Lithosphere -- Environmental Sciences

---

Internal structure of the Earth

Internal Structure of the Earth

The Earth’s internal structure is divided into several layers:

1. Crust:

   • Continental Crust: Thicker and less dense, composed mostly of granite.
   • Oceanic Crust: Thinner and more dense, composed mostly of basalt.
   • The crust is the outermost layer and is where we live. It varies in thickness from about 5 km (under the oceans) to about 70 km (under continents).

2. Mantle:

   • Comprises about 84% of Earth's volume.
   • Divided into the upper mantle and lower mantle.
   • Composed of silicate minerals that are rich in magnesium and iron.
   • The upper mantle includes the asthenosphere, which is semi-fluid and allows tectonic plates to move.

3. Core:

   • Outer Core: Liquid layer composed mainly of iron and nickel. It creates Earth's magnetic field through its movement.
   • Inner Core: Solid, due to the immense pressures, composed primarily of iron and nickel. It is the hottest part of the Earth.

Rock Types

Rocks are classified based on their formation processes:

1. Igneous Rocks:

   • Formed from the cooling and solidification of magma or lava.
   • Intrusive Igneous Rocks: Formed from magma that cools slowly beneath the Earth’s surface (e.g., granite).
   • Extrusive Igneous Rocks: Formed from lava that cools quickly on the Earth’s surface (e.g., basalt).

2. Sedimentary Rocks:

   • Formed from the accumulation and lithification of sediments.
   • Often contain fossils and are usually layered.
   • Examples include sandstone, limestone, and shale.

3. Metamorphic Rocks:

   • Formed from existing rocks that are subjected to heat and pressure, causing physical and chemical changes.
   • Examples include slate (from shale), marble (from limestone), and gneiss (from granite).

Soil

Soil is a natural resource composed of mineral particles, organic matter, water, and air. It forms through the weathering of rocks and the decay of organic material over time. Key aspects of soil include:

1. Soil Horizons:

   • O Horizon: Organic layer composed of decomposed leaves and organic material.
   • A Horizon (Topsoil): Rich in organic material and minerals, crucial for plant growth.
   • B Horizon (Subsoil): Accumulates minerals leached from the topsoil and contains more clay.
   • C Horizon: Consists of weathered parent material.
   • R Horizon: Unweathered bedrock.

2. Soil Composition:

   • Mineral Particles: Derived from the breakdown of rocks; classified into sand, silt, and clay based on size.
   • Organic Matter: Decomposed plant and animal material that enriches the soil.
   • Water and Air: Fill the spaces between soil particles and are essential for soil health and plant growth.

3. ==Soil Types==:

   • Sandy Soil: Drains quickly but has low nutrient retention.
   • Clay Soil: High nutrient content but poor drainage.
   • Loamy Soil: Balanced mixture of sand, silt, and clay; ideal for agriculture.

---

Solid Waste

What is solid waste?

Solid waste is the type of waste which is, well, solid in nature (duh).

Types of solid wastes

• Municipal Solid Waste (MSW):

  • Includes everyday items discarded by the public, such as household garbage, packaging, food scraps, yard waste, and broken furniture.
  • Generated from residential, commercial, and institutional sources.

• Industrial Waste:

  • Generated by manufacturing or industrial processes.
  • Includes materials such as scraps, chemicals, plastics, metals, and sludge.
  • Often contains hazardous substances requiring special disposal methods.

• Commercial Waste:

  • Produced by businesses such as retail stores, offices, restaurants, and service providers.
  • Includes packaging materials, office supplies, food waste, and old equipment.

• Agricultural Waste:

  • Generated from farming and agricultural activities.
  • Includes crop residues, manure, pesticide containers, and unused fertilizers.
  • Often biodegradable but can contain chemicals that need careful management.

• Domestic Waste:

  • Household waste similar to municipal waste but specifically from residential areas.
  • Includes food scraps, paper, plastics, glass, metals, textiles, and household hazardous waste (e.g., batteries, cleaning products).

• Pathological and Hazardous Solid Wastes:

  • Pathological Waste: Includes medical waste such as human tissues, organs, and body fluids.
  • Hazardous Waste: Waste that poses substantial or potential threats to public health or the environment, such as toxic chemicals, solvents, pesticides, and radioactive materials.

---

Recovery and Disposal methods

• Open Dumping:

  • Uncontrolled disposal of waste in open areas.
  • Can lead to environmental pollution, health hazards, and aesthetic issues.
  • Illegal in many places due to its negative impacts.

• Land Filling:

  • Controlled disposal of waste by burying it in designated areas known as landfills.
  • Modern landfills are engineered to minimize environmental impact, including lining systems to prevent leachate from contaminating groundwater and methane capture systems to reduce greenhouse gas emissions.
  • Regular monitoring and maintenance are required.

• Incineration:

  • Burning of waste materials at high temperatures to reduce volume and destroy hazardous components.
  • Can generate energy (waste-to-energy facilities) but may produce air pollutants and ash that require disposal.

• Composting:

  • Biological decomposition of organic waste (e.g., food scraps, yard waste) under controlled conditions to produce compost.
  • Compost can be used as a soil conditioner to enhance soil health and fertility.
  • Reduces the amount of organic waste sent to landfills.

• Recycling:

  • Processing of waste materials to make them suitable for reuse.
  • Includes the collection, sorting, and reprocessing of materials like paper, cardboard, glass, metals, and plastics.
  • Conserves natural resources, reduces energy consumption, and lowers greenhouse gas emissions.

---

Solid Waste Management and Control

• Hazardous and Biomedical Waste Management:

  • Hazardous Waste: Managed through special protocols to ensure safe handling, storage, treatment, and disposal to minimize risks to human health and the environment.
    • Methods include secure landfilling, incineration, chemical treatment, and bioremediation.
  • Biomedical Waste: Includes waste from hospitals, clinics, laboratories, and research facilities.
    • Requires segregation, containment, disinfection, and proper disposal to prevent infection and contamination.
    • Common methods include autoclaving, incineration, and chemical disinfection.

• Integrated Waste Management (IWM):

  • A comprehensive approach to managing solid waste that combines various methods and strategies.
  • Focuses on reducing waste generation, increasing recycling and composting, and ensuring safe disposal of remaining waste.
  • Encourages the use of a hierarchy: reduce, reuse, recycle, recover energy, and dispose as a last resort.

• Waste Minimization:

  • Strategies to reduce the amount and toxicity of waste generated.
  • Includes process modifications, resource efficiency, and product design improvements.
  • Encourages consumers and businesses to adopt sustainable practices and reduce their environmental footprint.