Heat
Heat
What you'll learn
- Difference between heat and temperature.
- How a thermometer works; types of thermometers.
- Three modes of heat transfer: conduction, convection, radiation.
- Real-world applications of each mode.
Key concepts
Heat vs Temperature
| Heat | Temperature | |
|---|---|---|
| Definition | Total thermal energy of particles in a substance | Average kinetic energy of particles |
| Unit | Joule (J) or calorie | Celsius (°C), Kelvin (K), Fahrenheit (°F) |
| Depends on | Mass, temperature, type of material | Only the state of the particles |
| Example | A bucket of hot water has more heat than a cup of hot water at the same temperature | A cup and a bucket at 80°C have the same temperature |
Temperature scales:
- Celsius (°C): water freezes at 0°C, boils at 100°C.
- Fahrenheit (°F): F = (9/5 × C) + 32; body temperature = 98.6°F = 37°C.
- Kelvin (K): K = C + 273; used in science.
Thermometers
- Thermometer: instrument used to measure temperature.
- Uses expansion of liquid (mercury or alcohol) with temperature.
- Mercury thermometer: silver-coloured liquid; range −39°C to 357°C. (Being phased out — mercury is toxic.)
- Alcohol thermometer: coloured liquid; range −115°C to 78°C; safer.
Types:
| Type | Use | Range |
|---|---|---|
| Clinical (medical) thermometer | Measure body temperature | 35°C to 42°C; has a kink to hold reading |
| Lab thermometer | General experiments | −10°C to 110°C |
| Maximum-minimum thermometer | Record day's max and min temp | Weather stations |
| Digital thermometer | Fast, no glass/mercury; medical | Any range |
| Infrared thermometer | No-contact; measures radiation | −50°C to 380°C |
Using a clinical thermometer:
- Normal human body temperature: 37°C (98.6°F).
- Wash before/after use; kink stops mercury falling back; hold for 1–2 min in mouth/armpit.
- Read before shaking down.
Modes of Heat Transfer
1. Conduction
- Heat transfer through a solid by particle-to-particle collision.
- Particles vibrate → transfer energy to neighbours → heat moves from hot end to cold end.
- No actual movement of particles; only energy passes.
- Best conductors: metals — iron, copper, aluminium, silver (silver best; copper second best).
- Poor conductors (insulators): wood, plastic, rubber, glass, air.
Examples:
- Metal spoon gets hot when left in hot tea.
- Cooking pan handle made of plastic — poor conductor → doesn't get as hot.
- Ice packs wrapped in cloth — cloth slows conduction → stays cold longer.
- Wearing layers in winter — air trapped between layers = good insulator.
- Birds puff up feathers in cold — traps more air.
2. Convection
- Heat transfer through fluids (liquids and gases) by actual movement of particles.
- Hot fluid rises (less dense); cold fluid sinks (denser) → convection current.
Examples:
- Heating a pot of water: water at bottom heats → rises → cooler water sinks → circular current → all water heats.
- Sea breeze: daytime — land heats faster → hot air over land rises → cool air from sea blows in (sea breeze). At night, land cools faster → land breeze.
- Monsoons in India: heating of land vs ocean creates large-scale convection.
- Hot air balloons: hot air inside is less dense → balloon rises.
- Ventilators placed near ceiling — hot air rises and escapes through ventilator.
- Room heater placed at floor level — heats air → rises → sets up convection current → heats whole room.
3. Radiation
- Heat transfer by electromagnetic waves (infrared radiation) without needing any medium.
- Can travel through vacuum; does NOT require particles.
- All objects emit radiation; hotter objects emit more.
Factors affecting radiation:
- Colour and surface:
- Black/dark, rough surfaces absorb and emit radiation BEST.
- White/shiny, smooth surfaces absorb and emit radiation LEAST (reflect most).
Examples:
- Earth receives heat from Sun (through vacuum of space) — only by radiation.
- Sitting near a campfire — feel warm even without touching (radiation, not conduction/convection).
- Solar cookers — black painted inner surface absorbs maximum radiation.
- Wearing white/light clothes in summer — reflects radiation, stays cooler.
- Thermos flask (vacuum flask): vacuum stops conduction and convection; silvered walls reduce radiation.
- Greenhouses: glass allows visible light in but traps infrared (radiation) — keeps plants warm.
Comparison of modes
| Feature | Conduction | Convection | Radiation |
|---|---|---|---|
| Medium needed | Yes (solid best) | Yes (fluid) | No — even in vacuum |
| Particle movement | No (vibrations only) | Yes | No |
| Speed | Slowest | Medium | Fastest (speed of light) |
| Main medium | Solids | Liquids and gases | Any/vacuum |
| Example | Metal rod heating | Boiling water | Sunlight reaching Earth |
Quick check
- What is the difference between heat and temperature?
- Normal body temperature is 37°C. Convert to Fahrenheit.
- Explain why a metal rod feels hotter to touch than a wooden table at the same temperature.
- Why are ventilators placed near the ceiling of rooms?
- Explain how a thermos flask reduces heat loss by all three modes of heat transfer.
Open the Practice tab for graded questions on Heat.
3 topics • Notes • Practice • AI explanations available
1. Thermometer
Read notes & practice →
2. Conduction
Read notes & practice →
3. Radiation
Read notes & practice →
For generative engines & students
Every topic page delivers structured HTML (headings, lists, tables, takeaways) in the first response. Perfect for citations in AI overviews and fast scanning by students and parents.
