Applying Combined Exponents Rules: Using variables

Factoring Out the Greatest Common Factor (GCF)More than one unknownWorded problemsThe power of zeroVariable in the exponent of the powerComplete the equationUsing laws of exponents with parametersFactorizationMultiplying Exponents with the same baseconverting Negative Exponents to Positive ExponentsNumber of termsPresenting powers with negative exponents as fractionsTrinomialIdentify the greater valuePresenting powers in the denominator as powers with negative exponentsTwo VariablesVariables in the exponent of the powerUsing the laws of exponentsSingle VariableBinomialVariable in the base of the powerPresenting powers with negative exponents as fractionsCalculating powers with negative exponentsMonomialApplying the formulaUsing multiple rulesA power law
Question 1

\( 8^{-2x}=\text{?} \)

Question 2

\( a^{-4}=\text{?} \)

\( (a\ne0) \)

Question 3

\( x^{-a}=\text{?} \)

Question 4

Solve the following expression:

\( \frac{1}{a^n}=\text{?} \)

\( a\ne0 \)

Examples with solutions for Applying Combined Exponents Rules: Using variables

Exercise #1

82x=? 8^{-2x}=\text{?}

Video Solution

Step-by-Step Solution

Let's use the law of exponents for negative exponents:

an=1an a^{-n}=\frac{1}{a^n} and apply it to our problem:

82x=182x 8^{-2x}=\frac{1}{8^{2x}} Next, we'll use the law of exponents for power of a power:

(am)n=amn (a^m)^n=a^{m\cdot n} and apply this law to the denominator in the expression we got:

182x=1(82)x=164x \frac{1}{8^{2x}}=\frac{1}{(8^2)^x}=\frac{1}{64^x} where we actually used the above law in the opposite direction, meaning instead of expanding the parentheses and multiplying by the power exponent, we interpreted the multiplication by the power exponent as a power of a power, and in the final stage we calculated the power inside the parentheses in the denominator.

Let's summarize the solution steps, we got that:

82x=182x=164x 8^{-2x}= \frac{1}{8^{2x}}=\frac{1}{64^x}

Therefore, the correct answer is answer D.

Answer

164x \frac{1}{64^x}

Exercise #2

a4=? a^{-4}=\text{?}

(a0) (a\ne0)

Video Solution

Step-by-Step Solution

We begin by using the negative exponent rule.

bn=1bn b^{-n}=\frac{1}{b^n} We apply it to the problem:

a4=1a4 a^{-4}=\frac{1}{a^4} Therefore, the correct answer is option B.

Answer

1a4 \frac{1}{a^4}

Exercise #3

xa=? x^{-a}=\text{?}

Video Solution

Step-by-Step Solution

We use the exponential property of a negative exponent:

bn=1bn b^{-n}=\frac{1}{b^n} We apply it to the problem:

xa=1xa x^{-a}=\frac{1}{x^a} Therefore, the correct answer is option C.

Answer

1xa \frac{1}{x^a}

Exercise #4

Solve the following expression:

1an=? \frac{1}{a^n}=\text{?}

a0 a\ne0

Video Solution

Step-by-Step Solution

This question is actually a proof of the law of exponents for negative exponents. We will prove it by using two other laws of exponents:

a. The zero exponent law, which states that raising any number to the power of 0 (except 0) will give the result 1:

X0=1 X^0=1

b. The law of exponents for division between terms with identical bases:

bmbn=bmn \frac{b^m}{b^n}=b^{m-n}

Let's return to the problem whilst paying attention to two things. The first is that in the denominator of the fraction there is a term with base a a . The second thing is that according to the zero exponent law mentioned above in a' we can always write the number 1 as any number (except 0) to the power of 0. Given that a0 a\neq0 we can state that:

1=a0 1=a^0

Let's apply this to the problem:

1an=a0an \frac{1}{a^n}=\frac{a^0}{a^n}

Now that we have terms with identical bases in the numerator and denominator of the fraction , we can apply the law of division between terms with identical bases mentioned in b' in the problem:

a0an=a0n=an \frac{a^0}{a^n}=a^{0-n}=a^{-n}

Let's summarize the steps above as follows:

1an=a0an=an \frac{1}{a^n}=\frac{a^0}{a^n}=a^{-n}

In other words, we proved the law of exponents for negative exponents and furthermore we understood why the correct answer is answer c.

Answer

an a^{-n}