Pearson Edexcel GCE Mathematics Pure 2 (June 2024)

Given \( y = x^3 – 7x^2 + 5x – 10 \)

Differentiating term by term:

• \( x^3 \to 3x^2 \)
• \( -7x^2 \to -7(2x) = -14x \)
• \( 5x \to 5 \)
• \( -10 \to 0 \)

\[ \frac{\mathrm{d}y}{\mathrm{d}x} = 3x^2 – 14x + 5 \]

✓ (M1 A1) Correct differentiation

From (i): \( \frac{\mathrm{d}y}{\mathrm{d}x} = 3x^2 – 14x + 5 \)

Differentiating again:

\[ \frac{\mathrm{d}^2y}{\mathrm{d}x^2} = 3(2x) – 14(1) + 0 \] \[ \frac{\mathrm{d}^2y}{\mathrm{d}x^2} = 6x – 14 \]

✓ (A1ft) Correct second derivative (follow through)

\[ \frac{\mathrm{d}^2y}{\mathrm{d}x^2} = 0 \] \[ 6x – 14 = 0 \]

Add 14 to both sides:

\[ 6x = 14 \]

Divide by 6:

\[ x = \frac{14}{6} \]

Simplify the fraction:

\[ x = \frac{7}{3} \]

✓ (M1) Setting second derivative to 0
✓ (A1) Correct exact value

Month 1: £400 \( \rightarrow a = 400 \)

Month 2: £390

Month 3: £380

The difference is \( 390 – 400 = -10 \). So, \( d = -10 \).

\[ u_{12} = 400 + (12-1)(-10) \] \[ u_{12} = 400 + (11)(-10) \] \[ u_{12} = 400 – 110 \] \[ u_{12} = 290 \]

✓ (B1) Correct calculation shown

Set sum \( S_N = 8100 \):

\[ 8100 = \frac{N}{2}(2(400) + (N-1)(-10)) \]

Multiply by 2 to clear the fraction:

\[ 16200 = N(800 – 10N + 10) \] \[ 16200 = N(810 – 10N) \]

Expand the bracket:

\[ 16200 = 810N – 10N^2 \]

Rearrange to form a quadratic equation (move everything to the left to make \( N^2 \) positive):

\[ 10N^2 – 810N + 16200 = 0 \]

Divide strictly by 10:

\[ N^2 – 81N + 1620 = 0 \]

(as required)

✓ (M1) Setting up sum equation
✓ (A1) Correct derivation

\[ N^2 – 81N + 1620 = 0 \]

Factors of 1620: 36 and 45. Check: \( 36 + 45 = 81 \) and \( 36 \times 45 = 1620 \).

\[ (N – 36)(N – 45) = 0 \]

So \( N = 36 \) or \( N = 45 \).

Logic check: Would the payment become negative? Let’s check the payment at month 45:

\[ u_{45} = 400 + 44(-10) = 400 – 440 = -40 \]

A negative payment implies the bank pays Jamie, which doesn’t make sense for paying off a loan. The loan is paid off at the earlier date.

Therefore, \( N = 36 \).

✓ (M1) Solving quadratic
✓ (A1) Selecting correct value (36)

Original point: \( (3, -2) \)

Transformation: \( x \to x + 2 \), \( y \) stays same.

\[ (3+2, -2) = (5, -2) \]

✓ (B1)

Original point: \( (3, -2) \)

Transformation: Multiply \( x \) coordinate by \( \frac{1}{2} \), \( y \) stays same.

\[ (3 \times \frac{1}{2}, -2) = (1.5, -2) \]

✓ (B1)

Original point: \( (3, -2) \)

1. Reflection (\( f(-x) \)): \( x \) becomes \( -3 \). Point is \( (-3, -2) \).

2. Vertical Stretch (\( \times 3 \)): \( y \) becomes \( -2 \times 3 = -6 \). Point is \( (-3, -6) \).

3. Vertical Shift (\( + 5 \)): \( y \) becomes \( -6 + 5 = -1 \). Point is \( (-3, -1) \).

✓ (B1 B1) One mark for each coordinate

Given \( u_1 = 6 \).

