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# Understanding minerals and their occurrence
Minerals are naturally occurring substances crucial to human life and industry, found in rocks and derived from the Earth's crust.
## 1. Understanding minerals and their occurrence
Minerals are fundamental to daily life, utilized in countless items from everyday objects to large-scale infrastructure and even present in our food. Geologists define a mineral as a homogenous, naturally occurring substance with a definable internal structure. Minerals exhibit a wide range of properties such as color, hardness, crystal form, luster, and density, which are influenced by the specific physical and chemical conditions under which they form. Geographers study minerals for their role in landforms and economic activities, while geologists focus on their formation, age, and composition [1](#page=1) [2](#page=2).
### 1.1 Rock composition
Rocks are typically combinations of homogenous substances called minerals. While some rocks, like limestone, consist of a single mineral, most are composed of several minerals in varying proportions. Over 2,000 minerals have been identified, but only a few are found abundantly in most rocks [2](#page=2).
### 1.2 Modes of mineral occurrence
Minerals are typically found in "ores," which are accumulations of minerals mixed with other elements. The concentration of minerals in an ore must be sufficient for commercially viable extraction. The way minerals occur influences the ease and cost of mining. Minerals generally occur in the following forms [2](#page=2):
#### 1.2.1 Igneous and metamorphic rocks
Minerals can be found in cracks, crevices, faults, or joints within igneous and metamorphic rocks. Small occurrences are termed veins, while larger ones are called lodes. These often form when minerals in liquid, molten, or gaseous states are forced upwards through cavities and cool as they rise. Major metallic minerals such as tin, copper, zinc, and lead are commonly obtained from veins and lodes [2](#page=2).
#### 1.2.2 Sedimentary rocks
In sedimentary rocks, numerous minerals are found in beds or layers, formed by deposition, accumulation, and concentration in horizontal strata. Coal and some iron ores are examples of minerals concentrated over long periods under heat and pressure. Other sedimentary minerals, like gypsum, potash salt, and sodium salt, form through evaporation, particularly in arid regions [2](#page=2).
#### 1.2.3 Residual deposits
A mode of formation involves the decomposition of surface rocks, where soluble constituents are removed, leaving a residual mass of weathered material containing ores. Bauxite is an example of a mineral formed in this manner [2](#page=2).
#### 1.2.4 Alluvial deposits
Certain minerals occur as alluvial deposits in the sands of valley floors and at the base of hills. These are known as 'placer deposits' and typically contain minerals resistant to corrosion by water. Gold, silver, tin, and platinum are significant placer minerals [3](#page=3).
#### 1.2.5 Ocean deposits
Ocean waters contain vast quantities of minerals, although many are too diffused for economic significance. However, common salt, magnesium, and bromine are largely extracted from seawater. Ocean beds are also rich in manganese nodules [3](#page=3).
### 1.3 Distribution variations
Mineral distribution across India is uneven. Peninsular rocks generally contain most reserves of coal, metallic minerals, mica, and non-metallic minerals. Petroleum deposits are primarily found in sedimentary rocks on the western and eastern flanks of the peninsula, in Gujarat and Assam. Rajasthan possesses reserves of many non-ferrous minerals. The vast alluvial plains of North India are largely devoid of economic minerals. These variations are attributed to differences in geological structure, processes, and the time involved in mineral formation. The economic viability of a mineral reserve is influenced by the concentration of minerals in the ore, ease of extraction, and proximity to markets [3](#page=3).
### 1.4 Major mineral categories and their occurrences in India
#### 1.4.1 Ferrous minerals
Ferrous minerals constitute approximately three-fourths of the total value of metallic mineral production in India. They are crucial for the development of metallurgical industries [3](#page=3).
* **Iron Ore:** India possesses abundant and good quality iron ore resources [3](#page=3).
* **Magnetite:** The finest iron ore, with up to 70% iron content and excellent magnetic properties valuable for the electrical industry [3](#page=3).
* **Hematite:** The most important industrial iron ore by quantity used, with 50-60% iron content [3](#page=3).
* **Major Iron Ore Belts:**
* **Odisha-Jharkhand belt:** Found in Mayurbhanj, Kendujhar (Odisha), and Singbhum (Jharkhand) districts [4](#page=4).
