Newton's Second Law Concepts

The behavior of objects when forces are balanced

The behavior of objects when forces are unbalanced

The gravitational pull between two objects

The energy conservation in a closed system

Acceleration decreases

Acceleration remains constant

Acceleration increases

Acceleration becomes zero

It applies a larger net force, increasing acceleration

It decreases the apple's speed

It increases the apple's mass

It reduces the apple's acceleration

Acceleration becomes infinite

Acceleration remains unchanged

Acceleration decreases

Acceleration increases

The pumpkin is thrown with less force

The pumpkin has a greater mass

The pumpkin has a smaller mass

The pumpkin is more aerodynamic

Velocity equals mass times acceleration

Mass equals force divided by acceleration

Acceleration equals net force divided by mass

Force equals mass times velocity

Net force equals mass times velocity

Net force equals mass times acceleration

Net force equals mass divided by acceleration

Net force equals acceleration divided by mass

Mass is directly proportional to acceleration

Acceleration is directly proportional to net force

Acceleration is directly proportional to mass

Force is inversely proportional to mass

The object will accelerate

The object will decelerate

The object will maintain its current state of motion

The object will change direction

To predict the gravitational pull between planets

To solve algebraic problems involving force, mass, and acceleration

To calculate the energy of a moving object

To determine the speed of light