Find \( u_2 \):

\[ u_2 = k(u_1) – 5 = 6k – 5 \]

Find \( u_3 \):

\[ u_3 = k(u_2) – 5 = k(6k – 5) – 5 \] \[ u_3 = 6k^2 – 5k – 5 \]

✓ (M1) Finding \( u_3 \) in terms of \( k \)

\[ 6k^2 – 5k – 5 = -1 \]

Add 1 to both sides:

\[ 6k^2 – 5k – 4 = 0 \]

(as required)

✓ (A1) Correct derivation

\[ 6k^2 – 5k – 4 = 0 \]

Factorise (look for numbers multiplying to \( 6 \times -4 = -24 \) and adding to -5, i.e., -8 and 3):

\[ 6k^2 – 8k + 3k – 4 = 0 \] \[ 2k(3k – 4) + 1(3k – 4) = 0 \] \[ (2k + 1)(3k – 4) = 0 \]

Solutions: \( k = -0.5 \) or \( k = \frac{4}{3} \).

Since \( k \) is positive, \( k = \frac{4}{3} \).

✓ (B1) Correct value of \( k \)

\( u_1 = 6 \)

\( u_2 = 6(\frac{4}{3}) – 5 = 8 – 5 = 3 \)

\( u_3 = -1 \) (given)

Sum \( \sum_{r=1}^{3} u_r = u_1 + u_2 + u_3 \):

\[ 6 + 3 + (-1) = 8 \]

✓ (M1) Attempting sum
✓ (A1) Correct answer

For \( \tan 2\theta \): replace \( \theta \) with \( 2\theta \)

\[ \tan 2\theta \approx 2\theta \]

For \( \cos 3\theta \): replace \( \theta \) with \( 3\theta \)

\[ \cos 3\theta \approx 1 – \frac{(3\theta)^2}{2} = 1 – \frac{9\theta^2}{2} \]

✓ (B1) Correct approximations stated or used

\[ \text{Expression} \approx \frac{\theta(2\theta)}{1 – (1 – \frac{9\theta^2}{2})} \]

Simplify numerator:

\[ \text{Numerator} = 2\theta^2 \]

Simplify denominator (watch the double negative!):

\[ \text{Denominator} = 1 – 1 + \frac{9\theta^2}{2} = \frac{9\theta^2}{2} \]

Combine:

\[ \frac{2\theta^2}{\frac{9\theta^2}{2}} \]

✓ (M1) Correct substitution

\[ \frac{2\theta^2}{\frac{9\theta^2}{2}} = 2 \div \frac{9}{2} \] \[ = 2 \times \frac{2}{9} \] \[ = \frac{4}{9} \]

✓ (A1) Correct numerical value

(i) \( f(x) = e^{4x^2 – 1} \)

Let \( u = 4x^2 – 1 \), then \( u’ = 8x \).

\[ f'(x) = 8x e^{4x^2 – 1} \]

(ii) \( g(x) = 8\ln x \)

\[ g'(x) = \frac{8}{x} \]

✓ (B1 B1) Correct derivatives

\[ 8x e^{4x^2 – 1} = \frac{8}{x} \]

Divide by 8:

\[ x e^{4x^2 – 1} = \frac{1}{x} \]

We want to remove the \( e \), so take natural logs (ln) of both sides. First, isolate the \( e \) term is usually helpful, but let’s look at the target equation. It has \( 4x^2 \) and \( \ln x \). Taking ln immediately works:

\[ \ln(x e^{4x^2 – 1}) = \ln(\frac{1}{x}) \]

Use log laws: \( \ln(ab) = \ln a + \ln b \) and \( \ln(1/x) = -\ln x \).

