A negative exponent is a mathematical notation that represents the reciprocal or inverse of a number raised to a positive exponent. It is used to express very small or fractional values in a concise manner, particularly in the context of integer exponents and scientific notation.
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When a number is raised to a negative exponent, it is equivalent to taking the reciprocal of that number raised to the corresponding positive exponent.
Negative exponents can be used to represent very small or fractional values, making them useful in scientific and mathematical applications.
In the context of integer exponents, negative exponents are used to represent the inverse or reciprocal of a number, rather than a power of that number.
Negative exponents are particularly important in the context of scientific notation, where they are used to express very small values in a concise and easily readable format.
The rules for manipulating negative exponents are similar to those for positive exponents, with the key difference being that the exponent is negative, indicating the reciprocal of the value.
Review Questions
Explain how a negative exponent is related to the reciprocal of a number.
$x^{-n} = \frac{1}{x^n}$. This means that a negative exponent represents the reciprocal or inverse of a number raised to the corresponding positive exponent. For example, $2^{-3}$ is equivalent to $\frac{1}{2^3} = \frac{1}{8}$. The negative exponent indicates that the value should be inverted or taken as the reciprocal of the base number raised to the positive exponent.
Describe the role of negative exponents in the context of scientific notation.
Negative exponents are essential in scientific notation, which is used to express very small or very large numbers in a compact and easily readable format. When a number is expressed in scientific notation, the negative exponent indicates that the value is a fraction or a very small number. For example, $4.2 \times 10^{-5}$ represents a value that is 4.2 divided by 100,000, or 0.000042. The negative exponent allows for the efficient representation of tiny values in scientific and mathematical applications.
Analyze how the rules for manipulating negative exponents differ from those for positive exponents.
The rules for manipulating negative exponents are similar to those for positive exponents, with the key difference being the reciprocal nature of the values. For example, the rule for multiplying numbers with the same base but different exponents is $x^a \times x^b = x^{a+b}$. However, with negative exponents, this rule becomes $x^{-a} \times x^{-b} = x^{-(a+b)}$, which is equivalent to $\frac{1}{x^{a+b}}$. This reflects the fact that negative exponents represent the reciprocal of the value, rather than a power of the base number.