
The plutonic rocks are less likely to be as pronounced in showing any porphyritic texture (a texture in which the first generation of large and well-shaped crystals are present inside a fine-grained groundmass) as any other volcanic rocks. Instead, the minerals inside the plutonic rocks have had a definite order with their period of crystallization which could have been distinct or coincided or overlapped with the period of formation of some other ingredients. The crystals that were formed earliest were more or less perfect in shape because most of the surrounding rock was still liquid while at later stage crystals are less regular in shape as they occupy the remaining spaces in-between the already-formed crystals. Because of this, the crystals formed earlier are known as idiomorphic crystals and the ones formed later are known as xenomorphic.
The hypabyssal rocks usually show structures that lie in-between the structures of extrusive igneous rocks and plutonic rocks or intrusive igneous rocks. They are usually porphyritic or non-crystalline amorphous solids, or sometimes vesicular i.e. present with many cavities. As they are formed near the surface of the Earth, they are indistinguishable in many cases from the lavas that have similar composition.
Types of Intrusive Igneous Rocks
Since any of the magma that is solidified and cooled within the intrusions of the Earth’s crust forms the intrusive rocks, there is a difference in between the cooling rates of the different intrusive igneous rocks, leading to different textures and hence different types of intrusive igneous rocks.
It is already known that the cooling of the magma within the intrusions is extremely slow. This is because the solid pre-existing rocks such as the country rock, surrounding the intrusions is an excellent insulator and thus, the temperature of the magma within the intrusions remains almost constant. It later very slowly cools down and solidifies forming the intrusive rocks. But there is a difference between the rates of cooling for the intrusive rocks at various depths. Due to this, the intrusive rocks formed at the very deep intrusions have coarse-grained texture whereas the intrusive rocks formed near the surface or shallow depths have less coarse-grained or fine-grained texture. This also forms the basis of classifying the intrusive rocks into plutonic (coarse-grained and formed at depth) and hypabyssal (less coarse-grained and formed at shallow depth) rocks.
Another manner in which most of the intrusive igneous rocks are classified is based on their mineral content such as the relative amounts of quartz, feldspar, plagioclase, etc. Both the plutonic and hypabyssal have their classification schemes due to the distinct nature of their granules and the relative mineral composition which can vary from bottom to top of the Earth’s crust.
FAQs on Intrusive Rock
1. What is an intrusive rock?
An intrusive rock is a type of igneous rock that forms when magma penetrates existing rock, crystallises, and solidifies deep within the Earth's crust. Because it cools very slowly beneath the surface, it develops large, visible mineral crystals. These rocks are also known as plutonic rocks and only become visible on the surface after the overlying layers are eroded away.
2. What is the main difference between intrusive and extrusive rocks?
The primary difference lies in their formation location and cooling rate, which determines their texture. Here’s a breakdown:
- Formation: Intrusive rocks solidify from magma below the Earth’s surface, while extrusive rocks solidify from lava on the Earth’s surface.
- Cooling Rate: Intrusive rocks cool slowly, over thousands of years, whereas extrusive rocks cool rapidly, in a matter of hours or days.
- Crystal Size: The slow cooling of intrusive rocks allows for the growth of large, visible crystals (a coarse-grained or phaneritic texture). Rapid cooling in extrusive rocks results in tiny, microscopic crystals (a fine-grained or aphanitic texture).
3. What are the key characteristics of intrusive rocks?
Intrusive rocks are primarily identified by the following characteristics:
- Coarse-Grained Texture: They are composed of large mineral crystals that are easily visible to the naked eye, such as in granite.
- High Density: They are generally very hard and dense due to their crystalline structure.
- Underground Origin: They form in large underground masses called plutons, which can take various forms like batholiths, sills, and dikes.
- Exposure through Erosion: They are typically found in the cores of mountain ranges, exposed only after extensive weathering and erosion have removed the overlying rock layers.
4. What are some common examples of intrusive igneous rocks?
The most common examples of intrusive rocks, which form the basis of continental and oceanic crust, include:
- Granite: A light-coloured rock rich in quartz and feldspar, making up a large part of the continental crust.
- Gabbro: A dark, coarse-grained rock rich in iron and magnesium, which is a major component of the oceanic crust.
- Diorite: An intermediate rock with a salt-and-pepper appearance, containing less quartz than granite.
- Peridotite: A dense, dark green ultramafic rock that is the main component of the Earth's upper mantle.
5. What are the different forms or structures of intrusive rocks?
When magma intrudes into pre-existing rock, it can form several distinct structures, or plutons. The main types include:
- Batholiths: These are the largest intrusive bodies, forming massive, irregularly shaped structures that often form the core of mountain ranges.
- Sills: A sheet-like intrusion that has been injected along the bedding planes of existing rock layers, running parallel to them.
- Dikes: A tabular intrusion that cuts vertically or at an angle across existing rock layers.
- Laccoliths: A dome-shaped intrusion that forms when magma pushes the overlying rock layers upward.
6. Why do intrusive rocks have large crystals while extrusive rocks do not?
The size of crystals in an igneous rock is directly related to its cooling rate. Intrusive rocks form from magma insulated deep within the Earth's crust, where it loses heat extremely slowly. This long cooling period, spanning thousands to millions of years, gives mineral ions ample time to migrate and bond, forming large, well-ordered crystals. In contrast, extrusive rocks form from lava exposed to the cool atmosphere, causing it to solidify rapidly and 'freezing' the ions in place before they can form large crystals.
7. If intrusive rocks form deep underground, how do they become exposed on the Earth's surface?
Intrusive rocks reach the surface through a two-part geological process. First, immense tectonic forces cause crustal uplift, pushing the deeply buried rock masses upwards to form mountain ranges. Second, the forces of weathering and erosion (from wind, water, and ice) act over millions of years to strip away the softer, overlying layers of rock, eventually exposing the hard, resistant core of intrusive rock, such as a granite batholith.
8. How does the composition of granite (a common intrusive rock) relate to the Earth's crust?
Granite is a felsic rock, meaning it is rich in silica and feldspar, which makes it less dense and lighter in colour. This composition is characteristic of the continental crust. Its lower density is a key reason why continents 'float' higher on the mantle compared to the oceanic crust, which is made of denser, mafic rocks like basalt and gabbro. Therefore, granite is fundamentally important to the structure and elevation of Earth's landmasses.
