Heat

1. Introduction

Heat is a form of energy that flows from a body at higher temperature to a body at lower temperature. It is one of the most fundamental concepts in physics and plays a crucial role in our daily lives, influencing everything from weather patterns to cooking food.

Heat energy is responsible for various observable effects in matter. Understanding heat is essential not only for scientific knowledge but also for practical applications in engineering, technology, and everyday life.

Effects of Heat in Daily Life

Temperature Changes

Heating increases temperature, cooling decreases it. This affects our comfort, cooking, and industrial processes.

Expansion of Materials

Most substances expand when heated, which is considered in construction, engineering, and manufacturing.

Change of State

Heat can change solids to liquids (melting) and liquids to gases (vaporization), fundamental to many natural and industrial processes.

Heat Transfer Visualization

HOT

Higher Temperature

COLD

Lower Temperature

Heat always flows from hotter to colder objects

2. Heat and Temperature

Although often used interchangeably in everyday language, heat and temperature are distinct concepts in physics. Understanding their difference is fundamental to studying thermal physics.

Definition: Energy in transit due to temperature difference

Nature: Form of energy

Flow Direction: Always from hotter to colder body

SI Unit: Joule (J)

Depends On: Mass, specific heat, temperature change

Analogy: Like total amount of water in a container

Temperature

Definition: Degree of hotness or coldness of a body

Nature: Measure of thermal state

Flow Direction: Doesn't flow, it's a property

SI Unit: Kelvin (K)

Depends On: Average kinetic energy of particles

Analogy: Like level of water in a container

Understanding the Difference

Scenario: A cup of boiling water and a bathtub of warm water

The cup of boiling water has a higher temperature (100°C) but contains less heat energy (due to small mass)
The bathtub of warm water has a lower temperature (40°C) but contains more heat energy (due to large mass)
If you touch both, the cup feels hotter (higher temperature), but the bathtub has more total heat energy

Molecular Interpretation

Temperature: Represents the average kinetic energy of molecules in a substance
Heat: Represents the total internal energy (kinetic + potential) transferred between bodies
When temperature increases, molecular motion becomes more vigorous
Heat transfer increases the internal energy of a body, which may increase temperature or change state

Low Temperature

Slow molecular motion

High Temperature

Fast molecular motion

3. Measurement of Temperature

Temperature is measured using instruments called thermometers. Different temperature scales have been developed for various applications, each with its own reference points and unit divisions.

Common Types of Thermometers

Clinical Thermometer

Measures body temperature (35°C to 42°C)

Laboratory Thermometer

Measures general temperatures (-10°C to 110°C)

Digital Thermometer

Electronic temperature measurement

Common Temperature Scales

Celsius Scale (°C)

Inventor: Anders Celsius (1742)

Reference Points:

0°C: Freezing point of water
100°C: Boiling point of water

Usage: Most countries except USA, scientific work

Fahrenheit Scale (°F)

Inventor: Daniel Fahrenheit (1724)

Reference Points:

32°F: Freezing point of water
212°F: Boiling point of water

Usage: USA, some Caribbean countries

Kelvin Scale (K)

Inventor: Lord Kelvin (1848)

Reference Points:

0 K: Absolute zero (-273.15°C)
273.15 K: Freezing point of water
373.15 K: Boiling point of water

Usage: Scientific work (SI unit)

Temperature Scale Conversions

Celsius to Kelvin:

K = °C + 273

Kelvin to Celsius:

°C = K - 273

Celsius to Fahrenheit:

°F = (9/5 × °C) + 32

Fahrenheit to Celsius:

°C = 5/9 × (°F - 32)

Example: Temperature Conversions

Problem: Convert 25°C to Kelvin and Fahrenheit.

Solution:

To Kelvin: K = °C + 273 = 25 + 273 = 298 K
To Fahrenheit: °F = (9/5 × °C) + 32 = (9/5 × 25) + 32 = 45 + 32 = 77°F

Result: 25°C = 298 K = 77°F

Absolute Zero

Definition: The lowest possible temperature where molecular motion theoretically stops
Value: 0 K = -273.15°C = -459.67°F
Significance: All thermal motion ceases; it's impossible to reach absolute zero in practice
In Kelvin scale: No negative values; all temperatures are positive

4. Effects of Heat

When heat is supplied to a substance, it can produce various observable effects. These effects form the basis for understanding thermal phenomena and have numerous practical applications.