* **Durg-Bastar-Chandrapur belt:** Located in Chhattisgarh and Maharashtra, featuring the Bailadila range with super high-grade hematite. Ore is exported via Vishakhapatnam port [4](#page=4).
* **Ballari-Chitradurga-Chikkamagaluru-Tumakuru belt:** In Karnataka, with the Kudremukh mines being a 100% export unit known for its large reserves. Ore is transported as slurry to a port near Mangaluru [4](#page=4).
* **Maharashtra-Goa belt:** Includes Goa and Ratnagiri district (Maharashtra), though ore quality is not very high, it is efficiently exploited and exported through Marmagao port [4](#page=4).
* **Manganese:** Primarily used in steel and ferro-manganese alloy production. Approximately 10 kg of manganese is required to produce one tonne of steel. It is also used in manufacturing bleaching powder, insecticides, and paints [4](#page=4).
#### 1.4.2 Non-ferrous minerals
India's reserves and production of non-ferrous minerals are not highly satisfactory, but they are vital for metallurgical, engineering, and electrical industries [4](#page=4).
* **Copper:** India is critically deficient in copper reserves and production. Its malleability, ductility, and conductivity make it essential for electrical cables, electronics, and chemical industries. Leading producers include Balaghat mines (Madhya Pradesh), Khetri mines (Rajasthan), and Singhbhum district (Jharkhand) [6](#page=6).
* **Bauxite:** The primary source for obtaining alumina and aluminum. Bauxite deposits form from the decomposition of various rocks rich in aluminum silicates. Aluminum is valued for its strength, lightness, conductivity, and malleability. Major bauxite deposits in India are found in the Amarkantak plateau, Maikal hills, and the plateau region of Bilaspur-Katni. Odisha was the largest bauxite-producing state in 2018-19, with Panchpatmali deposits in Koraput district being significant [6](#page=6).
#### 1.4.3 Non-metallic minerals
* **Mica:** Composed of thin, easily splittable plates or leaves. Its excellent dielectric strength, low power loss factor, insulating properties, and resistance to high voltage make it indispensable in electric and electronic industries [7](#page=7).
* **Deposits:** Found on the northern edge of the Chota Nagpur plateau, with the Koderma-Gaya-Hazaribagh belt in Jharkhand being a leading producer. In Rajasthan, the Ajmer region is a major producer, and the Nellore mica belt in Andhra Pradesh is also significant [7](#page=7).
* **Rock Minerals:**
* **Limestone:** Occurs with rocks of calcium carbonates or calcium and magnesium carbonates, typically in sedimentary rocks. It is a basic raw material for the cement industry and essential for smelting iron ore in blast furnaces [7](#page=7).
### 1.5 Hazards of mining
Mining activities pose significant risks to miners' health and the environment. Inhaling dust and noxious fumes can lead to pulmonary diseases, and miners face constant threats from collapsing roofs, inundation, and fires in coal mines. Mining also contaminates water sources and leads to land degradation, soil deterioration, and increased stream and river pollution due to the dumping of waste and slurry [7](#page=7).
> **Tip:** Understanding the geological context and the specific processes of mineral formation is key to comprehending their distribution and occurrence. Pay attention to the links between rock types and the minerals found within them.
> **Example:** The formation of placer deposits, like those containing gold, occurs when water erodes mineral-bearing rocks and deposits the resistant heavy minerals in stream beds or on beaches. This process concentrates valuable minerals in accessible locations [3](#page=3).
---
# Distribution and importance of metallic minerals in India
This topic explores the geographical spread and economic significance of key metallic minerals in India, focusing on ferrous minerals like iron ore and manganese, and non-ferrous minerals such as copper and bauxite.
### 2.1 General Distribution of Minerals in India
India possesses a rich and varied range of mineral resources, but their distribution is uneven across the country. Peninsular rocks generally hold the majority of reserves for coal, metallic minerals, mica, and many non-metallic minerals. Conversely, the sedimentary rocks along the western and eastern edges of the peninsula, in regions like Gujarat and Assam, contain most of the petroleum deposits. Rajasthan's rock systems also contain significant mineral reserves. The vast alluvial plains of North India are largely devoid of economic mineral deposits. These variations in mineral distribution are attributed to differences in geological structure, formation processes, and the time involved in their creation [3](#page=3).