\[ \ln x + \ln(e^{4x^2 – 1}) = -\ln x \] \[ \ln x + (4x^2 – 1) = -\ln x \]

Rearrange to match target:

\[ 4x^2 – 1 + 2\ln x = 0 \] \[ 4x^2 + 2\ln x – 1 = 0 \]

✓ (M1) Equating and taking logs
✓ (A1) Deriving exact form

\( x_1 = 0.6 \)

(i) Substitute into formula:

\[ x_2 = \sqrt{\frac{1-2\ln(0.6)}{4}} \] \[ x_2 \approx 0.7109 \] (to 4 d.p.)

(ii) Continue iterating to find \( \alpha \):

\( x_3 \approx 0.6485 \)

\( x_4 \approx 0.6830 \)

… convergence is oscillatory.

Eventually \( \alpha \approx 0.6706 \).

✓ (M1) Attempting iteration
✓ (A1) Correct \( x_2 \)
✓ (A1) Correct \( \alpha \)

\[ \vec{OA} = \begin{pmatrix} 2 \\ -3 \\ 5 \end{pmatrix}, \quad \vec{OB} = \begin{pmatrix} 5 \\ 6 \\ 8 \end{pmatrix} \] \[ \vec{AB} = \begin{pmatrix} 5 \\ 6 \\ 8 \end{pmatrix} – \begin{pmatrix} 2 \\ -3 \\ 5 \end{pmatrix} = \begin{pmatrix} 3 \\ 9 \\ 3 \end{pmatrix} \] \[ \vec{AB} = 3\mathbf{i} + 9\mathbf{j} + 3\mathbf{k} \]

✓ (B1) Correct vector

Case 1 (Internal):

\( \vec{AP} = \frac{2}{3}\vec{AB} \)

\[ \vec{OP} = \vec{OA} + \frac{2}{3}\vec{AB} \] \[ \vec{OP} = \begin{pmatrix} 2 \\ -3 \\ 5 \end{pmatrix} + \frac{2}{3}\begin{pmatrix} 3 \\ 9 \\ 3 \end{pmatrix} \] \[ \vec{OP} = \begin{pmatrix} 2 \\ -3 \\ 5 \end{pmatrix} + \begin{pmatrix} 2 \\ 6 \\ 2 \end{pmatrix} = \begin{pmatrix} 4 \\ 3 \\ 7 \end{pmatrix} \]

So \( P_1 = 4\mathbf{i} + 3\mathbf{j} + 7\mathbf{k} \)

Case 2 (External):

\( \vec{AP} = 2\vec{AB} \) (Going from A past B)

\[ \vec{OP} = \vec{OA} + 2\vec{AB} \] \[ \vec{OP} = \begin{pmatrix} 2 \\ -3 \\ 5 \end{pmatrix} + 2\begin{pmatrix} 3 \\ 9 \\ 3 \end{pmatrix} \] \[ \vec{OP} = \begin{pmatrix} 2 \\ -3 \\ 5 \end{pmatrix} + \begin{pmatrix} 6 \\ 18 \\ 6 \end{pmatrix} = \begin{pmatrix} 8 \\ 15 \\ 11 \end{pmatrix} \]

So \( P_2 = 8\mathbf{i} + 15\mathbf{j} + 11\mathbf{k} \)

✓ (M1) Strategy for finding P
✓ (A1) First position
✓ (M1) Second strategy
✓ (A1) Second position

Combine LHS over a common denominator:

\[ \frac{(\mathrm{cosec}\,\theta + 1) + (\mathrm{cosec}\,\theta – 1)}{(\mathrm{cosec}\,\theta – 1)(\mathrm{cosec}\,\theta + 1)} \]

Simplify numerator: \( 2\mathrm{cosec}\,\theta \)

Simplify denominator (difference of squares): \( \mathrm{cosec}^2\,\theta – 1 \)

