What definitions do I need to know for AS Physics?

AS Physics (9702) requires precise definitions for key terms across all 11 topics including: displacement, velocity, acceleration, momentum, force, work, power, potential difference, EMF, and more. Examiners award marks for exact wording, so learning definitions precisely is essential.

How should I learn physics definitions?

Focus on the key components of each definition. For example, 'potential difference' must include 'energy transferred per unit charge'. Use flashcards, write definitions from memory, and check against the correct wording. Many students lose marks by giving vague or incomplete definitions.

AS Physics Definitions

Cambridge AS Physics (9702) | 101 Key Terms

Topics 1-11 | Syllabus 2025-2027

Why Definitions Matter

Examiners award marks for precise wording. Saying "velocity is speed with direction" loses marks - you must say "rate of change of displacement". Learn these definitions exactly as written.

Jump to Topic:

1. Physical 2. Kinematics 3. Dynamics 4. Forces, 5. Work, 6. Deformation 7. Waves 8. Superposition 9. Electricity 10. DC 11. Particle

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1. Physical Quantities and Units

Scalar quantity: A quantity that has magnitude only.

Vector quantity: A quantity that has both magnitude and direction.

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1. Physical Quantities and Units (7 terms)

Scalar quantity

A quantity that has magnitude only.

Examples: mass, speed, energy, temperature, distance

Vector quantity

A quantity that has both magnitude and direction.

Examples: displacement, velocity, force, momentum, acceleration

SI base units

The fundamental units from which all other units are derived: kilogram (kg), metre (m), second (s), ampere (A), kelvin (K).

Systematic error

An error that causes readings to be shifted consistently in one direction (all too high or all too low) from the true value.

Cannot be reduced by averaging; must be eliminated by correcting the technique

Random error

An error that causes readings to scatter around the true value with no pattern.

Can be reduced by averaging multiple readings

Precision

A measure of how close repeated measurements are to each other.

High precision = low scatter in readings

Accuracy

A measure of how close a measurement is to the true value.

Can be accurate but not precise, or precise but not accurate

2. Kinematics (6 terms)

Displacement

The distance moved in a specified direction from a reference point.

Vector quantity; can be positive or negative

Speed speed = distance / time

The rate of change of distance travelled.

Scalar quantity

Velocity v = Δs / Δt

The rate of change of displacement.

Vector quantity; includes direction

Acceleration a = Δv / Δt

The rate of change of velocity.

Vector quantity; can be negative (deceleration)

Uniform acceleration

Constant acceleration, where velocity changes by equal amounts in equal time intervals.

Free fall

Motion under gravity with no other forces acting (no air resistance).

Acceleration = g = 9.81 m s⁻²

3. Dynamics (11 terms)

Mass

The property of an object that resists change in motion (inertia).

Scalar quantity; measured in kg

Linear momentum p = mv

The product of mass and velocity.

Vector quantity; unit: kg m s⁻¹

Force F = Δp / Δt

The rate of change of momentum.

For constant mass: F = ma

Newton's first law

An object remains at rest or continues with constant velocity unless acted upon by a resultant force.

Newton's second law F = Δp/Δt = ma

The resultant force on an object is proportional to its rate of change of momentum (and is in the same direction).

Newton's third law

When body A exerts a force on body B, body B exerts an equal and opposite force on body A.

Forces are same type, act on different bodies

Weight W = mg

The gravitational force acting on an object, equal to the product of its mass and the acceleration of free fall.

Terminal velocity

The constant velocity reached when the drag force on a falling object equals its weight, so there is no net force and no acceleration.

Principle of conservation of momentum

The total momentum of a system remains constant provided no external resultant force acts on the system.

Elastic collision

A collision in which both momentum and kinetic energy are conserved.

Relative speed of approach = relative speed of separation

Inelastic collision

A collision in which momentum is conserved but kinetic energy is not conserved.

Some KE is converted to other forms (heat, sound, deformation)

4. Forces, Density and Pressure (10 terms)

Centre of gravity

The single point where the entire weight of an object may be considered to act.

Moment of a force M = F × d

The product of the force and the perpendicular distance from the pivot to the line of action of the force.