> **Tip:** The economic viability of a mineral reserve is influenced by the concentration of the mineral in the ore, the ease of extraction, and its proximity to markets. These factors determine whether a mineral "deposit" or "reserve" becomes an active "mine" [3](#page=3).
### 2.2 Ferrous minerals
Ferrous minerals constitute approximately three-fourths of the total value of metallic mineral production in India and form a crucial foundation for the development of metallurgical industries. India exports a considerable amount of ferrous minerals after fulfilling domestic demand [3](#page=3).
#### 2.2.1 Iron ore
Iron ore is considered a fundamental mineral and the backbone of industrial development. India is well-endowed with substantial reserves of high-quality iron ore [3](#page=3).
* **Types of Iron Ore:**
* **Magnetite:** This is the finest grade of iron ore, containing up to 70% iron, and possesses excellent magnetic properties valuable in the electrical industry [3](#page=3).
* **Hematite:** While slightly lower in iron content (50-60%), hematite ore is the most industrially significant in terms of usage [3](#page=3).
* **Distribution of Iron Ore:**
* In 2018–19, nearly all iron ore production (97%) originated from Odisha, Chhattisgarh, Karnataka, and Jharkhand, with the remaining 3% coming from other states [3](#page=3).
* **Major Iron Ore Belts:**
* **Odisha-Jharkhand belt:** High-grade hematite is found in the Badampahar mines (Mayurbhanj and Kendujhar districts) in Odisha, and in the Singbhum district of Jharkhand (Gua and Noamundi) [4](#page=4).
* **Durg-Bastar-Chandrapur belt:** Located in Chhattisgarh and Maharashtra, this belt features very high-grade hematites in the Bailadila range of hills in Bastar district, Chhattisgarh. These hills contain 14 deposits of super high-grade hematite iron ore with excellent properties for steelmaking. Ore from these mines is exported to Japan and South Korea via the Vishakhapatnam port [4](#page=4).
* **Ballari-Chitradurga-Chikkamagaluru-Tumakuru belt:** This belt in Karnataka holds large iron ore reserves. The Kudremukh mines in the Western Ghats are a 100% export-oriented unit and are among the world's largest deposits, with ore transported as slurry to a port near Mangaluru [4](#page=4).
* **Maharashtra-Goa belt:** This belt includes Goa state and the Ratnagiri district of Maharashtra. Although the ore quality is not exceptionally high, it is efficiently exploited, and iron ore is exported through the Marmagao port [4](#page=4).
> **Example:** The Bailadila hills in Chhattisgarh are named after their resemblance to an ox's hump, similar to how the Kudremukh hills in Karnataka are named after a horse's face [3](#page=3).
#### 2.2.2 Manganese
Manganese is primarily used in the production of steel and ferro-manganese alloy; approximately 10 kilograms of manganese are required to produce one tonne of steel. It also finds applications in the manufacturing of bleaching powder, insecticides, and paints [4](#page=4).
* **Distribution of Manganese (2018–19):**
* Odisha: 16% [4](#page=4).
* Karnataka: 12% [4](#page=4).
* Madhya Pradesh: 33% [4](#page=4).
* Maharashtra: 27% [4](#page=4).
* Andhra Pradesh: 10% [4](#page=4).
* Others: 2% [4](#page=4).
> **Tip:** Superimposing maps of iron ore, manganese, coal, and iron and steel industries can reveal significant correlations, highlighting the interconnectedness of these resources and industries [4](#page=4).
### 2.3 Non-ferrous minerals
India's reserves and production of non-ferrous minerals are not as substantial. However, these minerals, including copper, bauxite, lead, zinc, and gold, play a crucial role in various metallurgical, engineering, and electrical industries [4](#page=4).
#### 2.3.1 Copper
India faces a critical deficiency in both the reserves and production of copper. Copper's properties of malleability, ductility, and good conductivity make it primarily useful in electrical cables, electronics, and chemical industries [6](#page=6).
* **Leading Copper Producers:**
* Balaghat mines in Madhya Pradesh [6](#page=6).
* Khetri mines in Rajasthan [6](#page=6).
* Singhbhum district of Jharkhand [6](#page=6).
#### 2.3.2 Bauxite
Bauxite is the primary ore from which alumina and subsequently aluminium are extracted. Aluminium is a valuable metal as it combines the strength of metals like iron with extreme lightness, good conductivity, and high malleability. Bauxite deposits are formed from the decomposition of various aluminium silicate-rich rocks [6](#page=6).