✓ (B1) Combined single fraction

Use identity \( 1 + \cot^2\theta = \mathrm{cosec}^2\theta \), so \( \mathrm{cosec}^2\theta – 1 = \cot^2\theta \).

\[ \frac{2\mathrm{cosec}\,\theta}{\cot^2\theta} \]

Convert to sin and cos:

\[ = 2 \left( \frac{1}{\sin\theta} \right) \div \left( \frac{\cos^2\theta}{\sin^2\theta} \right) \] \[ = \frac{2}{\sin\theta} \times \frac{\sin^2\theta}{\cos^2\theta} \] \[ = \frac{2\sin\theta}{\cos^2\theta} \] \[ = 2 \left( \frac{\sin\theta}{\cos\theta} \right) \left( \frac{1}{\cos\theta} \right) \] \[ = 2 \tan\theta \sec\theta \]

QED.

✓ (M1) Pythagorean identity
✓ (A1) Completion of proof

\[ 2\tan 2x \sec 2x = \cot 2x \sec 2x \]

Rearrange to solve (bring everything to one side or factorise):

\[ 2\tan 2x \sec 2x – \cot 2x \sec 2x = 0 \] \[ \sec 2x (2\tan 2x – \cot 2x) = 0 \]

Since \( \sec 2x = \frac{1}{\cos 2x} \) cannot be 0, we must have:

\[ 2\tan 2x – \cot 2x = 0 \] \[ 2\tan 2x = \frac{1}{\tan 2x} \] \[ \tan^2 2x = \frac{1}{2} \] \[ \tan 2x = \pm \sqrt{0.5} \]

✓ (B1) Use identity
✓ (M1) Simplify to trig equation

Range: \( 0 < x < 90 \), so \( 0 < 2x < 180 \).

1) \( \tan 2x = \sqrt{0.5} \)

\[ 2x = \tan^{-1}(\sqrt{0.5}) \approx 35.26^\circ \] \[ x \approx 17.6^\circ \]

2) \( \tan 2x = -\sqrt{0.5} \)

\[ 2x = 180 – 35.26 = 144.74^\circ \] \[ x \approx 72.4^\circ \]

✓ (M1) Solving for x
✓ (A1) Correct values

Using \( H = a(x-9)^2 + k \).

Use point A \( (0, 2) \):

\[ 2 = a(0-9)^2 + k \] \[ 2 = 81a + k \quad \text{(1)} \]

Use point B \( (20, 0.8) \):

\[ 0.8 = a(20-9)^2 + k \] \[ 0.8 = 121a + k \quad \text{(2)} \]

✓ (M1) Model form
✓ (dM1) Setting up simultaneous equations

Subtract (1) from (2):

\[ (0.8 – 2) = (121a – 81a) \] \[ -1.2 = 40a \] \[ a = \frac{-1.2}{40} = -0.03 \]

Substitute back into (1) to find \( k \):

\[ k = 2 – 81(-0.03) \] \[ k = 2 – (-2.43) = 4.43 \]

So, \( H = -0.03(x-9)^2 + 4.43 \).

(Alternative forms like \( ax^2+bx+c \) are acceptable if equivalent)

✓ (ddM1) Solving
✓ (A1) Correct equation

Valid limitations:

• Air resistance is not considered.
• Wind effects.
• The ball is not a particle (has size).

✓ (B1) Valid reason

Find \( H \) when \( x = 16 \).

\[ H = -0.03(16-9)^2 + 4.43 \] \[ H = -0.03(7)^2 + 4.43 \] \[ H = -0.03(49) + 4.43 \] \[ H = -1.47 + 4.43 \] \[ H = 2.96 \text{ m} \]

Conclusion: \( 2.96 > 2.5 \), so Chandra cannot catch the ball.

