understand that mass is the property of an object that resists change in motion
recall F = ma and solve problems using it, understanding that acceleration and resultant force are always in the same direction
define and use linear momentum as the product of mass and velocity
define and use force as rate of change of momentum
state and apply each of Newton’s laws of motion
describe and use the concept of weight as the effect of a gravitational field on a mass and recall that the weight of an object is equal to the product of its mass and the acceleration of free fall
3.2 Non-uniform motion
show a qualitative understanding of frictional forces and viscous/drag forces including air resistance (no treatment of the coefficients of friction and viscosity is required, and a simple model of drag force increasing as speed increases is sufficient)
describe and explain qualitatively the motion of objects in a uniform gravitational field with air resistance
understand that objects moving against a resistive force may reach a terminal (constant) velocity
3.3 Linear momentum and its conservation
state the principle of conservation of momentum
apply the principle of conservation of momentum to solve simple problems, including elastic and inelastic interactions between objects in both one and two dimensions (knowledge of the concept of coefficient of restitution is not required)
recall that, for a perfectly elastic collision, the relative speed of approach is equal to the relative speed of separation
understand that, while momentum of a system is always conserved in interactions between objects, some change in kinetic energy may take place