Unit: N m

Couple

A pair of equal and opposite forces acting on an object that produces rotation only (no translation).

Torque of a couple τ = F × d

The product of one of the forces and the perpendicular distance between the lines of action of the forces.

Principle of moments

For a body in rotational equilibrium, the sum of clockwise moments about any point equals the sum of anticlockwise moments about that point.

Equilibrium

A state where there is no resultant force and no resultant torque acting on a body.

Object is either at rest or moving with constant velocity

Density ρ = m / V

Mass per unit volume.

Unit: kg m⁻³

Pressure p = F / A

Force per unit area acting perpendicular to a surface.

Unit: Pa (pascal) = N m⁻²

Hydrostatic pressure Δp = ρgΔh

The pressure at a point in a fluid due to the weight of fluid above it.

Upthrust F = ρgV

The upward force on an object submerged in a fluid, equal to the weight of fluid displaced.

Archimedes' principle

5. Work, Energy and Power (6 terms)

Work done W = F × s

The product of force and displacement in the direction of the force.

Unit: joule (J) = N m

Principle of conservation of energy

Energy cannot be created or destroyed; it can only be transferred from one form to another.

Kinetic energy Eₖ = ½mv²

The energy an object has due to its motion.

Gravitational potential energy ΔEₚ = mgΔh

The energy an object has due to its position in a gravitational field.

In a uniform field near Earth's surface

Power P = W / t = E / t

The rate of doing work, or the rate of energy transfer.

Unit: watt (W) = J s⁻¹

Efficiency η = (useful output / total input) × 100%

The ratio of useful energy output to total energy input, expressed as a percentage.

6. Deformation of Solids (10 terms)

Hooke's law F = kx

The extension of a spring is directly proportional to the applied force, provided the limit of proportionality is not exceeded.

Spring constant k = F / x

The force per unit extension of a spring.

Unit: N m⁻¹

Limit of proportionality

The point beyond which the extension is no longer proportional to the applied force.

Elastic limit

The maximum stress that can be applied to a material before it becomes permanently deformed.

Elastic deformation

Deformation where the material returns to its original shape when the force is removed.

Plastic deformation

Permanent deformation where the material does not return to its original shape when the force is removed.

Stress σ = F / A

Force per unit cross-sectional area.

Unit: Pa (pascal)

Strain ε = ΔL / L

Extension per unit original length.

No unit (ratio)

Young modulus E = σ / ε = (F/A) / (ΔL/L)

The ratio of stress to strain for a material.

Unit: Pa; measure of stiffness

Elastic potential energy Eₚ = ½Fx = ½kx²

The energy stored in a deformed material within its limit of proportionality.

7. Waves (13 terms)

Progressive wave

A wave that transfers energy from one place to another.

Displacement (wave)

The distance moved by a particle from its equilibrium position.

Amplitude

The maximum displacement of a particle from its equilibrium position.

Period T = 1 / f

The time taken for one complete oscillation.

Unit: second (s)

Frequency f = 1 / T

The number of complete oscillations per unit time.

Unit: hertz (Hz)

Wavelength

The minimum distance between two points oscillating in phase.

Symbol: λ; Unit: metre (m)

Phase difference

The fraction of a cycle by which one wave leads or lags another, expressed in degrees or radians.

Wave speed v = fλ

The distance travelled by a wave per unit time.

Intensity I = P / A

Power per unit area perpendicular to the direction of wave travel.

Unit: W m⁻²; I ∝ A² (amplitude squared)

Transverse wave

A wave in which the oscillations are perpendicular to the direction of energy transfer.

Examples: light, water waves, waves on a string

Longitudinal wave

A wave in which the oscillations are parallel to the direction of energy transfer.

Examples: sound waves

Polarisation

The restriction of oscillations to a single plane perpendicular to the direction of wave travel.

Only transverse waves can be polarised

Doppler effect

The change in observed frequency when there is relative motion between the source and observer.

8. Superposition (10 terms)

Principle of superposition

When two or more waves meet at a point, the resultant displacement is the vector sum of the individual displacements.

