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Summary AQA A-level Physics Paper 2 All-in-one Notes

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Summary notes on AQA A-level Physics Paper 2 , with detailed graphs and key points. Extracted from the AQA textbook. Coloured graphs and easy to understand wordings.

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  • June 8, 2024
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A LEVEL PHYSICS
PAPER 2 ALL IN ONE NOTES
AQA Physics
2024 Summer Exams




Chapter 19 Thermal Physics

Internal energy = sum of all the kinetic energies and potential energies of all its

particles

Molecular kinetic energy increases with temperature

Potential energy increases if an object changes state from solid to liquid or liquid

to gas

In gases, molecules are so far apart that there are no intermolecular interactions =>

no potential energy (too far away for forces to exist) and entirely kinetic

Heat = energy that flows from a high temperature object to a lower temperature

object

When something absorbs heat => internal energy increases ( or energy of its atoms

& molecules increase)

When something releases energy => internal energy decreases

Heating an object result in:

- Temperature changing (reason of expand or contract as molecular motion

changes)


1

, - Object changing phases (s,l,g)

Temperature = measure of degree of hotness of a substance

Heat energy normally moves from regions of higher to lower temperature

Conditions for thermal equilibrium:

- No net transfer of heat energy between two objects

- Only occur if both objects are at the same temperature

NEWTON’S FIRST LAW OF THERMODYNAMICS

Internal energy due to temperature => thermal energy

Internal energy can be increased by:

- Energy transfer by heating the object

- Work done on the object

Change in internal energy = energy gained by heating + energy gained by working

ΔU=ΔQ+ΔW

States of molecules

- Solid:

● Atoms and molecules are held together by forces due to the electrical

charges of the protons and electrons in the atoms

● Vibrate randomly about fixed positions

● Higher the temp of the solid, the more the molecules vibrate

● Energy supplied to melt a solid raises the potential energy of the molecules

as they break free from each other



2

, - Liquid:

● Molecules move about at random in contact with each other

● Forces between the molecules are not enough to hold the molecules

together in fixed positions

● Higher temp of liquid, faster the molecules move

● Energy supplied to a liquid to raise its temperature increases its kinetic

energy of the molecules => enough KE to break free and move away (gas)

- Gas or vapour:

● Molecules move randomly but much further apart on avg than liquid

● Heating cause the molecules to speed up and gain KE

Absolute Zero = lowest possible temperature where objects have minimal KE

Absolute scale of temperature: in Kelvins (K)

- Absolute Zero: 0 K => lowest possible temperature

- Triple point of water: 273.15 K => temp where three phases of water (s,l,g) co-

exist in equilibrium (allow simultaneous presence and transition between

states without any phase becoming more dominant than others)

Specific Heat Capacity = the energy needed to raise the temperature of unit mass

of the substance by 1K without change of state

Energy needed Δ Q = mc ΔT where c is the specific heat capacity

Specific Latent Heat of Fusion = energy needed to melt a solid at its melting point

Specific Latent Heat of Vaporisation = energy needed to vaporise a liquid

* without change of temperature

Q = ml


3

, Chapter 20 Gases

Pressure of a gas = force per unit area that the gas exerts normally on a surface

Unit: Pascals (Pa) = Nm^-1

Boyle’s Law

pV = constant at constant temperature

* pressure and volume are inversely proportional

Charles’ Law

V
=k at constant pressure
T

* volume is directly proportional to absolute temperature

The Pressure Law

p
=k at constant volume
T

* pressure is directly proportional to absolute temperature

Ideal Gas Law

pV = nRT



4

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