✓ (M1) Calculation
✓ (A1) Correct conclusion

Use \( y = 2 \):

\[ 2 = 1 – t^3 \] \[ t^3 = -1 \] \[ t = -1 \]

Check with \( x \): \( x = (-1+3)^2 = 2^2 = 4 \). Consistent.

✓ (B1) Correct t value

\( x = (t+3)^2 \implies \frac{\mathrm{d}x}{\mathrm{d}t} = 2(t+3) \)

\( y = 1 – t^3 \implies \frac{\mathrm{d}y}{\mathrm{d}t} = -3t^2 \)

Use chain rule for gradient:

\[ \frac{\mathrm{d}y}{\mathrm{d}x} = \frac{\mathrm{d}y/\mathrm{d}t}{\mathrm{d}x/\mathrm{d}t} = \frac{-3t^2}{2(t+3)} \]

✓ (M1 A1) Chain rule use

Substitute \( t = -1 \):

\[ m = \frac{-3(-1)^2}{2(-1+3)} = \frac{-3}{4} \]

✓ (M1) Evaluating gradient

Use \( y – y_1 = m(x – x_1) \) with \( (4, 2) \) and \( m = -3/4 \).

\[ y – 2 = -\frac{3}{4}(x – 4) \]

Multiply by 4:

\[ 4(y – 2) = -3(x – 4) \] \[ 4y – 8 = -3x + 12 \] \[ 3x + 4y = 20 \]

(as required)

✓ (A1*) Correct proof

\( y = 1 – t^3 \). To maximize \( y \), we need the most negative \( t^3 \).

Minimum \( t = -2 \).

\[ y_{max} = 1 – (-2)^3 = 1 – (-8) = 9 \]

Max height = 9m.

✓ (B1) Correct height

\[ \text{Area} = \int_{0}^{1} 8x^2 e^{-3x} \, \mathrm{d}x \]

\( u = 8x^2 \implies \frac{\mathrm{d}u}{\mathrm{d}x} = 16x \)

\( \frac{\mathrm{d}v}{\mathrm{d}x} = e^{-3x} \implies v = -\frac{1}{3}e^{-3x} \)

Apply formula:

\[ I = \left[ -\frac{8}{3}x^2 e^{-3x} \right]_0^1 – \int_0^1 \left( -\frac{1}{3}e^{-3x} \right) (16x) \, \mathrm{d}x \] \[ I = \left[ -\frac{8}{3}x^2 e^{-3x} \right]_0^1 + \frac{16}{3} \int_0^1 x e^{-3x} \, \mathrm{d}x \]

✓ (M1 A1) Correct first application

Let \( u = x \implies \frac{\mathrm{d}u}{\mathrm{d}x} = 1 \)

Let \( \frac{\mathrm{d}v}{\mathrm{d}x} = e^{-3x} \implies v = -\frac{1}{3}e^{-3x} \)

\[ \int x e^{-3x} dx = \left[ -\frac{1}{3}x e^{-3x} \right] – \int \left( -\frac{1}{3}e^{-3x} \right) (1) \, \mathrm{d}x \] \[ = -\frac{1}{3}x e^{-3x} + \frac{1}{3} \int e^{-3x} \, \mathrm{d}x \] \[ = -\frac{1}{3}x e^{-3x} – \frac{1}{9}e^{-3x} \]

✓ (dM1) Second application

Substitute back into the main expression:

\[ I = \left[ -\frac{8}{3}x^2 e^{-3x} + \frac{16}{3} \left( -\frac{1}{3}x e^{-3x} – \frac{1}{9}e^{-3x} \right) \right]_0^1 \] \[ I = \left[ -\frac{8}{3}x^2 e^{-3x} – \frac{16}{9}x e^{-3x} – \frac{16}{27}e^{-3x} \right]_0^1 \]

Evaluate at upper limit \( x = 1 \):

\[ -\frac{8}{3}e^{-3} – \frac{16}{9}e^{-3} – \frac{16}{27}e^{-3} \] \[ = \left( -\frac{72}{27} – \frac{48}{27} – \frac{16}{27} \right) e^{-3} = -\frac{136}{27}e^{-3} \]

