Latent Heat Formula: Definition, Concepts, Types, Fusion, Vaporization and Solved Examples | CollegeSearch

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Latent Heat Formula: Definition, Formula, Types, Fusion, Vaporization and Facts

Kasturi Talukdar

Updated on 25th May, 2023 , 7 min read

Latent Heat Overview

Latent heat refers to the quantity of thermal energy needed for a substance to undergo a phase transition. The primary role of the Earth's atmosphere is to transfer energy in order to maintain balance between the poles and the equator. To grasp how the atmosphere sustains human life, it's essential to comprehend the mechanisms of heat exchange occurring within it. One such mechanism is the transmission of latent heat during the process of phase transition or heat exchange. This segment aims to provide an overview of latent heat, its various forms, and its significance.

Latent Heat Highlight

The table below shows the important highlights about Latent Heat:

Latent Heat Highlights

Definition:Energy emitted or absorbed by a material during a phase transition

Example: Melting of ice, boiling of water, condensation of steam

Importance: Helps regulate temperature changes, acts as energy storage, used in industrial processes, involved in weather patterns and geological processes

Unit:Joules per kilogram (J/kg) or calories per gram (cal/g)

Formula: L = Q / M,where Q is the heat absorbed or released, m is the mass of the substance, and L is the latent heat

What is Latent Heat?

Latent heat refers to the amount of thermal energy that is absorbed or released by a substance during a phase transition without any change in temperature. It is the energy that is required to change the state of a substance from one phase to another, such as from a solid to a liquid (melting), liquid to a gas (evaporation), or a gas to a liquid (condensation), or a liquid to a solid (freezing). During these phase transitions, the energy is either absorbed or released by the substance in the form of latent heat.

Examples of Latent Heat

  1. The melting of ice requires the absorption of latent heat of fusion to change it from a solid to a liquid state.
  2. When water boils, it absorbs the latent heat of vaporization to transform into steam.
  3. During the process of freeze-drying, food is dehydrated by sublimation, where the latent heat of sublimation is absorbed to remove water from the food.
  4. The formation of dew on grass or the production of rain in the atmosphere releases latent heat of condensation as water vapor condenses into liquid droplets.
  5. The cooling effect of sweating occurs due to the evaporation of sweat from the skin, which absorbs the latent heat of vaporization from the body, helping to regulate body temperature.

Latent Heat Formula

Latent heat is the quantity of heat needed per kilogramme to alter the state of an object in physics.

The MKS (meter-kilogram-second) method uses joules per kilogramme (J/kg) as its units.

The specific latent heat (L) of a substance is a measurement of the thermal energy (Q) released or absorbed per mass (m) during a phase change.

Mathematically, 

L = Q / M

Where,

  • L = specific latent heat of a substance
  • Q = amount of heat
  • M = mass of the substance

This equation describes the amount of heat Q that must be added or withdrawn in order for a mass m item to change phases. L records the object's particular latent heat.

Types of Latent Heat

The table below shows the types of latent heat with examples:

Type of Latent Heat

Description

Example

Area of Application

Latent Heat of Fusion

The energy required to change a substance from a solid to a liquid state.

The melting of ice into water.

  1. Metallurgy: Used in metal casting to control the cooling rate and improve the properties of the metal.
  2. Refrigeration: Used to freeze food and preserve it for longer periods of time.
  3. Geology: Helps explain the formation of rocks and minerals from magma or lava.
   
 

Latent Heat of Vaporization

The energy required to change a substance from a liquid to a gaseous state.

The boiling of water to produce steam.

  1. Power Generation: Used in steam turbines to generate electricity.
  2. Industrial Processes: Used in distillation and drying processes.
  3. Weather and Climate: Contributes to atmospheric energy and drives weather phenomena such as hurricanes and thunderstorms.
   
 

Latent Heat of Sublimation

The energy required to change a substance from a solid directly to a gaseous state, without passing through the liquid state.

The sublimation of dry ice (solid carbon dioxide) into carbon dioxide gas.

  1. Chemistry: Used in sublimation-based purification techniques for chemicals and compounds.
  2. Food Preservation: Used in freeze-drying to preserve food for long-term storage.
  3. Space Exploration: Used to store and transport essential supplies such as water and oxygen in solid form.
   
 

Latent Heat of Condensation

The energy released when a substance changes from a gaseous to a liquid state.

The formation of dew on grass or the production of rain in the atmosphere.

  1. Weather and Climate: Plays a critical role in the water cycle and is responsible for the formation of rain, snow, and other forms of precipitation.
  2. Air Conditioning: Used to dehumidify and cool the air by removing moisture from it.
  3. Materials Science: Used in the production of thin films and coatings through the process of chemical vapor deposition.

Applications of Latent Heat

Latent heat plays a crucial role in various natural and industrial processes, including:

  1. Climate and Weather: Latent heat is a significant contributor to atmospheric energy, which powers various weather phenomena such as hurricanes, thunderstorms, and tornadoes.
  2. Energy Production: Latent heat is used in the production of electricity through steam turbines, where water is heated to produce steam that drives the turbines.
  3. Refrigeration and Air Conditioning: Latent heat is used in refrigeration and air conditioning systems to cool and dehumidify the air.
  4. Materials Processing: Latent heat is used in materials processing, such as casting and solidification, to control the cooling rate and improve the material's properties.

Read more about the Efficiency Formula.

Importance of Latent Heat

Latent heat refers to the energy that is emitted or absorbed by a material during a phase transition. The amount of latent heat involved in condensation, evaporation, freezing, and melting depends on the temperature and pressure of the material. 

