Question 11 - A-Level Maths

Pre-U Pre-U 9795/2 2019 Specimen — Question 11 5 marks

Exam Board	Pre-U
Module	Pre-U 9795/2 (Pre-U Further Mathematics Paper 2)
Year	2019
Session	Specimen
Marks	5
Topic	Oblique and successive collisions
Type	Oblique collision, direction deflected given angle
Difficulty	Challenging +1.8 This is a challenging oblique collision problem requiring conservation of momentum in two directions, Newton's experimental law, the perpendicularity condition, and energy considerations. It involves multiple unknowns and requires systematic algebraic manipulation across several equations, placing it well above average difficulty but within reach of strong Further Maths students.
Spec	6.03b Conservation of momentum: 1D two particles 6.03c Momentum in 2D: vector form 6.03i Coefficient of restitution: e 6.03k Newton's experimental law: direct impact

11 \includegraphics[max width=\textwidth, alt={}, center]{adf5bd3c-5408-421d-b7d5-dea2d0f0185b-6_438_951_255_559} A smooth sphere \(P\) of mass \(3 m\) is at rest on a smooth horizontal table. A second smooth sphere \(Q\) of mass \(m\) and the same radius as \(P\) is moving along the table towards \(P\) and strikes it obliquely (see diagram). After the collision, the directions of motion of the two spheres are perpendicular.

Find the coefficient of restitution.
Given that one-sixth of the original kinetic energy is lost as a result of the collision, find the angle between the initial direction of motion of \(Q\) and the line of centres.

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Question 11(a)

Let \(u\) denote speed of sphere \(Q\) before impact, \(v_1\) and \(v_2\) the speeds of spheres \(Q\) and \(P\), respectively, after impact and \(\alpha\) the angle between \(Q\)'s initial direction of motion and the line of centres. After impact, if moving perpendicularly, \(Q\) moves perpendicular to line of centres and \(P\) moves along line of centres. (Stated or implied) [B1]

Conservation of linear motion: \(mu\cos\alpha = 0 + 3mv_2\) or \(mu_x = 3mv\) [M1A1]

Newton's experimental law: \(eu\cos\alpha = v_2\) or \(eu_x = v\) [A1]

\(\therefore e = \dfrac{1}{3}\) [A1]

Total: 5 marks

Question 11(b)

\(v_1 = u\sin\alpha\) and \(v_2 = \dfrac{1}{3}u\cos\alpha\) (both needed) [B1]

Loss in kinetic energy is

\(\dfrac{1}{2}mu^2 - \dfrac{1}{2}mu^2\sin^2\alpha - \dfrac{1}{2} \cdot 3m\dfrac{u^2\cos^2\alpha}{9}\) [M1A1]

\(= \dfrac{1}{12}mu^2\) (Or remaining kinetic energy is 5/6 of initial kinetic energy etc.) [A1]

But \(\cos^2\alpha + \sin^2\alpha = 1\) (used) [M1]

\(\Rightarrow \ldots \Rightarrow \sin^2\alpha = \dfrac{3}{4} \Rightarrow \sin\alpha = \dfrac{\sqrt{3}}{2} \Rightarrow \alpha = 60°\) [M1A1]

Total: 7 marks

**Question 11(a)**

Let $u$ denote speed of sphere $Q$ before impact, $v_1$ and $v_2$ the speeds of spheres $Q$ and $P$, respectively, after impact and $\alpha$ the angle between $Q$'s initial direction of motion and the line of centres. After impact, if moving perpendicularly, $Q$ moves perpendicular to line of centres and $P$ moves along line of centres. (Stated or implied) [B1]

Conservation of linear motion: $mu\cos\alpha = 0 + 3mv_2$ or $mu_x = 3mv$ [M1A1]

Newton's experimental law: $eu\cos\alpha = v_2$ or $eu_x = v$ [A1]

$\therefore e = \dfrac{1}{3}$ [A1]

**Total: 5 marks**

**Question 11(b)**

$v_1 = u\sin\alpha$ and $v_2 = \dfrac{1}{3}u\cos\alpha$ (both needed) [B1]

Loss in kinetic energy is

$\dfrac{1}{2}mu^2 - \dfrac{1}{2}mu^2\sin^2\alpha - \dfrac{1}{2} \cdot 3m\dfrac{u^2\cos^2\alpha}{9}$ [M1A1]

$= \dfrac{1}{12}mu^2$ (Or remaining kinetic energy is 5/6 of initial kinetic energy etc.) [A1]

But $\cos^2\alpha + \sin^2\alpha = 1$ (used) [M1]

$\Rightarrow \ldots \Rightarrow \sin^2\alpha = \dfrac{3}{4} \Rightarrow \sin\alpha = \dfrac{\sqrt{3}}{2} \Rightarrow \alpha = 60°$ [M1A1]

**Total: 7 marks**

Show LaTeX source

11\\
\includegraphics[max width=\textwidth, alt={}, center]{adf5bd3c-5408-421d-b7d5-dea2d0f0185b-6_438_951_255_559}

A smooth sphere $P$ of mass $3 m$ is at rest on a smooth horizontal table. A second smooth sphere $Q$ of mass $m$ and the same radius as $P$ is moving along the table towards $P$ and strikes it obliquely (see diagram). After the collision, the directions of motion of the two spheres are perpendicular.
\begin{enumerate}[label=(\alph*)]
\item Find the coefficient of restitution.
\item Given that one-sixth of the original kinetic energy is lost as a result of the collision, find the angle between the initial direction of motion of $Q$ and the line of centres.
\end{enumerate}

\hfill \mbox{\textit{Pre-U Pre-U 9795/2 2019 Q11 [5]}}

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