* **Major Bauxite Deposit Areas:**
* Amarkantak plateau [6](#page=6).
* Maikal hills [6](#page=6).
* Plateau region of Bilaspur-Katni [6](#page=6).
* **Distribution of Bauxite (2018–19):**
* Odisha was the largest producer, accounting for 65% of production, with the Panchpatmali deposits in Koraput district being the most significant [6](#page=6).
* Jharkhand: 10% [6](#page=6).
* Gujarat: 9% [6](#page=6).
* Chhattisgarh: 6% [6](#page=6).
* Maharashtra: 6% [6](#page=6).
* Madhya Pradesh: 3% [6](#page=6).
* Others: 1% [6](#page=6).
> **Example:** In the past, aluminium was so rare and precious that Emperor Napoleon III used aluminium buttons and served guests in aluminium utensils, while less important guests were served in gold and silver. Later, aluminium became common and was used by beggars in Paris [7](#page=7).
### 2.4 Non-metallic Minerals
#### 2.4.1 Mica
Mica is a mineral composed of layered plates or sheets that can be split into extremely thin layers. Its low power loss factor, excellent dielectric strength, insulating properties, and resistance to high voltage make it indispensable in electric and electronic industries [7](#page=7).
* **Major Mica Producing Areas:**
* Koderma-Gaya-Hazaribagh belt in Jharkhand (leading producer) [7](#page=7).
* Around Ajmer in Rajasthan [7](#page=7).
* Nellore mica belt of Andhra Pradesh [7](#page=7).
### 2.5 Rock Minerals
#### 2.5.1 Limestone
Limestone is typically found in association with rocks containing calcium carbonates or calcium and magnesium carbonates and is present in sedimentary rocks of most geological formations. It serves as the fundamental raw material for the cement industry and is essential for smelting iron ore in blast furnaces [7](#page=7).
> **Tip:** Examining maps can help explain why regions like Chota Nagpur are considered storehouses of minerals [7](#page=7).
### 2.6 Hazards of Mining
Mining, while essential for modern life, poses significant risks to miners and the environment [7](#page=7).
* **Health Hazards for Miners:** Inhalation of dust and noxious fumes can lead to pulmonary diseases. Miners constantly face threats from collapsing mine roofs, inundation, and fires, particularly in coal mines [7](#page=7).
* **Environmental Impacts:** Mining activities can contaminate water sources. The dumping of waste and slurry degrades land and soil, and contributes to stream and river pollution [7](#page=7).
---
# Non-metallic and rock minerals in India
This topic examines the geographical distribution and industrial significance of key non-metallic and rock minerals found in India, with a particular focus on mica and limestone.
### 3.1 Non-metallic minerals
#### 3.1.1 Mica
Mica is a mineral characterized by its layered or leafy structure, which allows it to be easily split into extremely thin sheets. These sheets can be so fine that a thousand can be stacked to form a mica sheet only a few centimeters high. Mica exhibits a range of colors, including clear, black, green, red, and brown. Its indispensability in the electric and electronic industries stems from its excellent dielectric strength, low power loss factor, effective insulating properties, and high voltage resistance [7](#page=7).
##### 3.1.1.1 Distribution of mica in India
Deposits of mica are primarily located on the northern edge of the Chota Nagpur plateau. The Koderma-Gaya-Hazaribagh belt in Jharkhand is identified as the leading producer of mica in the country. In Rajasthan, the principal mica-producing region is found around Ajmer. The Nellore mica belt in Andhra Pradesh is another significant contributor to India's mica production [7](#page=7).
### 3.2 Rock minerals
#### 3.2.1 Limestone
Limestone is a mineral found in association with rocks composed of calcium carbonates or calcium and magnesium carbonates. It occurs within sedimentary rocks across most geological formations. Limestone serves as a fundamental raw material for the cement industry. Furthermore, it is crucial for the smelting of iron ore in blast furnaces [7](#page=7).
> **Tip:** Understanding the geological formations associated with limestone is key to identifying potential deposits for industrial use.
> **Example:** The widespread availability of limestone in sedimentary rock areas explains its importance for both construction (cement) and metallurgical industries.
### 3.3 Hazards of mining
Mining, while essential for resource extraction, poses significant risks to both human health and the environment [7](#page=7).
