What formulas do I need to memorize for IGCSE Physics?

IGCSE Physics (0625) requires you to know approximately 37 formulas covering motion (v=d/t, a=Δv/t), forces (F=ma, W=mg), energy (KE=½mv², GPE=mgh), electricity (V=IR, P=IV), waves (v=fλ), and more. Some formulas are given in the exam, but you should memorize the core equations.

Are formulas provided in the IGCSE Physics exam?

Yes, Cambridge provides a formula sheet in the IGCSE Physics exam with some equations. However, not all formulas are provided, so you need to memorize key equations like v=d/t, F=ma, V=IR, and energy formulas. Our formula sheet highlights which ones you must memorize.

How do I use this IGCSE Physics formula sheet?

1) Enter your email to unlock the full formula sheet. 2) Click 'Download as PDF' or use Ctrl+P to print. 3) Use the color-coded sections to find formulas by topic. 4) Review the memory tips for each formula. 5) Practice with our worked examples page for step-by-step solutions.

What topics are covered in this Physics formula sheet?

The formula sheet covers all 12 IGCSE Physics topics: Motion, Mass/Weight/Density, Forces, Momentum, Energy/Work/Power, Pressure, Thermal Physics, Waves & Light, Electricity, Resistance & Circuits, Transformers, and Space Physics.

IGCSE Physics Formula Sheet

Cambridge IGCSE Physics (0625) | All 37 Required Equations

Based on official Cambridge syllabus 2023-2025

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Practice Problems

1. Motion

v = d / t

Speed = distance / time
v = Speed (m/s)
d = Distance (m)
t = Time (s)
Tip: "How far per second?"

a = (v - u) / t

Acceleration = change in velocity / time
a = Acceleration (m/s²)
v = Final velocity (m/s)
u = Initial velocity (m/s)
t = Time (s)

2. Mass, Weight & Density

W = m × g

Weight = mass × gravitational field strength
W = Weight (Newtons)
m = Mass (kg)
g = Gravitational field strength (9.8 N/kg on Earth)

ρ = m / V

Density = mass / volume
ρ (rho) = Density (kg/m³ or g/cm³)
m = Mass (kg)
V = Volume (m³)

3. Forces

F = m × a

Force = mass × acceleration (Newton's 2nd Law)
F = Force (Newtons)
m = Mass (kg)
a = Acceleration (m/s²)

k = F / x

Spring constant = force / extension (Hooke's Law)
k = Spring constant (N/m)
F = Force (Newtons)
x = Extension (metres)

M = F × d

Moment = force × perpendicular distance from pivot
M = Moment (Newton-metres, Nm)
F = Force (Newtons)
d = Distance (metres)

4. Momentum (Extended)

p = m × v

Momentum = mass × velocity
p = Momentum (kg m/s)
m = Mass (kg)
v = Velocity (m/s)

Δp = mv - mu

Change in momentum = final momentum - initial momentum
Δp = Change in momentum (kg m/s)
v = Final velocity (m/s)
u = Initial velocity (m/s)

F = Δp / t

Force = change in momentum / time
F = Force (Newtons)
Δp = Change in momentum (kg m/s)
t = Time (seconds)

Impulse = F × Δt

Impulse = force × time = change in momentum
Impulse (Newton-seconds, Ns or kg m/s)
F = Force (Newtons)
Δt = Time interval (s)

5. Energy, Work & Power

Eₖ = ½mv²

Kinetic energy = ½ × mass × velocity²
Eₖ = Kinetic Energy (Joules)
m = Mass (kg)
v = Velocity (m/s)

ΔEₚ = m × g × Δh

Gravitational PE = mass × g × change in height
Eₚ = Potential Energy (J)
m = Mass (kg)
g = 9.8 N/kg
h = Height (m)

W = F × d

Work done = force × distance moved
W = Work (Joules)
F = Force (Newtons)
d = Distance (metres)

P = W / t

Power = work done / time (or energy / time)
P = Power (Watts)
W = Work (Joules)
t = Time (seconds)

η = useful out / total in × 100%

Efficiency = useful output / total input × 100%
η (eta) = Efficiency (%), works for energy (J) or power (W)

6. Pressure

p = F / A

Pressure = force / area
p = Pressure (Pascals, Pa or N/m²)
F = Force (Newtons)
A = Area (m²)