Evaluate at lower limit \( x = 0 \):

\[ 0 – 0 – \frac{16}{27}(1) = -\frac{16}{27} \]

Total Area = Upper – Lower:

\[ -\frac{136}{27}e^{-3} – \left( -\frac{16}{27} \right) \] \[ = \frac{16}{27} – \frac{136}{27}e^{-3} \]

✓ (M1) Using limits
✓ (A1) Correct answer

\[ \frac{1}{V(25-V)} \equiv \frac{A}{V} + \frac{B}{25-V} \] \[ 1 \equiv A(25-V) + BV \]

Let \( V = 0 \): \( 1 = 25A \implies A = \frac{1}{25} \)

Let \( V = 25 \): \( 1 = 25B \implies B = \frac{1}{25} \)

\[ \frac{1}{V(25-V)} = \frac{1}{25V} + \frac{1}{25(25-V)} \]

✓ (M1 A1) Correct fractions

\[ \frac{1}{V(25-V)} \mathrm{d}V = \frac{1}{10} \mathrm{d}t \]

Using part (a):

\[ \int \left( \frac{1}{25V} + \frac{1}{25(25-V)} \right) \mathrm{d}V = \int \frac{1}{10} \mathrm{d}t \]

Multiply by 25 to simplify:

\[ \int \left( \frac{1}{V} + \frac{1}{25-V} \right) \mathrm{d}V = \int \frac{25}{10} \mathrm{d}t \] \[ \ln|V| – \ln|25-V| = 2.5t + C \] \[ \ln \left| \frac{V}{25-V} \right| = 2.5t + C \]

✓ (M1 A1ft) Integration

Initial condition: \( t = 0, V = 20 \).

\[ \ln \left| \frac{20}{25-20} \right| = 0 + C \] \[ \ln(4) = C \]

Equation is: \( \ln \left( \frac{V}{25-V} \right) = 2.5t + \ln 4 \)

✓ (M1) Using boundary condition

When \( V = 24 \):

\[ \ln \left( \frac{24}{25-24} \right) = 2.5t + \ln 4 \] \[ \ln 24 = 2.5t + \ln 4 \] \[ 2.5t = \ln 24 – \ln 4 = \ln \left( \frac{24}{4} \right) = \ln 6 \] \[ t = \frac{\ln 6}{2.5} \text{ hours} \]

Question asks for minutes (\( \times 60 \)):

\[ \text{Time} = \frac{\ln 6}{2.5} \times 60 = 24 \ln 6 \] \[ \approx 43 \text{ minutes} \]

✓ (dM1) Solving for t
✓ (A1) Correct value

\[ \ln \left( \frac{V}{25-V} \right) = 2.5t + \ln 4 \]

Exponentiate:

\[ \frac{V}{25-V} = e^{2.5t + \ln 4} = e^{2.5t} \cdot e^{\ln 4} = 4e^{2.5t} \] \[ V = 4e^{2.5t}(25-V) \] \[ V = 100e^{2.5t} – 4Ve^{2.5t} \] \[ V + 4Ve^{2.5t} = 100e^{2.5t} \] \[ V(1 + 4e^{2.5t}) = 100e^{2.5t} \] \[ V = \frac{100e^{2.5t}}{1 + 4e^{2.5t}} \]

To match form \( \frac{A}{e^{-kt} + B} \), divide numerator and denominator by \( e^{2.5t} \):

\[ V = \frac{100}{e^{-2.5t} + 4} \]

So \( A = 100, B = 4, k = 2.5 \).

✓ (M1) Removing logs
✓ (M1) Rearranging
✓ (A1) Correct form

As \( t \to \infty \), \( e^{-2.5t} \to 0 \).

\[ V \to \frac{100}{0 + 4} = 25 \]

\( L = 25 \) microlitres.