#### 3.3.1 Health impacts on miners
Miners are exposed to dust and noxious fumes, which can lead to pulmonary diseases. Constant threats to miners' safety include the risk of collapsing mine roofs, inundation, and fires, particularly in coal mines [7](#page=7).
#### 3.3.2 Environmental impacts of mining
Mining activities can contaminate water sources in the surrounding regions. The dumping of waste and slurry from mining operations results in the degradation of land and soil. This pollution also contributes to an increase in the contamination of streams and rivers [7](#page=7).
> **Tip:** The environmental and health consequences highlight the importance of implementing strict safety regulations and sustainable mining practices.
> **Example:** Air pollution caused by dust generation in mining areas (as depicted in Fig. 5.8) is a visible environmental hazard [7](#page=7).
---
# Energy resources in India: Conventional and non-conventional
Energy is fundamental to all human activities, powering everything from cooking and lighting to transportation and industrial machinery. In India, energy resources are broadly categorized into conventional and non-conventional sources, encompassing a wide range of materials and methods for power generation and distribution [9](#page=9).
### 4.1 Conventional sources of energy
Conventional energy sources include those that have been traditionally used and are often finite in supply.
#### 4.1.1 Coal
Coal is India's most abundant fossil fuel, fulfilling a significant portion of the nation's energy demands for power generation, industry, and domestic use. Its formation is a result of the compression of plant material over millions of years, leading to different forms based on the degree of compression, depth, and burial time [9](#page=9).
* **Peat:** Formed from decaying plants in swamps, it has low carbon and high moisture content, resulting in low heating capacity [9](#page=9).
* **Lignite:** A low-grade, soft brown coal with high moisture content. Principal reserves are in Neyveli, Tamil Nadu, used for electricity generation [9](#page=9).
* **Bituminous Coal:** Coal buried deep and subjected to increased temperatures; it is the most common type in commercial use [9](#page=9).
* **Metallurgical Coal:** High-grade bituminous coal essential for smelting iron in blast furnaces [9](#page=9).
* **Anthracite:** The highest quality hard coal [9](#page=9).
Coal deposits in India belong to two main geological ages: Gondwana (over 200 million years old), primarily found in the Damodar Valley (Jharia, Raniganj, Bokaro) and in the Godavari, Mahanadi, Son, and Wardha valleys, yielding metallurgical coal. Tertiary deposits (around 55 million years old) are located in the northeastern states of Meghalaya, Assam, Arunachal Pradesh, and Nagaland. Due to its bulky nature and weight loss during use (reduced to ash), heavy industries and thermal power stations are often situated near coalfields [9](#page=9).
#### 4.1.2 Petroleum
Petroleum, or mineral oil, is the second most important energy source in India after coal. It serves as fuel for heat and lighting, lubricant for machinery, and a crucial raw material for various manufacturing industries, acting as a nodal industry for synthetic textiles, fertilizers, and chemical industries through its refineries [11](#page=11).
Petroleum occurrences in India are typically associated with anticlines and fault traps in tertiary rock formations. Oil is trapped in porous limestone or sandstone layers, prevented from escaping by intervening non-porous layers. Natural gas, being lighter, usually occupies the space above the oil. Major petroleum production areas include Mumbai High, Gujarat, and Assam. Ankleshwar is a significant field in Gujarat, while Digboi, Naharkatiya, and Moran-Hugrijan are important in Assam, the oldest oil-producing state in India [11](#page=11).
#### 4.1.3 Natural Gas
Natural gas is found alongside petroleum deposits and is released during crude oil extraction. It is versatile, used as a domestic and industrial fuel, in the power sector for electricity generation, for heating in industries, as a feedstock for chemical, petrochemical, and fertilizer industries, and as a transport fuel (CNG) and cooking fuel (PNG). India's major natural gas reserves are in Mumbai High and allied fields on the west coast, supplemented by discoveries in the Cambay basin. New reserves have also been found in the Krishna-Godavari basin along the East Coast [11](#page=11).
The Hazira-Vijaipur-Jagdishpur (HVJ) cross-country gas pipeline, constructed by GAIL (India), was a significant development, connecting Mumbai High and Bassein gas fields to fertilizer, power, and industrial complexes in western and northern India. India's gas pipeline infrastructure has expanded significantly, from 1,700 km to 18,500 km, with plans to reach over 34,000 km to link all gas sources and consuming markets [11](#page=11).
