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Space, Time and Motion - Momentum and Impulse

Grade 11IBPhysics

Review the key concepts, formulae, and examples before starting your quiz.

🔑Concepts

Linear momentum is defined as the product of an object's mass and its velocity: p=mv\vec{p} = m\vec{v}. It is a vector quantity, meaning it has both magnitude and direction, measured in kgms1kg \cdot m \cdot s^{-1}.

Newton's Second Law in terms of momentum states that the net resultant force acting on an object is equal to the rate of change of its linear momentum: Fnet=ΔpΔtF_{net} = \frac{\Delta p}{\Delta t}.

Impulse (JJ) is the product of the average force and the time interval over which it acts: J=FΔtJ = F \Delta t. It is equivalent to the change in momentum: J=Δp=m(vu)J = \Delta p = m(v - u).

The area under a Force-time (FF-tt) graph represents the impulse delivered to an object, which corresponds to the total change in its momentum.

The Law of Conservation of Linear Momentum states that in an isolated system (where no external forces act), the total linear momentum remains constant: pinitial=pfinal\sum p_{initial} = \sum p_{final}.

In an elastic collision, both total momentum and total kinetic energy (EkE_k) are conserved. In an inelastic collision, only total momentum is conserved, while some kinetic energy is dissipated as heat, sound, or used in deformation.

The relationship between kinetic energy (EkE_k) and momentum (pp) is given by Ek=p22mE_k = \frac{p^2}{2m}.

📐Formulae

p=mvp = mv

F=ΔpΔtF = \frac{\Delta p}{\Delta t}

J=FΔt=ΔpJ = F\Delta t = \Delta p

m1u1+m2u2=m1v1+m2v2m_1 u_1 + m_2 u_2 = m_1 v_1 + m_2 v_2

Ek=p22mE_k = \frac{p^2}{2m}

Impulse=Fdt\text{Impulse} = \int F \, dt

💡Examples

Problem 1:

A tennis ball of mass 0.060 kg0.060\text{ kg} is moving horizontally at 40 m s140\text{ m } s^{-1} when it is struck by a racket. The ball rebounds in the opposite direction at 30 m s130\text{ m } s^{-1}. If the ball is in contact with the racket for 0.005 s0.005\text{ s}, calculate the average force exerted by the racket on the ball.

Solution:

Taking the initial direction as positive: u=40 m s1u = 40\text{ m } s^{-1} v=30 m s1v = -30\text{ m } s^{-1} m=0.060 kgm = 0.060\text{ kg} Δt=0.005 s\Delta t = 0.005\text{ s}

Change in momentum: Δp=m(vu)=0.060×(3040)=4.2 kg ms1\Delta p = m(v - u) = 0.060 \times (-30 - 40) = -4.2\text{ kg } m \cdot s^{-1}

Average force: F=ΔpΔt=4.20.005=840 NF = \frac{\Delta p}{\Delta t} = \frac{-4.2}{0.005} = -840\text{ N}

Explanation:

The negative sign indicates that the force acts in the direction opposite to the initial velocity. The impulse delivered is 4.2 N s4.2\text{ N } s.

Problem 2:

A block of mass 2.0 kg2.0\text{ kg} moving at 5.0 m s15.0\text{ m } s^{-1} collides with a stationary block of mass 3.0 kg3.0\text{ kg}. The two blocks stick together after the collision. Calculate the final velocity of the combined mass.

Solution:

Using conservation of momentum: m1u1+m2u2=(m1+m2)vm_1 u_1 + m_2 u_2 = (m_1 + m_2)v (2.0×5.0)+(3.0×0)=(2.0+3.0)v(2.0 \times 5.0) + (3.0 \times 0) = (2.0 + 3.0)v 10=5.0v10 = 5.0v v=2.0 m s1v = 2.0\text{ m } s^{-1}

Explanation:

Since the blocks stick together, it is a perfectly inelastic collision. The total momentum before the collision (10 kg ms110\text{ kg } m \cdot s^{-1}) must equal the total momentum after the collision.

Momentum and Impulse - Revision Notes & Key Formulas | IB Grade 11 Physics