Δp = ρ × g × Δh

Pressure in fluid = density × g × depth
Δp = Pressure change (Pa)
ρ = Density (kg/m³)
g = 9.8 N/kg
h = Depth (metres)

7. Thermal Physics

T (K) = θ (°C) + 273

Temperature conversion - Celsius to Kelvin
T = Absolute temperature (Kelvin)
θ (theta) = Temperature (°Celsius)

P₁V₁ = P₂V₂

Boyle's Law - pressure × volume = constant (at constant temperature)
P = Pressure (Pascals)
V = Volume (m³ or cm³)

ΔE = m × c × Δθ

Specific heat capacity - energy = mass × SHC × temp change
ΔE = Energy (Joules)
m = Mass (kg)
c = Specific heat capacity (J/kg°C)
Δθ = Temp change (°C)

E = m × L

Latent heat - energy = mass × specific latent heat (no temp change)
E = Energy (Joules)
m = Mass (kg)
L = Specific latent heat (J/kg)

8. Waves & Light

v = f × λ

Wave equation - speed = frequency × wavelength
v = Wave speed (m/s)
f = Frequency (Hertz, Hz)
λ (lambda) = Wavelength (metres)

f = 1 / T

Frequency = 1 / period
f = Frequency (Hertz, Hz), T = Period (seconds) - time for one complete wave

i = r

Law of reflection - angle of incidence = angle of reflection
i = Angle of incidence (degrees)
r = Angle of reflection (degrees)
Both measured from normal

n = sin i / sin r

Refractive index (Snell's Law) - n = sin(incidence) / sin(refraction)
n = Refractive index (no unit)
i = Angle of incidence
r = Angle of refraction

n = 1 / sin c

Critical angle - for total internal reflection
n = Refractive index, c = Critical angle (degrees) - angle where light reflects internally

9. Electricity

I = Q / t

Current = charge / time
I = Current (Amperes)
Q = Charge (Coulombs)
t = Time (seconds)

V = W / Q

Voltage (p.d. or e.m.f.) = energy / charge
V = Voltage (Volts)
W = Work/Energy (Joules)
Q = Charge (Coulombs)

V = I × R

Ohm's Law - voltage = current × resistance
V = Voltage (Volts)
I = Current (Amperes)
R = Resistance (Ohms, Ω)

P = I × V

Electrical power = current × voltage
P = Power (Watts)
I = Current (Amperes)
V = Voltage (Volts)

E = P × t

Electrical energy = power × time (or E = I×V×t)
E = Energy (Joules)
P = Power (Watts)
t = Time (seconds)

P = I² × R

Power loss in cables (why high voltage = less loss)
P = Power (Watts)
I = Current (Amperes)
R = Resistance (Ohms)

10. Resistance & Circuits

Rₜ = R₁ + R₂ + ...

Series resistance - total = sum of all resistances
R = Resistance (Ohms, Ω)
In series: same current flows through all

R ∝ L

Resistance ∝ length - longer wire = more resistance
R = Resistance (Ω)
L = Length (m)
Double length = double resistance

R ∝ 1/A

Resistance ∝ 1/area - thicker wire = less resistance
R = Resistance (Ω)
A = Cross-sectional area (m²)
Double area = half resistance

1/Rₜ = 1/R₁ + 1/R₂

Parallel resistance - reciprocal sum of resistances
R = Resistance (Ohms, Ω)
In parallel: same voltage across all

Vout = (R₂/Rₜ) × Vin

Potential divider - output voltage = (R₂/total R) × input voltage
V = Voltage (Volts)
Rₜ = R₁ + R₂ (total resistance in Ohms)

11. Transformers

Vₚ/Vₛ = Nₚ/Nₛ

Transformer equation - voltage ratio = turns ratio
V = Voltage (Volts)
N = Number of turns
p = primary coil, s = secondary coil

IₚVₚ = IₛVₛ

Transformer power - power in = power out (100% efficiency)
I = Current (Amperes)
V = Voltage (Volts)
Power = I × V (Watts)

12. Space Physics

v = 2πr / T

Orbital speed = circumference / orbital period
v = Orbital speed (m/s)
r = Orbital radius (metres)
T = Orbital period (seconds)

v = H₀ × d

Hubble's Law - recession speed = Hubble constant × distance
v = Recession speed (m/s)
H₀ = Hubble constant (≈2.2×10⁻¹⁸ s⁻¹)
d = Distance (metres)

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