#### 4.1.4 Electricity
Electricity's per capita consumption is a key indicator of a nation's development. It is primarily generated through two methods [11](#page=11):
* **Hydroelectricity:** Generated by fast-flowing water using hydro turbines; it is a renewable resource. India has several multipurpose projects like Bhakra Nangal, Damodar Valley Corporation, and Kopili Hydel Project that produce hydroelectric power [11](#page=11).
* **Thermal Power:** Produced by burning fossil fuels like coal, petroleum, and natural gas to drive turbines. Thermal power stations utilize non-renewable fossil fuels [11](#page=11).
> **Tip:** Once generated, hydroelectricity and thermal electricity are indistinguishable [11](#page=11).
### 4.2 Non-conventional sources of energy
The increasing demand for energy and the reliance on fossil fuels, coupled with rising prices and supply uncertainties, necessitate the exploration and utilization of renewable energy sources. These non-conventional sources include solar, wind, tidal, geothermal, and nuclear energy. Their development is crucial for environmental conservation and energy security [13](#page=13) [9](#page=9).
#### 4.2.1 Nuclear or atomic energy
Nuclear energy is produced by altering the structure of atoms, releasing significant amounts of energy in the form of heat used for electric power generation. Uranium and Thorium are the key minerals used, found in Jharkhand, the Aravalli ranges of Rajasthan, and the monazite sands of Kerala [13](#page=13).
#### 4.2.2 Solar energy
As a tropical country, India possesses immense potential for harnessing solar energy. Photovoltaic technology directly converts sunlight into electricity. Solar energy is becoming increasingly popular, particularly in rural and remote areas, reducing dependence on firewood and dung cakes, thereby contributing to environmental conservation and preserving manure for agriculture [13](#page=13).
> **Example:** Solar operated electronic milk testing equipment utilizes solar energy [13](#page=13).
#### 4.2.3 Wind power
India has substantial wind power potential, with the largest wind farm cluster located in Tamil Nadu, extending from Nagarcoil to Madurai. Other significant wind power states include Andhra Pradesh, Karnataka, Gujarat, Kerala, Maharashtra, and Lakshadweep. Nagarcoil and Jaisalmer are recognized for their effective use of wind energy [13](#page=13).
> **Example:** Windmills are a common sight in areas with significant wind power generation, such as Nagarcoil [13](#page=13).
#### 4.2.4 Biogas
Biogas is produced from shrubs, farm waste, and animal and human waste, serving as a domestic fuel in rural areas. The decomposition of organic matter generates gas with higher thermal efficiency than kerosene, dung cake, or charcoal. Biogas plants can be established at municipal, cooperative, or individual levels, with those using cattle dung often referred to as 'Gobar gas plants'. These plants offer dual benefits by providing energy and improving manure quality, while also preventing the depletion of trees and manure due to burning fuelwood and cow dung cakes [13](#page=13).
> **Tip:** Biogas is considered the most efficient use of cattle dung [13](#page=13).
#### 4.2.5 Tidal energy
Tidal energy utilizes oceanic tides to generate electricity. Floodgate dams built across inlets trap water during high tide. As the tide recedes, the retained water flows back to the sea through a pipe connected to a power-generating turbine. Ideal conditions for tidal energy utilization in India exist in the Gulf of Khambhat and the Gulf of Kuchchh in Gujarat on the western coast, and the Gangetic delta in the Sunderban regions of West Bengal [14](#page=14).
#### 4.2.6 Geothermal energy
Geothermal energy harnesses heat from the Earth's interior to produce electricity. Where the geothermal gradient is high, groundwater absorbs heat from shallow rocks and rises to the surface as steam, which can then drive turbines. India has numerous hot springs with the potential for electricity generation. Experimental projects are underway in the Parvati Valley (Himachal Pradesh) and Puga Valley (Ladakh) [14](#page=14).
### 4.3 Conservation of energy resources
Energy is fundamental to economic development, supporting agriculture, industry, transport, and domestic needs. The continuous rise in energy consumption necessitates a sustainable approach to energy development, emphasizing both energy conservation and the increased use of renewable sources. India is currently one of the least energy-efficient countries [14](#page=14).
> **Tip:** "Energy saved is energy produced" [14](#page=14).