1

Rise in Temperature

Description: Increase in the degree of hotness of a body

Molecular Explanation: Heat energy increases the kinetic energy of molecules, making them move faster

Quantified by: Specific heat capacity (amount of heat needed to raise temperature)

Examples: Water heating on stove, metal getting hot in sun

2

Expansion of Substances

Description: Increase in dimensions (length, area, volume) when heated

Molecular Explanation: Increased molecular motion causes molecules to occupy more space

Quantified by: Coefficients of linear, areal, and volume expansion

Examples: Railway tracks expand in summer, hot air balloons rise

3

Change of State

Description: Transformation from one state of matter to another

Molecular Explanation: Heat overcomes intermolecular forces, allowing change in arrangement

Quantified by: Latent heat (heat needed for state change without temperature change)

Examples: Ice melting, water boiling, dry ice subliming

Visualizing Heat Effects

Temperature Rise

Small

Expansion

Solid

Heat

Liquid

State Change

Other Effects of Heat (Beyond Basics)

Chemical Changes: Heat can cause chemical reactions (cooking, combustion)
Electrical Effects: Heating can change electrical resistance (used in thermistors)
Biological Effects: Heat affects biological processes (enzyme activity, metabolism)
Optical Effects: Heat can change refractive index (mirage formation)
Mechanical Effects: Thermal stress can cause cracks in materials

5. Expansion Due to Heat

Most substances expand when heated and contract when cooled. This property, known as thermal expansion, occurs because increased thermal energy causes particles to vibrate more vigorously and occupy more space.

Types of Thermal Expansion

Linear Expansion

Definition: Increase in length when heated

Formula: ΔL = αL₀ΔT

Where:

ΔL = Change in length
α = Coefficient of linear expansion
L₀ = Original length
ΔT = Change in temperature

Example: Railway tracks, bridges

Areal Expansion

Definition: Increase in area when heated

Formula: ΔA = βA₀ΔT

Where:

ΔA = Change in area
β = Coefficient of areal expansion (β ≈ 2α)
A₀ = Original area
ΔT = Change in temperature

Example: Metal plates, glass windows

Volume Expansion

Definition: Increase in volume when heated

Formula: ΔV = γV₀ΔT

Where:

ΔV = Change in volume
γ = Coefficient of volume expansion (γ ≈ 3α)
V₀ = Original volume
ΔT = Change in temperature

Example: Liquids, gases, solids

Example: Linear Expansion Problem

Problem: A steel rail is 10 m long at 20°C. If the coefficient of linear expansion of steel is1.2 × 10⁻⁵ /°C, how much will it expand when heated to 50°C?

Solution:

Original length, L₀ = 10 m
Temperature change, ΔT = 50°C - 20°C = 30°C
Coefficient, α = 1.2 × 10⁻⁵ /°C
Expansion, ΔL = α × L₀ × ΔT
ΔL = (1.2 × 10⁻⁵) × 10 × 30
ΔL = 3.6 × 10⁻³ m = 3.6 mm

The rail will expand by 3.6 mm when heated from 20°C to 50°C.

Applications of Thermal Expansion

Railway Tracks

Gaps left between rails to allow for expansion in summer, preventing buckling.

Thermometers

Liquid (mercury/alcohol) expands in a narrow tube, showing temperature change.

Bridges

Expansion joints allow for thermal expansion and contraction.

Hot Riveting

Hot rivets contract when cooled, creating tight joints in metal structures.

Fire Alarms

Bimetallic strips bend when heated, completing circuit to trigger alarm.

Opening Jar Lids

Heating metal lid expands it more than glass, making it easier to open.

