List of Physics Formulas

Physics is a fundamental branch of science that studies matter, its fundamental constituents, and its motion and behavior through space and time. Physics Formulas are very important during applications of various concepts of physics.

In this article, we will cover all important formulas related to physics ranging from mechanics to electromagnetism as well as thermodynamics and quantum mechanics.

List of all Physics Formula

Below is the list of all important formulas related to physics:

Physics Formulas	Formulas
Frequency Formula	F = v/λ
Kinetic Energy Formula	E = 1/2 mv2
Ohm’s Law Formula	V = I × R
Pressure Formula	P = F/A
Weight Formula	W = mg
Newton’s Second Law	F = m × a
Power Formula	P = W/t
Density Formula	P = m/V
Acceleration Formula	a = v – u/t
Average Speed Formula	S = d/t
Pendulum Formula	T = 2π√L/g
Fahrenheit Formula	F = (9/5 × °C) + 32
Work Formula	W = F × d × cosθ
Torque Formula	T = F × r × sinθ
Displacement Formula	ΔX = Xf–Xi
Mass Formula	F = m × a or m = F/a
Amplitude Formula	x = A sin (ωt + ϕ)
Tension Formula	T = mg + ma
Surface Charge Density Formula	σ = q / A
Linear Speed Formula	V(linear speed) = ΔS/ΔT
Position Formula	Δx = x2 − x1
Heat of Fusion Formula	q = m × ΔHF
Gravity Formula	F α m1m2/r2
Spring Potential Energy Formula	P.E = 1/2 k × x2
Physics Kinematics Formula	v2 = vo2 + 2a(x – xo)
DC Voltage Drop Formula	V = I × R
Hubble’s Law Formula	v = Hor
Induced Voltage Formula	e = – N(dΦB/dt)
Latent Heat Formula	L = Q / M
Wavelength Formula	λ = v/f
Gravitational Force Formula	F = G(m1m2)/R2
Potential Energy Formula	PE = mgh
Strain Energy Formula	U = Fδ / 2
Friction Force Formula	f = μN
Cell Potential Formula	Ecell = Ecathode − Eanode
Shear Modulus Formula	(shear stress)/(shear strain) = (F/A)/(x/y)
Water Pressure Formula	Water pressure = ρ g h
Refractive Index Formula	n = c/v
Centroid Formula	C = [(x1 + x2 + x3)/ 3, (y1 + y2 + y3)/ 3]

Mechanics Formulas

Few important mechanics formulas are given below:

Newton’s Second Law of Motion

F = m × a

Where:

• F is the force applied to an object,
• m is the mass of the object,
• a is the acceleration of the object.

Work-Energy Theorem

W = ΔKE

Where:

• W is the work done on an object,

• ΔKE is the change in kinetic energy.

Kinetic Energy

KE = 1/2mv²

Where:

• KE is the kinetic energy,
• m is the mass of the object,
• v is the velocity of the object.

Potential Energy (Gravitational)

PE = mgh

Where:

• PE is the potential energy,
• m is the mass,
• g is the acceleration due to gravity,
• h is the height.

Hooke’s Law (Spring Force)

F_s = −kx

Where:

• F_s is the spring force,
• k is the spring constant,
• x is the displacement from the equilibrium position.

Newton’s Law of Universal Gravitation

F = G ⋅ m₁ ⋅ m₂ / r²

Where:

• F is the gravitational force between two masses,
• G is the gravitational constant,
• m₁ and m₂ are the masses,
• r is the distance between the centers of the masses.

Kinematics Formulas

Below are some important kinematics formulas:

Displacement (s)

s = ut + 1/2 at²

Where:

• s is the displacement.
• u is the initial velocity
• a is the acceleration,
• t is the time.

Final Velocity(v)

v = u+ at

Where:

• v is the final velocity,
• u is the initial velocity,
• a is the acceleration,
• t is the time.

Kinematic Third Equation of Motion

v² = u² + 2as

Where:

• v is the final velocity,
• u is the initial velocity,
• a is the acceleration,
• s is the displacement.

Average Velocity (v)

v = Δx / Δt

Where:

• v is the average velocity.
• Δx is the displacement.
• Δt is the time interval.

Acceleration (a)

a = Δv /Δt

Where:

a is the acceleration.

Δv is the change in velocity.

Δt is the time interval.

Electricity Formulas

Few important electricity formulas are given below:

Electric Current (I)

I = Q/t

Where:

• I is the electric current (measured in Amperes, A).
• Q is the charge that passes through a given point.
• t is the time taken.

Electric Charge (Q)

Q = I × t

Where:

• Q is the electric charge (measured in Coulombs, C).
• I is the electric current.
• t is the time taken.