Individuals can contribute to energy conservation by using public transport, switching off lights when not in use, employing power-saving devices, and opting for non-conventional energy sources [14](#page=14).
---
# Conservation and hazards of mineral and energy resources
This topic examines the significant environmental and health risks associated with mining, emphasizing the necessity of conserving finite mineral and energy resources through sustainable practices and the adoption of substitutes.
### 5.1 Hazards of mining
Mining operations pose considerable threats to both the health of miners and the surrounding environment. The inhalation of dust and noxious fumes by miners can lead to serious pulmonary diseases. Furthermore, miners face constant dangers such as collapsing mine roofs, inundation, and fires, particularly in coal mines [7](#page=7).
The environmental consequences of mining are also severe. Water sources in mining regions often become contaminated. The dumping of waste materials and slurry contributes to land degradation, soil deterioration, and increased pollution in streams and rivers. Air pollution is another significant issue, caused by the generation of dust during mining activities [7](#page=7).
To mitigate these risks, stricter safety regulations and the consistent implementation of environmental laws are crucial to prevent mining from being a dangerous industry [8](#page=8).
### 5.2 Conservation of minerals
The industrial and agricultural sectors are heavily reliant on mineral deposits and the products derived from them. However, the Earth's crust contains only a small fraction, approximately one percent, of workable mineral deposits. We are rapidly depleting these resources, which took millions of years to form and accumulate. The geological processes responsible for mineral formation are exceptionally slow, meaning replenishment rates are minuscule compared to current consumption rates. Consequently, mineral resources are finite and non-renewable. Rich mineral deposits are valuable but transient assets for any country [8](#page=8).
Continued extraction of ores becomes increasingly costly as deposits are found at greater depths and their quality declines [8](#page=8).
#### 5.2.1 Mineral examples and locations
* **Mica:** A mineral composed of easily splittable plates or leaves that can be layered into extremely thin sheets. Its excellent dielectric strength, low power loss factor, insulating properties, and resistance to high voltage make it indispensable in the electric and electronic industries. Mica deposits are found on the northern edge of the Chota Nagpur plateau, with the Koderma-Gaya-Hazaribagh belt in Jharkhand being a leading producer. Rajasthan, around Ajmer, is another significant mica-producing area, alongside the Nellore mica belt in Andhra Pradesh [7](#page=7).
* **Limestone:** Found in association with rocks containing calcium carbonates or calcium and magnesium carbonates, typically in sedimentary rocks of various geological formations. Limestone serves as a fundamental raw material for the cement industry and is essential for smelting iron ore in blast furnaces [7](#page=7).
> **Tip:** Understanding the geographical distribution of mineral resources, as highlighted by the example of Chota Nagpur being a mineral storehouse, is key to comprehending resource management and economic geography [7](#page=7).
### 5.3 Conservation of energy resources
Energy is a fundamental requirement for economic development, underpinning all sectors including agriculture, industry, transport, and domestic use. Economic development plans implemented since India's independence have necessitated a continuous increase in energy consumption, leading to a steady rise in its use across the country [14](#page=14).
Given this escalating demand and the finite nature of many energy sources, there is an urgent need to adopt a sustainable approach to energy development. This involves two primary strategies: promoting energy conservation and increasing the utilization of renewable energy sources [14](#page=14).
India currently ranks among the least energy-efficient countries globally. Therefore, a cautious approach to the judicious use of limited energy resources is imperative. Individuals can contribute by opting for public transport, switching off electricity when not in use, employing power-saving devices, and utilizing non-conventional energy sources. The principle that "energy saved is energy produced" underscores the importance of conservation [14](#page=14).
#### 5.3.1 Renewable energy sources
* **Tidal Energy:** Harnesses the power of oceanic tides by building floodgate dams across inlets. During high tide, water enters and is trapped; as the tide recedes, the retained water flows back through turbines to generate electricity. India has ideal locations for tidal energy utilization in the Gulf of Khambhat and the Gulf of Kuchchh in Gujarat, as well as the Gangetic delta in the Sunderban regions of West Bengal [14](#page=14).
* **Geothermal Energy:** Refers to the heat and electricity generated from the Earth's interior. This energy is available due to progressively increasing temperatures with depth. In areas with a high geothermal gradient, groundwater absorbs heat from rocks and becomes hot, turning into steam that can drive turbines. India has numerous hot springs with potential for electricity generation. Two experimental projects are operational: one in the Parvati valley near Manikaran, Himachal Pradesh, and another in the Puga Valley, Ladakh [14](#page=14).
