Physical Geography Chapter-5-MINERALS AND ROCKS

 Chapter-5-MINERALS AND ROCKS

 Mineral is a naturally occurring organic and inorganic substance, having an orderly atomic

structure and a definite chemical composition and physical properties.

 A mineral is composed of two or more elements. But, sometimes single element minerals like

sulphur, copper, silver, gold, graphite etc. are found.

 These elements are in solid form in the outer layer of the earth and in hot and molten form in the

interior.

 About 98 per cent of the total crust of the earth is composed of eight elements like oxygen,

silicon, aluminium, iron, calcium, sodium, potassium and magnesium (Table 5.1), and the rest

is constituted by titanium, hydrogen, phosphorous, manganese, sulphur, carbon, nickel and

other elements.

Sl. No. Elements By Weight(%)

1. Oxygen 46.60

2. Silicon 27.72

3. Aluminium 8.13

4. Iron 5.00

5. Calcium 3.63

6. Sodium 2.83

7. Potassium 2.59

8. Magnesium 2.09

9. Others 1.41

 The basic source of all minerals is the hot magma in the interior of the earth.

 When magma cools, crystals of minerals appear and a systematic series of minerals are formed

in sequence to solidify so as to form rocks.

 Minerals such as coal, petroleum and natural gas are organic substances found in solid,

liquid and gaseous forms respectively.

PHYSICAL CHARACTERISTICS

 External crystal form — determined by internal arrangement of the molecules —

cubes, octahedrons, hexagonal prisms, etc.

 Cleavage — tendency to break in given directions producing relatively plane surfaces

— result of internal arrangement of the molecules — may cleave in one or more

directions and at any angle to each other.

 Fracture — internal molecular arrangement so complex there are no planes of molecules;

the crystal will break in an irregular manner, not along planes of cleavage.

 Lustre — appearance of a material without regard to colour; each mineral has a distinctive

lustre like metallic, silky, glossy etc.

 Colour — some minerals have characteristic colour determined by their molecular

structure — malachite, azurite, chalcopyrite etc., and some minerals are coloured by

impurities. For example, because of impurities quartz may be white, green, red, yellow etc.

 Streak — colour of the ground powder of any mineral. It may be of the same colour as the

mineral or may differ — malachite is green and gives green streak, fluorite is purple or green but

gives a white streak.

 Transparency — transparent: light rays pass through so that objects can be seen plainly;

translucent

— light rays pass through but will get diffused so that objects cannot be seen; opaque —

light will not pass at all.

 Structure — particular arrange- ment of the individual crystals; fine, medium or coarse

grained; fibrous — separable, divergent, radiating.

 Hardness — relative resistance being scratched; ten minerals are selected to measure the

degree of hardness from 1-10. They are:

 talc; 2. gypsum; 3. calcite;

4. fluorite; 5. apatite; 6. feldspar; 7. quartz; 8. topaz; 9. corundum;

10. diamond. Compared to this for example, a fingernail is 2.5 and glass or knife blade is

5.5.

 Specific gravity — the ratio between the weight of a given object and the weight of an equal

volume of water; object weighed in air and then weighed in water and divide weight in air

by the difference of the two weights.

SOME MAJOR MINERALS AND THEIR CHARACTERISTICS

Feldspar

 Silicon and oxygen are common elements in all types of feldspar and sodium,

potassium, calcium, aluminium etc. are found in specific feldspar variety.

 Half of the earth’s crust is composed of feldspar.

 It has light cream to salmon pink colour.

 It is used in ceramics and glass making.

Quartz

 It is one of the most important components of sand and granite.

 It consists of silica.

 It is a hard mineral virtually insoluble in water.

 It is white or colourless and used in radio and radar.

 It is one of the most important components of granite.

Pyroxene

 Pyroxene consists of calcium, aluminum, magnesium, iron and silica.

 Pyroxene forms 10 per cent of the earth’s crust.

 It is commonly found in meteorites.

 It is in green or black colour.

Amphibole

 Aluminium, calcium, silica, iron, magnesium are the major elements of

amphiboles.

 They form 7 per cent of the earth’s crust.

 It is in green or black colour and is used in asbestos industry.

 Hornblende is another form of amphiboles.

Mica

 It comprises of potassium, aluminium, magnesium, iron, silica etc.

 It forms 4 per cent of the earth’s crust.

 It is commonly found in igneous and metamorphic rocks.

 It is used in electrical instruments.

Olivine

 Magnesium, iron and silica are major elements of olivine.

 It is used in jewellery.

 It is usually a greenish crystal, often found in basaltic rocks.

 Besides these main minerals, other minerals like chlorite, calcite, magnetite,

haematite, bauxite and barite are also present in some quantities in the rocks.

Metallic Minerals

These minerals contain metal content and can be sub-divided into three types:

(i) Precious metals : gold, silver, platinum etc.

(ii) Ferrous metals : iron and other metals often mixed with iron to form various kinds of steel.

(iii) Non-ferrous metals : include metals like copper, lead, zinc, tin, aluminium etc.

Non-Metallic Minerals

 These minerals do not contain metal content. Sulphur, phosphates and nitrates are

examples of non-metallic minerals.

 Cement is a mixture of non-metallic minerals.

ROCKS

 The earth’s crust is composed of rocks.

