Exponential Functions and Exponents

💡 Learning Objectives

By the end of this lesson you will be able to:

• State and apply the product, quotient, and power rules of exponents
• Simplify expressions involving zero exponents, negative exponents, and rational exponents
• Recognize the form f(x) = a · bˣ and identify its key features
• Distinguish exponential growth (b > 1) from exponential decay (0 < b < 1)
• Compare the growth of an exponential function with that of a polynomial function
• Apply exponential models to compound interest, population, and decay problems

Product rule

aᵐ · aⁿ = aᵐ⁺ⁿ

x⁴ · x³ = x⁷

Quotient rule

aᵐ / aⁿ = aᵐ⁻ⁿ

x⁷ / x² = x⁵

Power of a power

(aᵐ)ⁿ = aᵐⁿ

(x²)⁵ = x¹⁰

Power of a product

(ab)ⁿ = aⁿbⁿ

(2x)³ = 8x³

Zero exponent

a⁰ = 1, a ≠ 0

7⁰ = 1

Negative exponent

a⁻ⁿ = 1/aⁿ

x⁻³ = 1/x³

Rational exponent

a^(1/n) = ⁿ√a

8^(1/3) = 2

General rational

a^(m/n) = ⁿ√(aᵐ)

8^(2/3) = 4

⚠️ Common mistakes

1. (x + y)ⁿ ≠ xⁿ + yⁿ. There is no shortcut; you must expand the binomial.

2. aᵐ + aⁿ does not simplify to aᵐ⁺ⁿ. Exponent rules apply to multiplication, not addition.

3. A negative exponent does not make the value negative; it takes the reciprocal. For example, 2⁻³ = 1/8 (positive).

📘 Example — Putting the rules together

Simplify ( (3x²y⁻³)² · (xy⁴) ) / (x³y⁻²).

Numerator: (3x²y⁻³)² = 9x⁴y⁻⁶, then (9x⁴y⁻⁶)(xy⁴) = 9x⁵y⁻².

Divide: 9x⁵y⁻² / (x³y⁻²) = 9x² · y⁻²⁺² = 9x² · y⁰ = 9x².

Domain

All real numbers (−∞, ∞)

Range

(0, ∞) when a > 0; (−∞, 0) when a < 0

Horizontal asymptote

y = 0

y-intercept

(0, a)

Growth if b > 1

function increases; rises without bound as x → ∞

Decay if 0 < b < 1

function decreases; approaches 0 as x → ∞

📘 Example — Growth or decay?

• f(x) = 3(1.08)ˣ has b = 1.08, so this is growth.

• g(x) = 100(0.85)ˣ has b = 0.85, so this is decay.

• h(x) = 2 · 5⁻ˣ. Rewrite as 2 · (1/5)ˣ. Base 1/5 < 1, so this is decay.

📘 Example — Identify the key features

For f(x) = 2 · 3^(x − 1) − 4:

Base b = 3 (growth), parent graph shifted 1 right and 4 down.

Horizontal asymptote: y = −4.

y-intercept: f(0) = 2 · 3⁻¹ − 4 = 2/3 − 4 = −10/3.

💡 Eventually, exponentials win

For any polynomial p(x) and any exponential f(x) = bˣ with b > 1, there exists some value of x beyond which f(x) > p(x) and the gap only widens. Exponentials eventually dominate polynomials — even the slow-looking 1.001ˣ will outpace x¹⁰⁰⁰ for large enough x.

💡 Two central formulas

• Compounded n times per year at rate r:

A = P · (1 + r/n)^(n·t).

• Continuously compounded:

A = P · e^(r·t).

Here P is the principal, r is the annual rate expressed as a decimal, and t is time in years.

📘 Example — Comparing compounding frequencies

You invest $1000 for 5 years at a nominal annual rate of 6%.

Annual compounding: 1000 · (1.06)⁵ ≈ $1338.23.

Monthly compounding: 1000 · (1 + 0.06/12)^60 ≈ $1348.85.

Continuous compounding: 1000 · e^(0.06 · 5) ≈ $1349.86.

📘 Example — Radioactive decay

A certain isotope decays so that 5% of the material disappears per hour. Starting with 80 g, the mass t hours later is m(t) = 80 · (0.95)ᵗ.

After 10 hours: m(10) = 80 · (0.95)¹⁰ ≈ 80 · 0.5987 ≈ 47.90 g.