---
## Common mistakes to avoid
- Review all topics thoroughly before exams
- Pay attention to formulas and key definitions
- Practice with examples provided in each section
- Don't memorize without understanding the underlying concepts
Glossary
| Term | Definition |
|------|------------|
| Mineral | A homogenous, naturally occurring substance with a definable internal structure, found in varied forms from hard to soft. |
| Ore | An accumulation of any mineral mixed with other elements, where the mineral content is sufficiently concentrated for commercially viable extraction. |
| Veins | Small occurrences of minerals found in the cracks, crevices, faults, or joints of igneous and metamorphic rocks. |
| Lodes | Larger occurrences of minerals found in the cracks, crevices, faults, or joints of igneous and metamorphic rocks. |
| Placer Deposits | Alluvial deposits found in sands of valley floors and the base of hills, generally containing minerals not corroded by water, such as gold, silver, tin, and platinum. |
| Ferrous Minerals | Minerals that contain iron and account for a significant portion of the production of metallic minerals, providing a base for metallurgical industries. |
| Non-Ferrous Minerals | Minerals that do not contain iron but are vital for various metallurgical, engineering, and electrical industries, including copper, bauxite, lead, zinc, and gold. |
| Bauxite | A clay-like substance from which alumina and aluminium are obtained, formed by the decomposition of rocks rich in aluminium silicates. |
| Mica | A mineral composed of plates or leaves that easily split into thin sheets, valued for its dielectric strength, low power loss factor, and insulating properties in electric and electronic industries. |
| Limestone | A rock mineral found in association with calcium carbonates or calcium and magnesium carbonates, serving as a basic raw material for the cement industry and for smelting iron ore. |
| Coal | A combustible black or brownish-black sedimentary rock, formed from the remains of plants over millions of years, used extensively for power generation and industrial energy. |
| Peat | An early stage of coal formation, produced by decaying plants in swamps, characterized by low carbon, high moisture, and low heating capacity. |
| Lignite | A low-grade brown coal that is soft and has a high moisture content, with principal reserves found in Neyveli, Tamil Nadu, used for electricity generation. |
| Bituminous Coal | A type of coal formed from buried plant material subjected to increased temperatures, it is the most popular coal in commercial use and includes metallurgical coal for smelting iron. |
| Anthracite | The highest quality and hardest form of coal. |
| Petroleum | Also known as mineral oil, it is a major energy source providing fuel for heat, lighting, lubricants, and raw materials for manufacturing industries. |
| Natural Gas | A gaseous mixture, often found with petroleum deposits, used as domestic and industrial fuel, in the power sector, and as a raw material in various industries. |
| Hydro Electricity | Electricity generated by running water that drives hydro turbines, a renewable energy source. |
| Thermal Power | Electricity generated by burning fossil fuels like coal, petroleum, and natural gas to drive turbines. |
| Nuclear Energy | Energy obtained by altering the structure of atoms, releasing heat used to generate electric power, typically using Uranium and Thorium. |
| Solar Energy | Energy derived from sunlight, which can be tapped using photovoltaic technology to convert sunlight directly into electricity. |
| Wind Power | Energy generated from the kinetic energy of wind, used to drive turbines, with significant potential in coastal areas. |
| Tidal Energy | Energy generated from the ebb and flow of oceanic tides, where water is trapped and released through turbines. |
| Geothermal Energy | Energy derived from the heat within the Earth's interior, used to heat groundwater which turns into steam to drive turbines. |
| Conventional Sources of Energy | Energy sources that have been traditionally used, including firewood, cattle dung cake, coal, petroleum, natural gas, and electricity from hydel and thermal power. |
| Non-Conventional Sources of Energy | Renewable energy sources that are being increasingly utilized to reduce dependence on fossil fuels, such as solar, wind, tidal, geothermal, biogas, and atomic energy. |
| Conservation of Minerals | The careful and planned use of mineral resources to ensure their availability for future generations, involving improved technologies, recycling, and the use of substitutes. |
| Conservation of Energy Resources | The judicious use and efficient management of energy resources, coupled with the promotion of renewable energy sources, to ensure sustainable development. |