 A rock is an aggregate of one or more minerals.

 Rock may be hard or soft and in varied colours.

 For example, granite is hard, soapstone is soft.

 Gabbro is black and quartzite can be milky white.

 Rocks do not have definite composition of mineral constituents.

 Feldspar and quartz are the most common minerals found in rocks.

 Petrology is science of rocks.

 A petrologist studies rocks in all their aspects viz., mineral composition, texture,

structure, origin, occurrence, alteration and relationship with other rocks.

 As there is a close relation between rocks and landforms, rocks and soils, a geographer

requires basic knowledge of rocks.

 There are many different kinds of rocks which are grouped under three families on the

basis of their mode of formation.

 They are:

 Igneous Rocks — solidified from magma and lava;

 Sedimentary Rocks — the result of deposition of fragments of rocks by exogenous processes;

 Metamorphic Rocks — formed out of existing rocks undergoing recrystallisation.

Igneous Rocks

 As igneous rocks form out of magma and lava from the interior of the earth, they are known

as primary rocks.

 The igneous rocks (Ignis – in Latin means ‘Fire’) are formed when magma cools and

solidifies.

 When magma in its upward movement cools and turns into solid form it is called igneous

rock.

 The process of cooling and solidification can happen in the earth’s crust or on the surface of

the earth.

 Igneous rocks are classified based on texture. Texture depends upon size and

arrangement of grains or other physical conditions of the materials.

 If molten material is cooled slowly at great depths, mineral grains may be very large.

 Sudden cooling (at the surface) results in small and smooth grains.

 Intermediate conditions of cooling would result in intermediate sizes of grains making up

igneous rocks.

 Granite, gabbro, pegmatite, basalt, volcanic breccia and tuff are some of the examples of

igneous rocks.

Sedimentary Rocks

 The word ‘sedimentary’ is derived from the Latin word sedimentum, which means settling.

 Rocks (igneous, sedimentary and metamorphic) of the earth’s surface are exposed to

denudational agents, and are broken up into various sizes of fragments.

 Such fragments are transported by different exogenous agencies and deposited.

 These deposits through compaction turn into rocks.

 This process is called lithification.

 In many sedimentary rocks, the layers of deposits retain their characteristics even after

lithification.

 Hence, we see a number of layers of varying thickness in sedimentary rocks like sandstone,

shale etc.

 Depending upon the mode of formation, sedimentary rocks are classified into three major groups:

(i) mechanically formed — sandstone, conglomerate, limestone, shale, loess etc. are examples;

(ii) organically formed — geyserite, chalk, limestone, coal etc. are some examples; (iii)chemically

formed — chert, limestone, halite, potash etc. are some examples.

Metamorphic Rocks

 The word metamorphic means ‘change of form’.

 These rocks form under the action of pressure, volume and temperature (PVT) changes.

 Metamorphism occurs when rocks are forced down to lower levels by tectonic processes or

when molten magma rising through the crust comes in contact with the crustal rocks or the

underlying rocks are subjected to great amounts of pressure by overlying rocks.

 Metamorphism is a process by which already consolidated rocks undergo recrystallisation

and reorganisation of materials within original rocks.

 Mechanical disruption and reorganisation of the original minerals within rocks due to

breaking and crushing without any appreciable chemical changes is called dynamic

metamorphism.

 The materials of rocks chemically alter and recrystallise due to thermal metamorphism.

 There are two types of thermal metamorphism — contact metamorphism and regional

metamorphism.

 In contact metamorphism the rocks come in contact with hot intruding magma and lava and

the rock materials recrystallise under high temperatures.

 Quite often new materials form out of magma or lava are added to the rocks.

 In regional metamorphism, rocks undergo recrystallisation due to deformation caused by

tectonic shearing together with high temperature or pressure or both.

 In the process of metamorphism in some rocks grains or minerals get arranged in layers or

lines. Such an arrangement of minerals or grains in metamorphic rocks is called foliation

or lineation.

 Sometimes minerals or materials of different groups are arranged into alternating thin to thick

layers appearing in light and dark shades. Such a structure in metamorphic rocks is called

banding and rocks displaying banding are called banded rocks.

 Types of metamorphic rocks depend upon original rocks that were subjected to

metamorphism.

 Metamorphic rocks are classified into two major groups — foliated rocks and non-foliated

rocks. Gneissoid, granite, syenite, slate, schist, marble, quartzite etc. are some examples of

metamorphic rocks.

ROCK CYCLE

 Rocks do not remain in their original form for long but may undergo transformation.

Rock cycle is a continuous process through which old rocks are transformed into

new ones.

 Igneous rocks are primary rocks and other rocks (sedimentary and metamorphic) form

from these primary rocks. Igneous rocks can be changed into metamorphic rocks.

 The fragments derived out of igneous and metamorphic rocks form into

sedimentary rocks.

 Sedimentary rocks themselves can turn into fragments and the fragments can be a

source for formation of sedimentary rocks.

 The crustal rocks (igneous, metamorphic and sedimentary) once formed may be

carried down into the mantle (interior of the earth) through subduction process (parts

or whole of crustal plates going down under another plate in zones of plate

convergence) and the same melt down due to increase in temperature in the

interior and turn into molten magma, the original source for igneous rocks