✓ (B1) Value 25
✓ (B1) Valid reason

\[ P = ab^t \] \[ \log_{10} P = \log_{10} (ab^t) \] \[ \log_{10} P = \log_{10} a + \log_{10} (b^t) \] \[ \log_{10} P = \log_{10} a + t \log_{10} b \]

Compare with \( y = c + mx \) where \( y = \log_{10} P \) and \( x = t \).

• Intercept \( c = \log_{10} a = 0.81 \)
• Gradient \( m = \log_{10} b = 0.0054 \)

✓ (M1) Correct log structure

Find \( a \):

\[ \log_{10} a = 0.81 \implies a = 10^{0.81} \approx 6.457 \]

Find \( b \):

\[ \log_{10} b = 0.0054 \implies b = 10^{0.0054} \approx 1.013 \]

✓ (A1 A1) Correct values to 3dp

(i) \( a \) is the value of \( P \) when \( t = 0 \) (year 2004).

Interpretation: The world population in 2004 was approximately 6.46 billion.

(ii) \( b \) is the multiplier for each year.

Interpretation: The population increases by approximately 1.3% each year (or factor of 1.013).

✓ (B1 B1) Correct interpretations

Year 2030 is \( 2030 – 2004 = 26 \) years after start.

\[ t = 26 \] \[ P = 6.457 \times (1.013)^{26} \] \[ P \approx 9.03 \text{ billion} \]

✓ (M1) Substituting t=26
✓ (A1) Correct answer

We are predicting for 2030 using data from 2004-2007.

Comment: Unreliable because it involves significant extrapolation (2030 is far outside the data range).

✓ (B1) Extrapolation mentioned

\[ x^2 – 6x + y^2 + 14y + 33 = 0 \] \[ (x-3)^2 – 9 + (y+7)^2 – 49 + 33 = 0 \] \[ (x-3)^2 + (y+7)^2 – 25 = 0 \] \[ (x-3)^2 + (y+7)^2 = 25 \]

(i) Centre: \( (3, -7) \)

(ii) Radius \( r_1 = \sqrt{25} = 5 \)

✓ (B1) Centre
✓ (M1 A1) Method & Radius

Centre \( C_1 \): \( P(3, -7) \), \( r_1 = 5 \).

Centre \( C_2 \): \( Q(-6, -8) \), \( r_2 = k \).

Distance \( d = PQ \):

\[ d = \sqrt{(3 – (-6))^2 + (-7 – (-8))^2} \] \[ d = \sqrt{9^2 + 1^2} = \sqrt{81 + 1} = \sqrt{82} \]

✓ (M1 A1) Correct distance

Condition 1 (Touching externally): \( r_1 + r_2 > d \implies 5 + k > \sqrt{82} \implies k > \sqrt{82} – 5 \).

Wait, for intersection (2 points), we need \( k + 5 > \sqrt{82} \) AND \( |k-5| < \sqrt{82} \).

Let’s visualise. Circles touch externally if \( r_1 + r_2 = d \). They touch internally if \( |r_1 – r_2| = d \).

Intersection occurs strictly between these limits.

Lower Limit (External touch): \( 5 + k = \sqrt{82} \implies k = \sqrt{82} – 5 \).

Upper Limit (Internal touch): \( k – 5 = \sqrt{82} \implies k = \sqrt{82} + 5 \). (Assuming \( k > 5 \))

Or \( 5 – k = \sqrt{82} \implies k = 5 – \sqrt{82} \) (Reject as \( k>0 \)).

Range: \( \sqrt{82} – 5 < k < \sqrt{82} + 5 \).

