IB Maths AI SL Integration Paper 1 & 2 ∫xⁿ dx ~6 min read

Integrating Powers of x

Integration reverses the power rule for differentiation. Where differentiating drops the power by 1, integrating raises it by 1 — then divides by the new power. This note covers that rule, the special cases, and how to handle sums, fractions and products.

📘 What you need to know

The integration power rule: ∫xⁿ dx = xⁿ⁺¹/(n+1) + c — raise the power by 1, then divide by the new power.
A constant multiplier rides along: ∫axⁿ dx = axⁿ⁺¹/(n+1) + c.
Special case: ∫a dx = ax + c — a constant integrates to that constant times x.
The rule fails when n = −1 — you cannot integrate 1/x this way.
Rewrite first: turn fractions like a/xⁿ into ax⁻ⁿ, and expand any products.
Integrate a sum or difference of powers term by term, and never forget the + c.

The integration power rule

Integration reverses the power rule for differentiation. Differentiating drops the power by 1; integrating does the opposite — it raises the power by 1, then divides by that new power.

The integration power rule ∫ axⁿ dx = axⁿ⁺¹n + 1 + c raise the power by 1, then divide by the new power · n ≠ −1 · given in the formula booklet

To integrate axⁿ: raise the power by 1, then divide by the new power. Below, 4x³ becomes x⁴ + c.

A constant multiplier simply rides along, and — because this is an indefinite integral — the result always ends in + c. The rule is given in the formula booklet.

Special cases and negative powers

A plain constant has its own short rule: integrating a number a gives ax.

Integrating a constant ∫ a dx = ax + c a constant integrates to that constant times x — e.g. ∫4 dx = 4x + c

The power rule also handles negative powers — but a fraction has to be rewritten first. A term like 6/x³ becomes 6x⁻³, which integrates as normal. The one case the rule cannot handle is n = −1: that would mean dividing by zero, so 1/x cannot be integrated this way.

Sums, products and quotients

An expression that is a sum or difference of powers is integrated term by term — integrate each piece separately and add the results, with a single + c at the end.

Products and quotients cannot be integrated term by term as they stand. Expand a product of brackets, or simplify a quotient by dividing through, so that every term is a single power of x — only then does the power rule apply.

🧭 Recipe — integrating an expression

Rewrite every term as a power of x: turn a/xⁿ into ax⁻ⁿ, and expand any brackets.
Take one term at a time — a sum or difference is integrated piece by piece.
Apply the power rule: for each axⁿ, raise the power by 1, then divide by the new power.
Integrate any constant term using ∫a dx = ax.
Add a single + c — and convert negative powers back to fractions if asked.

Worked examples

WE 1

A single power-rule term

Find ∫6x² dx.

raise the power by 1, then divide by the new power 3 ∫6x² dx = 6x³/3 + c ∫6x² dx = 2x³ + c the coefficient 6 rides along; 6 ÷ 3 = 2, and don’t forget the + c.

WE 2

A polynomial, term by term

Find ∫(4x³ − 9x² + 2x − 5) dx.

integrate each term separately 4x³ → 4x⁴/4 = x⁴ −9x² → −9x³/3 = −3x³ 2x → 2x²/2 = x² · −5 → −5x ∫(…) dx = x⁴ − 3x³ + x² − 5x + c the constant −5 integrates to −5x; one + c covers the whole expression.

WE 3

A negative power from a fraction

Find ∫(x² + 6/x³) dx.

rewrite the fraction as a negative power: 6/x³ = 6x⁻³ x² → x³/3 6x⁻³ → 6x⁻²/(−2) = −3x⁻² ∫(…) dx = x³/3 − 3x⁻² + c = x³/3 − 3/x² + c raising the power −3 by 1 gives −2; dividing by −2 flips the sign.

WE 4

A constant and a negative power

Find ∫(8 − 2/x²) dx.

rewrite: 8 − 2x⁻² 8 → 8x (the constant rule) −2x⁻² → −2x⁻¹/(−1) = 2x⁻¹ ∫(…) dx = 8x + 2x⁻¹ + c = 8x + 2/x + c −2 ÷ (−1) = +2, so the sign flips — a common slip with negative powers.

WE 5

A product — expand first

Find ∫3x(x − 4) dx.

a product — expand before integrating 3x(x − 4) = 3x² − 12x 3x² → 3x³/3 = x³ −12x → −12x²/2 = −6x² ∫3x(x − 4) dx = x³ − 6x² + c you cannot integrate a product bracket by bracket — expand to a sum of powers first.

WE 6

Full question: find y, then check it

It is given that dy/dx = 12x³ − 6x + 3/x². (a) Find an expression for y. (b) Verify your answer by differentiating it.

(a) rewrite: dy/dx = 12x³ − 6x + 3x⁻², then integrate 12x³ → 12x⁴/4 = 3x⁴ −6x → −6x²/2 = −3x² 3x⁻² → 3x⁻¹/(−1) = −3x⁻¹ y = 3x⁴ − 3x² − 3/x + c (b) differentiate y to check d/dx(3x⁴ − 3x² − 3x⁻¹ + c) = 12x³ − 6x + 3x⁻² (a) y = 3x⁴ − 3x² − 3/x + c · (b) differentiating gives back 12x³ − 6x + 3/x² integrating a derivative recovers the original function — differentiating your answer is the perfect check.

💡 Top tips

The integration power rule has two moves: raise the power by 1, then divide by the new power.
Never forget the + c — an indefinite integral without it loses a mark.
Rewrite fractions as negative powers before integrating: a/xⁿ becomes ax⁻ⁿ.
The rule fails for n = −1 — 1/x cannot be integrated with the power rule.
Check any integration by differentiating the answer — you should get back what you started with.

⚠ Common mistakes

Forgetting the constant of integration “+ c“.
Raising the power but not dividing by the new power — or dividing by the old one.
Integrating a product or quotient term by term — expand or simplify it first.
Mishandling negative powers: raising −3 by 1 gives −2, and dividing by −2 flips the sign.
Forgetting that a constant integrates to ax, not to 0.

Next up: Finding the Constant of Integration — using a known point to pin down that “+ c” and turn a whole family of curves into one definite answer. The integration rule itself never changes: rewrite every term as a power of x, raise the power, divide by the new power, + c.

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