Anomalous Expansion of Water

Most substances expand when heated, but water shows anomalous behavior
From 0°C to 4°C: Water contracts (density increases)
At 4°C: Water has maximum density (1 g/cm³)
Above 4°C: Water expands normally like other liquids
Significance: Ice floats on water, aquatic life survives in winter

6. Change of State

Matter exists in three primary states: solid, liquid, and gas. Change of state refers to the transformation from one state to another when heat is added or removed. These changes occur at specific temperatures and involve energy transfer.

Solid

Properties: Fixed shape and volume

Particle Arrangement: Regular, closely packed

Motion: Vibrational only

Liquid

Properties: Fixed volume, takes container shape

Particle Arrangement: Random, less closely packed

Motion: Vibrational + rotational + translational

Gas

Properties: No fixed shape or volume

Particle Arrangement: Very far apart, completely random

Motion: High speed in all directions

Processes of State Change

Melting

Definition: Change from solid to liquid

Temperature: Melting point (fixed for pure substances)

Energy: Absorbs heat (latent heat of fusion)

Examples: Ice to water, butter melting, wax melting

Special Cases:

Gallium: Melts at 30°C (in hand)
Tungsten: Highest melting point (3422°C)

Boiling

Definition: Change from liquid to gas throughout liquid

Temperature: Boiling point (depends on pressure)

Energy: Absorbs heat (latent heat of vaporization)

Examples: Water boiling, alcohol boiling

Special Cases:

Water: Boils at 100°C at sea level
High altitude: Lower boiling point
Pressure cooker: Higher boiling point

Evaporation

Definition: Slow change from liquid to gas at surface

Temperature: Occurs at any temperature

Energy: Absorbs heat from surroundings (cooling effect)

Examples: Drying clothes, sweat cooling, puddles drying

Factors Affecting:

Temperature (increases with temperature)
Surface area (more area, faster evaporation)
Humidity (slower in humid conditions)
Wind speed (faster with wind)

Other State Changes

Process	Change	Heat	Example
Freezing	Liquid → Solid	Releases heat	Water to ice
Condensation	Gas → Liquid	Releases heat	Dew formation, clouds
Sublimation	Solid → Gas	Absorbs heat	Dry ice, naphthalene balls
Deposition	Gas → Solid	Releases heat	Frost formation

Evaporation vs Boiling

Aspect	Evaporation	Boiling
Temperature	Occurs at any temperature	Occurs at fixed boiling point
Location	Only at surface	Throughout the liquid
Rate	Slow process	Fast process
Bubbles	No bubbles formed	Bubbles formed throughout
Cooling Effect	Causes cooling	No cooling effect
Examples	Drying clothes, sweat cooling	Water boiling, cooking

7. Latent Heat

Latent heat is the heat energy required to change the state of a substance without changing its temperature. The term "latent" means "hidden" because this heat doesn't cause temperature rise but is absorbed or released during state changes.

Heating Curve of Water

Ice (-20°C)

Ice (0°C)

Water (0°C)

Water (100°C)

Steam (100°C)

Steam (120°C)

A: Heating ice

B: Melting (latent heat)

C: Heating water

D: Boiling (latent heat)

E: Heating steam

0°C

100°C

-20°C

120°C

Temperature

Observation: During state changes (B and D), temperature remains constant while heat is absorbed.

Latent Heat of Fusion

Definition: Heat required to change 1 kg of solid into liquid at its melting point without temperature change

Formula: Q = m × L_f

Where:

Q = Heat absorbed (J)
m = Mass (kg)
L_f = Latent heat of fusion (J/kg)

Examples:

Water: L_f = 3.34 × 10⁵ J/kg
Ice absorbs heat when melting
Water releases heat when freezing

Latent Heat of Vaporization

Definition: Heat required to change 1 kg of liquid into vapor at its boiling point without temperature change

Formula: Q = m × L_v

Where:

Q = Heat absorbed (J)
m = Mass (kg)
L_v = Latent heat of vaporization (J/kg)

Examples:

Water: L_v = 22.6 × 10⁵ J/kg
Water absorbs heat when boiling
Steam releases heat when condensing

Example: Latent Heat Calculation

Problem: How much heat is required to melt 2 kg of ice at 0°C? (Latent heat of fusion of ice = 3.34 × 10⁵ J/kg)

Solution:

Using formula: Q = m × L_f

Q = 2 kg × 3.34 × 10⁵ J/kg

Q = 6.68 × 10⁵ J = 668,000 J

Thus, 668,000 J of heat is needed to melt 2 kg of ice at 0°C.

