What is an inelastic collision?

A collision where objects do not conserve kinetic energy; instead, some is lost to heat, sound, or deformation.

What is a perfectly inelastic collision?

It is when colliding bodies stick together and move with a common velocity after collision.

Is momentum conserved in inelastic collisions?

Yes, momentum is always conserved in isolated systems regardless of energy loss.

Why is kinetic energy lost?

Because energy transforms into heat, sound, and deformation during impact.

Are real-life collisions elastic or inelastic?

Most real-life collisions are partially inelastic since some energy is always lost.

Can energy loss be calculated?

Yes, by comparing the system’s kinetic energy before and after the collision.

Where are inelastic collisions applied?

They are studied in crash testing, sports science, astrophysics, and accident reconstruction.

Inelastic Collision Calculator

Understanding Inelastic Collisions

In physics, collisions are categorized based on how momentum and kinetic energy behave. Momentum is always conserved in isolated collisions, but kinetic energy may not be. When two objects collide and stick together, the collision is called a perfectly inelastic collision. Such collisions are common in real life, including vehicle crashes, sports impacts, and particle interactions.

Key Principles

Conservation of Momentum: Total momentum before collision equals total momentum after collision.
Kinetic Energy Loss: Unlike elastic collisions, some kinetic energy is transformed into heat, sound, or deformation.
Final Velocity: In perfectly inelastic collisions, colliding bodies move together with the same velocity after impact.

Formula

v = (m₁v₁ + m₂v₂) / (m₁ + m₂)

Where:

m₁, m₂ = masses of the two objects
v₁, v₂ = initial velocities of the two objects
v = final shared velocity after collision

Kinetic Energy Loss

ΔKE = KE_initial - KE_final

Kinetic energy decreases because part of it is transformed into other forms of energy, such as sound waves, internal vibrations, or permanent deformation of materials.

Worked Example

A 2 kg cart moving at 4 m/s collides with a 3 kg stationary cart. After collision, they stick together.

v = (2×4 + 3×0) / (2+3) = 8 / 5 = 1.6 m/s

Final velocity of the combined carts is 1.6 m/s. Initial KE = ½(2)(4²) = 16 J. Final KE = ½(5)(1.6²) = 6.4 J. Energy lost = 16 - 6.4 = 9.6 J.

Applications

Vehicle Safety: Crash tests use inelastic collision physics to design safer cars.
Sports: Explains energy dissipation in tackles, ball impacts, and wrestling.
Astrophysics: Planet formation involves dust and rocks sticking together in inelastic collisions.
Engineering: Helps analyze material deformation and energy absorption systems.
Accident Reconstruction: Forensic physics relies on momentum and energy principles.

Insights

Perfectly inelastic collisions illustrate why no process is 100% efficient. Energy conservation still holds globally, but mechanical energy transforms into other less useful forms. This principle underpins the Second Law of Thermodynamics and real-world inefficiencies in mechanical systems.

Inelastic Collision Calculator