Interference

The superposition of two or more waves resulting in a new wave pattern.

Constructive interference

Superposition where waves are in phase, producing a resultant wave with greater amplitude.

Destructive interference

Superposition where waves are in antiphase (180° out of phase), producing a resultant wave with smaller amplitude.

Coherence

When two sources emit waves with a constant phase difference.

Required for observable interference pattern

Path difference

The difference in distance travelled by two waves from their sources to a given point.

Stationary (standing) wave

A wave pattern formed by the superposition of two progressive waves of the same frequency travelling in opposite directions.

Node

A point on a stationary wave where the amplitude is always zero.

Antinode

A point on a stationary wave where the amplitude is maximum.

Diffraction

The spreading of a wave as it passes through a gap or around an obstacle.

9. Electricity (7 terms)

Electric current I = Q / t

The rate of flow of electric charge.

Unit: ampere (A)

Charge Q = It

The product of current and time.

Unit: coulomb (C)

Potential difference V = W / Q

The energy transferred per unit charge between two points.

Unit: volt (V) = J C⁻¹

Resistance R = V / I

The ratio of potential difference across a component to the current through it.

Unit: ohm (Ω)

Ohm's law

The current through a conductor is proportional to the potential difference across it, provided physical conditions (e.g., temperature) remain constant.

Resistivity ρ = RA / L

The resistance of a material of unit length and unit cross-sectional area.

Unit: Ω m

Electrical power P = VI = I²R = V²/R

The rate of energy transfer in an electrical component.

Unit: watt (W)

10. DC Circuits (7 terms)

Electromotive force (EMF) ε = W / Q

The energy transferred per unit charge by a source in driving charge around a complete circuit.

Unit: volt (V)

Internal resistance

The resistance within a source of EMF that causes energy to be dissipated inside the source.

Terminal potential difference V = ε - Ir

The potential difference across the terminals of a source, equal to EMF minus the voltage dropped across internal resistance.

Kirchhoff's first law

The sum of currents entering a junction equals the sum of currents leaving it.

Based on conservation of charge

Kirchhoff's second law

The sum of EMFs around any closed loop equals the sum of potential differences around that loop.

Based on conservation of energy

Potential divider

A circuit that uses resistors to divide a voltage into smaller parts.

Potentiometer

A device for comparing potential differences using a null method (zero current through galvanometer).

11. Particle Physics (14 terms)

Nucleon number (A)

The total number of protons and neutrons in a nucleus.

Also called mass number

Proton number (Z)

The number of protons in a nucleus.

Also called atomic number; defines the element

Isotopes

Atoms of the same element with the same proton number but different nucleon numbers (different number of neutrons).

Unified atomic mass unit (u)

A unit of mass equal to 1/12 of the mass of a carbon-12 atom.

1 u = 1.66 × 10⁻²⁷ kg

Antiparticle

A particle with the same mass as its corresponding particle but opposite charge.

e.g., positron is antiparticle of electron

Alpha (α) radiation

A helium nucleus (2 protons + 2 neutrons) emitted from an unstable nucleus.

Charge: +2e; Mass: 4u

Beta-minus (β⁻) radiation

A high-energy electron emitted from a nucleus when a neutron converts to a proton.

Also emits an electron antineutrino

Beta-plus (β⁺) radiation

A positron emitted from a nucleus when a proton converts to a neutron.

Also emits an electron neutrino

Gamma (γ) radiation

High-energy electromagnetic radiation emitted from an excited nucleus.

No charge, no mass

Quark

A fundamental particle that combines to form hadrons. Six flavours: up, down, strange, charm, top, bottom.

Lepton

A fundamental particle that does not experience the strong nuclear force.

Includes electrons and neutrinos

Hadron

A particle made of quarks that experiences the strong nuclear force.

Includes baryons and mesons

Baryon

A hadron made of three quarks.

e.g., proton (uud), neutron (udd)

Meson

A hadron made of one quark and one antiquark.

e.g., pion, kaon

More AS Physics Resources

AS Formula Sheet Past Papers Revision Notes

LumiExams.com | Cambridge AS Physics (9702) | Syllabus 2025-2027