Practical Implications of Latent Heat

Cooling by evaporation: Sweat evaporates using body heat, causing cooling
Refrigeration: Refrigerants absorb latent heat when evaporating
Steam burns: Steam at 100°C causes worse burns than water at 100°C because steam releases latent heat when condensing
Climate moderation: Large water bodies moderate climate due to high latent heat of water
Cooking: Food cooks faster in pressure cooker due to higher temperature of steam

8. Specific Heat Capacity

Specific heat capacity is a fundamental property of substances that determines how much heat energy is required to raise the temperature of a unit mass by one degree. Different substances have different abilities to store thermal energy.

Specific Heat Capacity Formula

Q = m × c × ΔT

Where:

Q = Heat energy supplied or removed (Joules)
m = Mass of the substance (kilograms)
c = Specific heat capacity (J/kg°C)
ΔT = Change in temperature (°C or K)

Definition of Specific Heat Capacity:

The amount of heat required to raise the temperature of 1 kg of a substance by 1°C (or 1 K).

Specific Heat Capacity of Common Substances

Substance	Specific Heat Capacity (J/kg°C)	Significance
Water	4186 (approximately 4200)	Very high; excellent for temperature regulation
Ice	2100	About half of liquid water
Aluminium	900	High for a metal; used in cookware
Iron/Steel	450	Moderate; heats up relatively quickly
Copper	385	Low; excellent conductor of heat
Lead	130	Very low; heats up very quickly
Air (at constant pressure)	1005	Moderate; affects weather patterns

Example: Specific Heat Calculation

Problem: How much heat is required to raise the temperature of 5 kg of water from 20°C to 80°C? (Specific heat of water = 4200 J/kg°C)

Solution:

Mass, m = 5 kg
Specific heat, c = 4200 J/kg°C
Temperature change, ΔT = 80°C - 20°C = 60°C
Heat required, Q = m × c × ΔT
Q = 5 × 4200 × 60
Q = 1,260,000 J = 1.26 × 10⁶ J

Thus, 1.26 million joules of heat is needed.

Significance of Water's High Specific Heat

Climate Moderation: Oceans and large water bodies absorb and release heat slowly, moderating coastal climates
Biological Importance: Helps maintain stable body temperature in organisms
Industrial Use: Used as coolant in engines and industrial processes
Cooking: Water takes time to heat up and cool down, useful in cooking
Thermal Storage: Used in solar water heaters and thermal energy storage systems

Comparing Heating of Different Materials

Scenario: Equal masses of water and copper heated with same heat source

Aspect	Water	Copper
Specific Heat	4200 J/kg°C	385 J/kg°C
Heating Rate	Slow (high specific heat)	Fast (low specific heat)
Cooling Rate	Slow to cool down	Fast to cool down
Practical Implication	Good for storing heat	Good for transferring heat

9. Transfer of Heat

Heat can be transferred from one place to another through three distinct mechanisms: conduction, convection, and radiation. Each method operates differently and is dominant in different situations and materials.

Conduction

Mechanism: Direct transfer through collisions between adjacent particles

Medium Required: Solid materials (best in metals)

Particle Movement: Particles vibrate but don't change position

Example: Metal spoon in hot soup gets hot at handle

Convection

Mechanism: Transfer by actual movement of heated substance

Medium Required: Fluids (liquids and gases)

Particle Movement: Particles move from one place to another

Example: Hot air rises, cool air sinks (room heating)

Radiation

Mechanism: Transfer by electromagnetic waves

Medium Required: No medium needed (works in vacuum)

Particle Movement: No particle movement involved

Example: Heat from Sun reaching Earth

9.1 Conduction

Conduction is the transfer of heat through a material without any net movement of the material itself. It occurs when faster-moving particles collide with slower-moving particles, transferring kinetic energy.