✓ (dM1) Setting up inequalities
✓ (A1) Correct limits

\[ \{ k : \sqrt{82} – 5 < k < \sqrt{82} + 5 \} \]

✓ (A1) Correct notation

LHS: \( \frac{\mathrm{d}}{\mathrm{d}x} (x+y)^3 = 3(x+y)^2 (1 + \frac{\mathrm{d}y}{\mathrm{d}x}) \)

RHS: \( \frac{\mathrm{d}}{\mathrm{d}x} (3x^2 – 3y – 2) = 6x – 3\frac{\mathrm{d}y}{\mathrm{d}x} \)

Equate:

\[ 3(x+y)^2 (1 + \frac{\mathrm{d}y}{\mathrm{d}x}) = 6x – 3\frac{\mathrm{d}y}{\mathrm{d}x} \]

Expand LHS:

\[ 3(x+y)^2 + 3(x+y)^2 \frac{\mathrm{d}y}{\mathrm{d}x} = 6x – 3\frac{\mathrm{d}y}{\mathrm{d}x} \]

Group \( \frac{\mathrm{d}y}{\mathrm{d}x} \) terms:

\[ 3(x+y)^2 \frac{\mathrm{d}y}{\mathrm{d}x} + 3\frac{\mathrm{d}y}{\mathrm{d}x} = 6x – 3(x+y)^2 \] \[ \frac{\mathrm{d}y}{\mathrm{d}x} [3(x+y)^2 + 3] = 6x – 3(x+y)^2 \] \[ \frac{\mathrm{d}y}{\mathrm{d}x} = \frac{6x – 3(x+y)^2}{3(x+y)^2 + 3} \]

Simplify by dividing by 3:

\[ \frac{\mathrm{d}y}{\mathrm{d}x} = \frac{2x – (x+y)^2}{(x+y)^2 + 1} \]

✓ (M1 A1) LHS Diff
✓ (A1) RHS Diff
✓ (M1 A1) Rearranging

At \( P(1, 0) \), substitute \( x=1, y=0 \) into the derivative:

\[ \frac{\mathrm{d}y}{\mathrm{d}x} = \frac{2(1) – (1+0)^2}{(1+0)^2 + 1} \] \[ \frac{\mathrm{d}y}{\mathrm{d}x} = \frac{2 – 1}{1 + 1} = \frac{1}{2} \]

The tangent gradient is \( m_T = 1/2 \).

The normal gradient \( m_N = -1 / m_T = -2 \).

Equation of normal: \( y – y_1 = m_N(x – x_1) \)

\[ y – 0 = -2(x – 1) \] \[ y = -2x + 2 \]

(as required)

✓ (M1) Gradient calculation
✓ (A1) Correct proof

Substitute \( y = 2-2x \):

LHS: \( (x + (2-2x))^3 = (2-x)^3 \)

RHS: \( 3x^2 – 3(2-2x) – 2 = 3x^2 – 6 + 6x – 2 = 3x^2 + 6x – 8 \)

Equate:

\[ (2-x)^3 = 3x^2 + 6x – 8 \]

Expand LHS: \( 8 – 12x + 6x^2 – x^3 \)

\[ 8 – 12x + 6x^2 – x^3 = 3x^2 + 6x – 8 \]

Rearrange to form a cubic equation (= 0):

\[ x^3 – 3x^2 + 18x – 16 = 0 \]

We know \( x=1 \) is a root (since P is on the line and curve). Use synthetic division or algebraic division by \( (x-1) \).

\[ (x-1)(x^2 – 2x + 16) = 0 \]

Now check the quadratic \( x^2 – 2x + 16 \) for roots using the discriminant \( \Delta = b^2 – 4ac \).

\[ \Delta = (-2)^2 – 4(1)(16) \] \[ \Delta = 4 – 64 = -60 \]

Since \( \Delta < 0 \), the quadratic has no real roots.

Therefore, \( x=1 \) is the only real solution. The normal does not meet \( C \) again.

✓ (M1) Substitution
✓ (dM1) Cubic equation
✓ (ddM1) Factoring out (x-1)
✓ (A1) Discriminant logic
✓ (A1) Conclusion