Ohm’s Law

V = IR

Where:

• V is the voltage,
• I is the current,
• R is the resistance.

Power

P = VI

Where:

• P is the power,
• I is the current,
• V is the voltage.

Resistance

R = ρl / A

Where:

• R is the resistance,
• ρ is resistivity,
• l is length, and
• A is area

Watt’s Law

P = I²R or P = V²/R

Where:

• R is the resistance,
• I is Current, and
• V is Voltage

Electric Energy

 P = W x T

where:

• P is power,
• W is energy, and
• T is time

Voltage

V = E / Q

where

• E is energy, and
• Q is charge

Electromagnetism Formulas

Important Electromagnetism Formulas are given below:

Electric Field (E)

E = F/q

Where:

• E is the electric field.
• F is the force experienced by the charge.
• q is the magnitude of the charge.

Faraday’s Law of Electromagnetic Induction

ε = dΦ/dt

Where:

• ε is the induced EMF.
• Φ is the magnetic flux through the loop.
• t is time.

Magnetic Force on a Moving Charge

F = qvBsinθ

Where:

• F is the magnetic force,
• q is the charge,
• v is the velocity,
• B is the magnetic field strength,
• θ is the angle between v and B.

Gauss’ Law for Electric Field

Φ = q/ε_o

Where:

• ε_o is the electric permittivity of free space
• Φ is the magnetic flux through the loop.
• q is the net charge enclosed by the surface.

Electric Potential (Voltage)

V = W/q

Where:

• V is the electric potential (voltage).
• W is the electric potential energy.
• q is the charge.

Optics Formulas

Few important optics formula are:

Snell’s Law (Refraction)

n₁ sinθ₁ = n₂ sinθ₂

Where:

• n₁ incident index
• n₂ refracted index
• θ₁ incident angle
• θ₂ refracted angle

Lens Formula

1/f = 1/v – 1/u

Where:

• f is the focal length of the lens,
• u is the object distance,
• v is the image distance.

Magnification for Lenses

m = −v/u

Where:

• m is the magnification,
• v is the image distance,
• u is the object distance.

Magnifying Power

M = 1 + d/f

Where:

• M is the magnifying power
• f is the focal distance
• d is the distance between the object and the lens

Thin Lens Formula

1/f = 1/i + 1/o

Where:

• f is the focal length.
• i is the image distance.
• o is the object distance.

Sound Formulas

Important sound formulas are given below:

Speed of Sound

v = √(B/p)

Where:

• v is the speed of sound,
• B is the bulk modulus of the medium,
• ρ is the density of the medium.

Wavelength (λ)

λ = v/f

Where:

• λ is Wavelength
• v is Speed of sound
• f is Frequency of the sound wave

Frequency (f)

f = v / λ

Where:

f is Frequency

v is Speed of sound

λ is Wavelength

Acoustic Impedance (Z)

Z = ρ × c

Where:

• Z is Acoustic impedance
• ρ is Density of the medium
• c is Speed of sound in the medium

Fluid Mechanics Formulas

Few important formulas related to fluid mechanics are:

Density

ρ = mV

Where:

• ρ is density of fluid
• m is mass, and
• v is volume

Pressure

P = F/A

Where:

• P is the pressure of the fluid,
• F is applied Force,
• A is area

Pressure at a Depth h in a Fluid of Constant Density

p = p_o + ρgh

where:

• p is pressure at height h
• p_o is the pressure at the fluid’s surface,
• ρ is the density of the fluid,
• g is the acceleration due to gravity, and
• h is the depth to which the object is submerged

Viscosity

η = FL/vA

Where:

• η is fluid viscosity
• F is force
• L is distance between the plates
• V is constant velocity
• A is area of the plate

Pascal’s Law

F = PA

Where:

• F is applied Force
• P is Pressure, and
• A is area under cross-section.

Reynolds Number (Re)

Re = pvL/μ

Where:

• ρ is the density of the fluid.
• v is the velocity of the fluid.
• L is a characteristic length (e.g., diameter of the pipe).
• μ is the dynamic viscosity of the fluid.

Thermodynamics formulas

Important thermodynamics formulas are illustrated below:

First Law of Thermodynamics (Energy Conservation)

ΔU = Q − W

Where:

• ΔU is the change in internal energy,
• Q is the heat added to the system,
• W is the work done by the system.

Work Done in Isothermal Process (Ideal Gas)

W = nRTln(V_f/V_i)

Where:

• W is the work done,
• n is the number of moles of gas,
• R is the ideal gas constant,
• T is the temperature,
• V_f is the final volume,
• V_i is the initial volume.

Heat Transfer (Constant Pressure)

Q = nC_p ΔT

Where:

• Q is the heat added or removed,
• n is the number of moles of gas,
• C_p is the specific heat at constant pressure,
• ΔT is the change in temperature.

