Motion Basics
Newton’s Laws
Forces & Gravity
Momentum & Collisions
Energy, Work & Power
100

Quantity that describes how fast an object is moving

Speed

100

Newton’s law that explains why objects resist changes in motion

Newton’s First Law

100

The force that pulls objects toward Earth

Gravity

100

Quantity calculated using mass and velocity

Momentum

100

Energy an object has due to motion

Kinetic energy

200

Quantity that includes both speed and direction

Velocity

200

Law that states force equals mass times acceleration

Newton’s Second Law

200

Approximate acceleration due to gravity near Earth

9.8 m/s²

200

Type of quantity momentum is

Vector

200

Energy an object has due to height

Gravitational potential energy

300

Term that describes a change in velocity over time

Acceleration

300

Law that explains action–reaction force pairs

Newton’s Third Law

300

Type of motion where gravity is the only force acting

Free fall

300

Collision where objects stick together

Inelastic collision

300

The sum of kinetic and potential energy

Mechanical energy

400

Motion where speed and direction do not change

Constant velocity

400

according to Newton’s First Law, this must be true for an object to change velocity

A net force must act on the object

400

At the top of its path, an upward-thrown object has this velocity

Zero

400

Collision in which kinetic energy is conserved

Elastic collision

400

What doubles when work stays the same but time is cut in half

Power

500

When an object slows down while moving forward, the acceleration is in this direction

Opposite the direction of motion

500

Law that explains why seatbelts are needed in a sudden stop

Newton’s First Law

500

In free fall (ignoring air resistance), heavy and light objects do this

Fall at the same rate

500

Quantity that is always conserved in a closed system during a collision

Momentum

500

What happens to kinetic energy when speed doubles

It quadruples

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