  1. Temperature regulation: Latent heat helps to regulate temperature changes in substances during phase changes. When a substance undergoes a phase change, it either absorbs or releases latent heat, which helps to maintain a constant temperature.
  2. Energy storage: Latent heat acts as a form of energy storage. During a phase change, energy is absorbed or released as latent heat, which can be used later on for different applications.
  3. Industrial processes: The concept of latent heat is used in various industrial processes like refrigeration, drying, distillation, and chemical processing, among others. For example, in refrigeration, the latent heat of vaporization is used to extract heat from the surroundings, while in drying, the latent heat of evaporation is used to remove moisture from the product.
  4. Weather and climate: Latent heat is a key factor in the formation of weather patterns, including the development of thunderstorms, hurricanes, and other forms of precipitation. The energy released during the condensation of water vapor is responsible for driving these phenomena.
  5. Geological processes: Latent heat is also involved in geological processes like the formation of rocks and minerals from magma or lava. As magma cools and solidifies, it releases latent heat of fusion, which helps to determine the structure and properties of the resulting rock.

Latent Heat: Things to Remember

  1. The amount of heat energy needed per mass unit for a phase transition to occur is referred to as latent heat.
  2. The measure of latent heat in the MKS (meter-kilogram-second) system is joules per kilogramme (J/kg).
  3. Latent Heat can be stated mathematically as L = Q / M. Where L is a substance's specific latent heat, Q is the quantity of heat, and M is the substance's mass.
  4. Every phase transition occurs at a particular temperature and pressure.
  5. During a phase change, there is no difference in temperature.
  6. Latent heat can be absorbed or discharged.
  7. Endothermic phase transitions absorb heat from the surroundings.
  8. During exothermic phase transitions, heat is released into the atmosphere.
  9. The latent heat of fusion represents the shift from liquid to solid.
  10. Latent heat of vaporization represents the change from a liquid to a gas.
  11. The latent heat of sublimation represents the shift from solid to gas.

Also Read: 

Latent Heat: Sample Questions

What is latent heat?

Answer:Latent heat refers to the amount of energy that is either absorbed or released by a substance during a phase transition without a change in temperature.

What is the unit of latent heat?

Answer:The unit of latent heat is joules per kilogram (J/kg) or calories per gram (cal/g).

How does latent heat affect weather and climate?

Answer:Latent heat plays a vital role in weather and climate patterns as it is involved in the formation of clouds, precipitation, and atmospheric circulation.

What is the formula for calculating latent heat?

Answer:The formula for calculating latent heat is Q = mL, where Q is the heat absorbed or released, m is the mass of the substance, and L is the latent heat.

What is the difference between latent heat of fusion and latent heat of vaporization?

Answer:Latent heat of fusion is the energy required to change a solid to a liquid or vice versa, while latent heat of vaporization is the energy required to change a liquid to a gas or vice versa.

How is latent heat used in industrial processes?

Answer:Latent heat is used in industrial processes such as refrigeration, air conditioning, and distillation, where it acts as an energy storage mechanism.

What is the significance of latent heat in geology?

Answer:Latent heat plays a crucial role in geology as it is involved in the formation of rocks and minerals through processes such as melting and solidification.

How does latent heat affect the human body?

Answer:Latent heat plays a significant role in regulating the body temperature of humans and other animals by enabling the evaporation of sweat.

What is the importance of latent heat in energy conservation?

Answer:Latent heat can be used to store energy, thereby reducing the need for constant heating and cooling, and promoting energy conservation.

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Frequently Asked Questions

What is latent heat formula?

The formula for latent heat is Q = mL, where Q is the heat added or removed, m is the mass of the substance, and L is the substance’s latent heat.

What is the unit of latent heat?

The unit of latent heat is joules per kilogram (J/kg).

What is the difference between latent heat of fusion and latent heat of vaporization?

The latent heat of fusion is the amount of heat required to melt a solid into a liquid at constant temperature, while the latent heat of vaporization is the amount of heat required to turn a liquid into a gas at constant temperature.

How do you calculate latent heat of fusion?

The latent heat of fusion can be calculated using the formula Q = mL, where Q is the heat added or removed, m is the mass of the substance, and Lf is the substance’s latent heat of fusion.

How do you calculate latent heat of vaporization?

The latent heat of vaporization can be calculated using the formula Q = mL, where Q is the heat added or removed, m is the mass of the substance, and Lv is the substance’s latent heat of vaporization.

What is the importance of latent heat?

The importance of latent heat lies in the fact that it plays a crucial role in the physical changes of matter. Latent heat is required for phase transitions such as melting, freezing, vaporization, and condensation.

What are some examples of latent heat?

Some examples of latent heat include the melting of ice, boiling of water, and the process of condensation.

Can latent heat be negative?

Yes, latent heat can be negative when heat is removed from a substance during a phase change. In this case, the heat energy is released, and the substance loses its latent heat.

What is the difference between specific heat and latent heat?

Specific heat is the amount of heat required to raise the temperature of a substance by one degree Celsius or Kelvin, while latent heat is the amount of heat required to change the phase of a substance at a constant temperature.

How is latent heat used in everyday life?

Latent heat is used in many everyday applications, such as air conditioning and refrigeration systems, where it is used to cool or heat a space by changing the phase of a refrigerant. It is also used in cooking, where the latent heat of evaporation is used to cook food more quickly in a pressure cooker.

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