Ideal Gas Law

PV = nRT

Where:

• P is the pressure of the gas.
• V is the volume of the gas.
• n is the number of moles of gas.
• R is the gas constant.
• T is the temperature of the gas.

Entropy Change

ΔS = Q/T

Where:

• ΔS is the change in entropy.
• Q is the heat.
• T is the temperature.

Gibbs Free Energy

ΔG = ΔH − TΔS

Where:

• ΔG is the change in Gibbs free energy,
• ΔH is the change in enthalpy,
• ΔS is the change in entropy, and
• T is the absolute temperature

Wave Formulas

Important formulas related to wave are described below:

Wave Velocity (v)

v = f × λ

Where:

• v = Wave velocity (in meters per second, m/s)
• f = Frequency of the wave (in Hertz, Hz)
• λ = Wavelength of the wave (in meters, m)

Frequency (f)

f = 1/T

Where:

• f = Frequency (in Hertz, Hz)
• T = Time period of one wave cycle (in seconds, s)

Wavelength (λ)

λ = v/f

Where:

• λ = Wavelength (in meters, m)
• v = Wave velocity (in meters per second, m/s)
• f = Frequency (in Hertz, Hz)

Period (T)

T = 1/f

Where:

• T = Period (in seconds, s)
• f = Frequency (in Hertz, Hz)

Intensity (I)

I = P/A

where:

• P is the power
• A is the area.

Physics Formulas List
Vernier Calliper	Elastic Collision Formula
Acceleration-Time Graph	Wheatstone Bridge
Tangential Acceleration Formula	Projectile Motion
Inductance Formula	Newton’s law of cooling
Coefficient of Static friction Formula	Stoke’s Law
Angle between two vector Formula	Displacement Current
Heat Transfer Formulas	Resonant Frequency Formula
Gravitational Force	Normal Force Formula
Magnetic Field in a Solenoid	Mechanical Energy Formula
Angular Speed Formula	Relation between Frequency and Wavelength
Signal to noise ratio Formula	Air Resistance Formula
Lens Maker’s Formula	Wind Energy Formula
Angular Momentum	Resistance in Series and Parallel Combinations
Simple Harmonic Motion	Laws of Conservation of Momentum
Newton’s Third Law of Motion	Charge Density Formula
Radio Waves	Propagation Constant Formula
Current Density	Dynamic Viscosity Formula
Thermal Energy Formula	Surface Charge Density Formula
Time Dilation Formula	Heat of Reaction Formula
Current Density Formula	Tangential Velocity Formula
Induced Voltage Formula	Circular Velocity Formula
Spherical Capacitor Formula	Terminal Velocity Formula
Coefficient of Performance Formula	Surface Energy Formula
Relative Velocity Formula	Heat of Solution Formula
Linear Speed Formula	Energy of Wave Formula
Resistivity Formula	Electric Charge Formula
Cylindrical Capacitor Formula	Flow Rate Formula
Tension Formula	Resistors in Parallel Formula
Energy Level Formula	RC Circuit Frequency Variation
Transformer Formula	Net Force Formula
Drag Force Formula	Energy Density Formula
Speed Time Distance Formula	Heat Input Formula
Heat Rate Formula	Diffraction Grating Formula
Kinematic Viscosity Formula	Force of Attraction Formula
Power Factor Formula for Single Phase	EMF Formula
Capacitive Reactance Formula	Angular Velocity Formula
Heat Index Formula	Initial Velocity Formula
Strain Formula	Emissive Power Formula
Snell’s Law Formula	Brownian Motion Formula
Sound Pressure Level Formula	Banking of Road Formula
Amplitude Formula	Magnetic Declination Formula
Wave Velocity Formula	Water Pressure Formula
Heat Release Rate Formula	Light Waves and Color Formula
Moment Formula	Heat Flux Formula
Equivalent Resistance Formula	Heat Conduction Formula
Heat Loss Formula	Energy Momentum Formula
Bulk Modulus Formula	Work Done by Gravity Formula
Wavelength Formula	Radiation Pressure Formula
Efficiency Formula	Critical Velocity Formula
Voltage Divider Formula	Spring Force Formula
Doppler Shift Formula	Strain Energy Formula
Wavelength to Frequency Formula	Angular Displacement Formula
Average Speed Formula	Friction Formula
Pressure Drop Formula	Centripetal Force Formula
Conservation of Energy Formula	Deceleration Formula
Intensity Formula	Frequency Formula
Temperature Conversion Formula	Pressure Drop Formula
Instantaneous Speed Formula	Orbital Velocity Formula
Momentum Formula	Static Electricity Formula
Polarization Formula	Reflection and Ray Model of Light Formula
Length Contraction Formula	Resistance Formula
Stress Formula	Distance Traveled Formula
Instantaneous Velocity Formula	De Broglie Wavelength Formula
Inductive Reactance Formula	Radiant Energy Formula
Absolute Pressure Formula	Static Friction Formula
Average Force Formula	Kelvin To Celsius Formula
Specific Gravity Formula	Sound Intensity Formula
Thermal Expansion Formula	Beam Deflection Formula
Rotational Inertia Formula	Relativistic Mass Formula
Energy Consumption Formula	Stopping Distance Formula
Momentum and its Conservation Formula	Heat Gain Formula
Voltage Drop Formula	Heat Transfer Formula
Electrical Formulas	Heat of Fusion Formula
Lightning Formula	Special Theory of Relativity Formula
Wave Power Formula	Electric Field Formula
Momentum of Photon Formula	Photon Energy Formula
Beat Frequency Formula	Wave Speed Formula
Relativistic Doppler Effect Formula	Mechanical Advantage Formula
Poiseuilles Law Formula	Rotational Kinetic Energy Formula
Weight Formula	Heat Load Formula
DC Voltage Drop Formula	Oscillatory Motion Formula
Heat of Vaporization Formula	Potential Energy Formula
Horsepower Formula	Magnetism Formula
Poiseuilles Law Formula	Friction Loss Formula
Relativity Formula	Dimensional Formula of Potential Energy
Dimensions of Electric Charge	Dimensional Formula of Torque