How Conduction Works

Heat is applied to one end of the material
Particles at the heated end gain kinetic energy and vibrate faster
These particles collide with neighboring particles, transferring energy
The process continues throughout the material
No overall movement of material occurs

Hot → Warm → Cool → Cold

Heat flows from hot to cold regions

Example: Cooking Utensils

Metal cooking utensils have metal handles that conduct heat:

Problem: Handle gets too hot to hold
Solution: Use wooden or plastic handles (poor conductors)
Principle: Metals are good conductors, wood/plastic are insulators

9.2 Convection

Convection is the transfer of heat by the actual movement of the heated substance (fluid - liquid or gas). It involves bulk movement of molecules from one place to another.

Convection Currents

Fluid near heat source gets heated
Heated fluid expands, becomes less dense
Less dense fluid rises
Cooler, denser fluid sinks to replace it
Creates a continuous circulation called convection current

Convection current cycle

Example: Sea Breeze and Land Breeze

Sea Breeze (Daytime)

Land heats up faster than sea during day
Air above land gets hot, rises
Cooler air from sea moves towards land
Breeze blows from sea to land

Land Breeze (Nighttime)

Land cools faster than sea at night
Air above sea is warmer, rises
Cooler air from land moves towards sea
Breeze blows from land to sea

9.3 Radiation

Radiation is the transfer of heat by electromagnetic waves, primarily infrared radiation. Unlike conduction and convection, radiation doesn't require any medium and can travel through vacuum.

Characteristics of Heat Radiation

Travels at speed of light (3 × 10⁸ m/s in vacuum)
Doesn't require any medium (works in space)
Can be reflected, absorbed, or transmitted
All objects above absolute zero emit thermal radiation
Amount of radiation depends on temperature (Stefan-Boltzmann law)
Dark, rough surfaces are good absorbers and emitters
Light, shiny surfaces are poor absorbers and emitters (good reflectors)

Example: Solar Energy

The Sun's energy reaches Earth through radiation:

Travels 150 million km through space (vacuum)
Takes about 8 minutes to reach Earth
Heats Earth's surface, drives weather systems
Solar panels convert this radiation to electricity

10. Good and Bad Conductors of Heat

Materials vary greatly in their ability to conduct heat. This property determines whether a material is suitable for applications requiring rapid heat transfer (conductors) or heat retention (insulators).

Good Conductors

Definition: Materials that allow heat to pass through easily

Properties:

High thermal conductivity
Usually metals
Free electrons aid heat transfer
Feel cold to touch (conduct heat away from hand)

Examples:

Silver (best conductor)
Copper
Aluminium
Iron
Gold

Uses: Cooking utensils, heat exchangers, radiators

Bad Conductors (Insulators)

Definition: Materials that don't allow heat to pass through easily

Properties:

Low thermal conductivity
Usually non-metals
No free electrons
Feel warm to touch (don't conduct heat away)

Uses: Cooking utensils, heat exchangers, radiators

Bad Conductors (Insulators)

Definition: Materials that don't allow heat to pass through easily

Properties:

Low thermal conductivity
Usually non-metals
No free electrons
Feel warm to touch (don't conduct heat away)

Examples:

Wood
Plastic
Glass
Air (when trapped)
Wool, cotton
Rubber

Uses: Handles of utensils, thermal insulation, clothing

Experiment: Comparing Conductors

Setup: Rods of different materials (copper, iron, aluminium, wood) with wax attached at ends are heated at one end.

Observation: Wax melts at different distances from heat source:

Copper: Wax melts farthest (best conductor)
Aluminium: Next best
Iron: Moderate conductor
Wood: Wax doesn't melt far (poor conductor)

Conclusion: Different materials have different thermal conductivities.

