1 / 20
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Know the Fundamental Theorem of Algebra

Lesson 9 of 9: Complex Number System

In this lesson:

  • State the Fundamental Theorem of Algebra
  • Demonstrate it for quadratic polynomials (all three cases)
  • Apply it to count roots and factor polynomials
Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

What You Will Learn Today

  1. State the FTA: every degree- polynomial has exactly complex roots (counting multiplicity)
  2. Demonstrate the FTA for quadratics using all three discriminant cases
  3. Explain why real-coefficient polynomials factor into linear complex factors
  4. Explain why odd-degree real-coefficient polynomials must have at least one real root
Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

The Motivation:

Over the real numbers: No solution. .

Over the complex numbers: Two solutions — and .

The Fundamental Theorem of Algebra confirms: every polynomial has exactly roots in .

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

The Pattern You Have Been Observing

Degree Polynomial Roots
2
2
3

Degree gives exactly roots in .

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

The Fundamental Theorem of Algebra

Theorem: Every polynomial of degree has exactly roots in , counted with multiplicity.

Guarantees existence — not a formula for finding roots.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Multiplicity: What "Counting Multiplicity" Means

Multiplicity = how many times a root appears as a factor.

Degree 2 → 2 roots counting multiplicity. FTA ✓

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

The Theorem Guarantees Existence, Not Method

FTA says: Roots exist in .

FTA does NOT say: How to find them.

Degree Method
2 Quadratic formula
3, 4 Cubic/quartic formulas
5+ No general formula (Abel–Ruffini)
Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Demonstrating the FTA for Quadratics

Three-column summary table: Case 1 (discriminant positive) shows x²−5x+6=0 with roots 2 and 3, factored form (x−2)(x−3), count 2. Case 2 (zero) shows x²−4x+4=0 with root 2 (repeated), factored form (x−2)², count 2. Case 3 (negative) shows x²−4x+5=0 with roots 2±i, factored form (x−(2+i))(x−(2−i)), count 2.

All three cases give exactly 2 roots. The FTA holds for all quadratics.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Case 1: Two Real Roots (Positive Discriminant)

Roots: and

Factored form:

Count: 2 real roots. FTA ✓

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Case 2: One Repeated Root (Zero Discriminant)

Root: (multiplicity 2)

Factored form:

Count: 2 roots counting multiplicity. FTA ✓

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Case 3: Two Complex Roots (Negative Discriminant)

Roots: and

Factored form:

Count: 2 complex roots. FTA ✓

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

The Quadratic Proof Is Complete

Discriminant Roots Count
Two distinct real 2
One repeated root 2
Complex conjugate pair 2

Every quadratic has exactly 2 roots in . QED.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Two Common Errors About the FTA

A student says:

  1. "The FTA says every polynomial has real roots."

  2. " has 2 roots: and ."

What is wrong in each? State the correct version.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Complex Roots Come in Conjugate Pairs

For real-coefficient polynomials:

If is a root, then is also a root.

Why: Conjugating gives when coefficients are real.

Complex roots always come in conjugate pairs.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Odd-Degree Polynomials Must Have a Real Root

  • Complex roots pair up → even count
  • Degree is odd → at least one root unpaired
  • That unpaired root must be real

Example: — one real root .

Odd-degree real-coefficient polynomial: real root guaranteed.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Two Cubics: Counting All Three Roots

Both cubics have exactly 3 roots in . FTA holds for degree 3.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Check-In: State and Apply the FTA

  1. State the Fundamental Theorem of Algebra in one sentence.

  2. Explain in one sentence why a degree-7 polynomial with real coefficients must have at least one real root.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

Factor Completely Over

Roots: — two real, two complex.

Count: 4 roots for degree 4. FTA ✓

The theorem predicts the answer before you compute it.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

The Complex Number System: The Full Story

Cluster Content
CN.A.1–3 Define ; arithmetic
CN.B.4–6 Geometry: plane, polar, distance
CN.C.7–9 Algebra: roots, factoring, FTA

The complex numbers are sufficient for all polynomial algebra.

Grade 9 Algebra | HSN.CN.C.9
Know the Fundamental Theorem of Algebra | Lesson 9 of 9

You Have Completed the Complex Number System

The Fundamental Theorem of Algebra:

Every polynomial of degree has exactly roots in , counted with multiplicity.

This is why complex numbers were worth building.

Carl Friedrich Gauss first proved this in 1799. It took new mathematics to do it.

Grade 9 Algebra | HSN.CN.C.9