Solved Examples on Physics Formulas

Example 1: A stretched string has a displacement of 20 cm and a spring constant of 50Nm⁻¹. Calculate the potential energy that the stretched string contains.

Solution:

The parameters that are given are

k = 50Nm⁻¹

x is equal to 20 cm, or 0.2 m.

Potential energy is what it will be.

P.E. = 1/2 k × x²

P.E =3/4 X 50 × (0.2)²

P.E = 1 J

Example 2: When x is in meters and t is in seconds, a body travels down the x-axis in accordance with the equation x = 1 – 2 t + 3t². Determine the body’s acceleration at t = 3s.

Solution:

As we have

x = 1 – 2 t + 3t² then;

Speed v = dx/dt = d(1 – 2t + 3t²)/dt = −2 + 6t

Now Acceleration a = dv/dt = d(−2+6t)/dt = 6

acceleration when t is 3s = 6 m/s²

Example 3: Determine the weight of an item that weighs 50 kg on Earth.

Solution:

We know, weight = m × g

w = (50 × 9.8) kg m/s²

w = 490 N

Example 4: A person travels in 10 seconds from Point A to Point B and returns in 8 seconds. Determine the person’s average speed if the distance is 36 meters between A and B.

Solution:

This distance traveled in total is 36 + 36 = 72 meters.

18 seconds was the total time taken.

Thus, average speed is equal to the total distance traveled divided by total time.

average speed = 72/18 = 4 m/s.

Hence the average speed of the person is 4 m/s.

Example 5: Determine the mass of an object having a kinetic energy of 100J and a velocity of 5 m/s.

Solution:

We know, KE = ½ mv².

100 = ½ x m x 5 x 5.

100 = 25 m/2

m = (100 × 2)/25

m = 8 kg

Practice Problems

Problems 1: Determine the displacement that an object traveling at a speed of 60 m/s will cover in 3 seconds.

Problems 2: A 50 cm long, thin rod has an evenly distributed total charge of 5 mC over it. Determine the linear density of charges.

Problems 3: A automobile with a mass of 250 kg is moving at a speed of 10 meters per second. What is the kinetic energy of it?

Problems 4: 400kcal of heat is required for the phase transition of a 2 kilogram material. Calculate the heat it contains latently.

Problems 5: A cube immersed in water with a side length of 0.1 meters and a density of 800 kg/m³. Determine if the cube will sink or float by computing the buoyant force acting on it.

Physics Formulas FAQs

What is the Physics Formula for Distance?

Use the distance formula, d = st, to answer all distance-related questions. Given that they both express a distance in units of time, such as miles or kilometers per hour, the speed and the rate are comparable.

How to learn physics formulas quickly?

The Tips to remember physics formulas are:

• Go through and become acquainted. We may see that several variables in physics are repeated. For instance, the variable r, or R, is used to represent radius and appears in most formulations.
• Utilize and have fun with problem-solving.
• Acquire knowledge about formula.
• Recognize a formula’s components and structure.
• Take notes after that.
• After visualizing, give yourself a test.

What is the most well-known formula in physics?

All the physics formulas are well known however one of the most famous physics equation is, E = mc², which deals with energy. In this equation, the symbols E, m, and c stand for energy, mass, and the speed of light in a vacuum, which is equal to 3×10⁸ meters per second.