Thermal Conductivity Values

Material	Thermal Conductivity (W/mK)	Rank as Conductor
Silver	429	Best
Copper	401	Very Good
Aluminium	237	Good
Iron	80	Moderate
Glass	1.0	Poor
Wood	0.1	Very Poor
Air	0.024	Excellent Insulator

11. Practical Applications of Heat Transfer

Understanding heat transfer mechanisms allows us to design systems for heating, cooling, and insulation. These principles are applied in everyday objects, buildings, and industrial processes.

Cooking Utensils

Principle: Conduction

Metal bottoms for good heat conduction; wooden/plastic handles as insulators.

Woollen Clothes

Principle: Conduction + Convection

Wool traps air (poor conductor), reducing heat loss from body in winter.

Thermos Flask

Principle: All three methods minimized

Double walls with vacuum (stops conduction/convection); silvered surfaces (reduce radiation).

Building Insulation

Principle: Conduction + Convection

Insulating materials in walls/roofs reduce heat transfer, saving energy.

Car Radiators

Principle: Conduction + Convection

Metal fins conduct heat from engine; airflow carries heat away by convection.

Refrigerators

Principle: Conduction + Convection

Insulated walls minimize heat entry; coolant circulates absorbing heat.

Solar Water Heaters

Principle: Radiation + Conduction

Black pipes absorb solar radiation; water circulates transferring heat.

Sea Breeze

Principle: Convection

Natural cooling near coasts due to differential heating of land and sea.

House Design for Thermal Comfort

Hot Climates

Thick walls (reduce heat conduction)
Light-colored exterior (reflects radiation)
Windows with shades (block direct sunlight)
Cross ventilation (promotes cooling convection)
Insulated roofs (reduce heat entry)

Cold Climates

Double-glazed windows (trap air, reduce conduction)
Dark-colored exterior (absorbs radiation)
Insulation in walls/roofs (reduce heat loss)
South-facing windows (maximize solar gain)
Minimize air leaks (reduce convective heat loss)

12. Important Points for Examination

Examination Strategy & Tips

1

Differentiate Clearly Between Heat and Temperature

Heat: Energy in transit, measured in joules
Temperature: Degree of hotness, measured in °C or K
Heat depends on mass; temperature doesn't
Use examples to illustrate difference

2

Write Formulas with Correct Units

Heat transfer: Q = mcΔT (Joules)
Latent heat: Q = mL (Joules)
Linear expansion: ΔL = αL₀ΔT (meters)
Always include units in numerical answers
Show formula before substitution

3

Explain Processes with Examples

For conduction: Metal spoon in hot liquid
For convection: Sea breeze/land breeze
For radiation: Heat from Sun
For expansion: Railway tracks with gaps
For state change: Melting of ice, boiling of water

4

Draw Neat Diagrams When Required

Heating curve showing state changes
Convection currents (sea/land breeze)
Thermos flask construction
Clinical/laboratory thermometer
Use labels, arrows, and proper scaling

5

Understand Practical Applications

Why utensils have metal bottoms but wooden handles
Why woollen clothes keep us warm
How thermos flask works
Why gaps are left in railway tracks
Why water is used as coolant

Quick Revision Checklist

Difference between heat and temperature
Three temperature scales and conversions
Three effects of heat (temperature rise, expansion, state change)
Types of expansion (linear, areal, volume) with formulas
Processes of state change (melting, boiling, evaporation)
Latent heat (fusion and vaporization) with formulas
Specific heat capacity formula and significance
Three methods of heat transfer with examples
Good and bad conductors with examples
Practical applications of heat transfer
Anomalous expansion of water
Units of all physical quantities

Common Mistakes to Avoid

Confusing heat and temperature
Thinking evaporation occurs only at boiling point
Forgetting that temperature remains constant during state change
Mixing up the three methods of heat transfer
Not writing units in numerical answers
Confusing good and bad conductors
Forgetting anomalous expansion of water
Not differentiating between evaporation and boiling

Important Formulas to Remember

Heat Transfer:

Q = m × c × ΔT

Latent Heat:

Q = m × L

Linear Expansion:

ΔL = α × L₀ × ΔT

Temperature Conversion:

K = °C + 273

Heat Capacity:

c = Q / (m × ΔT)

Volume Expansion:

ΔV = γ × V₀ × ΔT