1.6: Exponents and Square Roots (2024)

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    • 1.6: Exponents and Square Roots (1)
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    Learning Objectives

    • Interpret exponential notation with positive integer exponents.
    • Calculate the \(n\)th power of a real number.
    • Calculate the exact and approximate value of the square root of a real number.

    Exponential Notation and Positive Integer Exponents

    If a number is repeated as a factor numerous times, then we can write the product in a more compact form using exponential notation. For example,

    \(5\cdot 5\cdot 5\cdot 5=5^{4}\)

    The base is the factor, and the positive integer exponent indicates the number of times the base is repeated as a factor. In the above example, the base is \(5\) and the exponent is \(4\). In general, if \(a\) is the base that is repeated as a factor \(n\) times, then

    1.6: Exponents and Square Roots (2)

    Figure \(\PageIndex{1}\)

    When the exponent is \(2\), we call the result a square. For example,

    \(3^{2}=3\cdot 3=9\)

    The number \(3\) is the base and the integer \(2\) is the exponent. The notation \(3^{2}\) can be read two ways: “three squared” or “\(3\) raised to the second power.” The base can be any real number.

    It is important to study the difference between the ways the last two examples are calculated. In the example \((−7)^{2}\), the base is \(−7\) as indicated by the parentheses. In the example \(−5^{2}\), the base is \(5\), not \(−5\), so only the \(5\) is squared and the result remains negative. To illustrate this, write

    \(-5^{2}=-1\cdot 5^{2}=-1\cdot 5\cdot 5=-25\)

    This subtle distinction is very important because it determines the sign of the result.

    The textual notation for exponents is usually denoted using the caret \((^)\) symbol as follows:

    \(\begin{aligned}8^{2}&=8\wedge 2=8*8=64 \\ -5.1^{2}&=-5.1\wedge 2=-5.1*5.1=-26.01 \end{aligned}\)

    The square of an integer is called a perfect square. The ability to recognize perfect squares is useful in our study of algebra. The squares of the integers from \(1\) to \(15\) should be memorized. A partial list of perfect squares follows:

    \(\{0,1,4,9,16,25,36,49,64,81,100,121,144,169,196,225,...\}\)

    Exercise \(\PageIndex{1}\)

    Simplify

    \((−12)^{2}\).

    Answer

    \(144\)

    When the exponent is \(3\) we call the result a cube. For example,

    \(3^{3}=3\cdot 3\cdot 3=27\)

    The notation \(3^{3}\) can be read two ways: “three cubed” or “\(3\) raised to the third power.” As before, the base can be any real number.

    Note that the result of cubing a negative number is negative. The cube of an integer is called a perfect cube. The ability to recognize perfect cubes is useful in our study of algebra. The cubes of the integers from \(1\) to \(10\) should be memorized. A partial list of perfect cubes follows:

    \(\{0,1,8,27,64,125,216,343,512,729,1000,...\}\)

    If the exponent is greater than \(3\), then the notation an is read “a raised to the \(n\)th power.”

    \(\begin{aligned} 10^{6}&=10\cdot 10\cdot 10\cdot 10\cdot 10\cdot 10=1,000,000 \\ (-1)^{4}&=(-1)(-1)(-1)(-1)=1 \\ \left(\frac{1}{3} \right)^{5}&=\frac{1}{3}\cdot \frac{1}{3}\cdot \frac{1}{3}\cdot \frac{1}{3}\cdot \frac{1}{3} =\frac{1}{243} \end{aligned}\)

    Notice that the result of a negative base with an even exponent is positive. The result of a negative base with an odd exponent is negative. These facts are often confused when negative numbers are involved. Study the following four examples carefully:

    The base is \((-2)\) The base is \(2\)
    \(\begin{array}{c}{(-2)^{4}=(-2)\cdot (-2)\cdot (-2)\cdot (-2)=+16} \\ {(-2)^{3}=(-2)\cdot (-2)\cdot (-2)=-8} \end{array}\) \(\begin{array}{c}{-2^{4}=-2\cdot 2\cdot 2\cdot 2=-16}\\{-2^{3}=-2\cdot 2\cdot 2=-8} \end{array}\)
    Table \(\PageIndex{1}\)

    The parentheses indicate that the negative number is to be used as the base.

    Example \(\PageIndex{1}\)

    Calculate:

    1. \(\left(-\frac{1}{3} \right)^{3}\)
    2. \(\left(-\frac{1}{3} \right)^{4}\)

    Solution:

    The base is \(−\frac{1}{3}\) for both problems.

    a. Use the base as a factor three times.

    \(\begin{aligned} \left(-\frac{1}{3} \right)^{3}&=\left(-\frac{1}{3} \right)\left(-\frac{1}{3} \right)\left(-\frac{1}{3} \right) \\ &=-\frac{1}{27} \end{aligned}\)

    b. Use the base as a factor four times.

    \(\begin{aligned} \left(-\frac{1}{3} \right)^{4}&=\left(-\frac{1}{3} \right)\left(-\frac{1}{3} \right)\left(-\frac{1}{3} \right)\left(-\frac{1}{3} \right) \\ &=+\frac{1}{81} \end{aligned}\)

    Answer:

    a. \(-\frac{1}{27}\); b. \(\frac{1}{81}\)

    Exercise \(\PageIndex{3}\)

    Simplify:

    \(−10^{4}\) and \((−10)^{4}\).

    Answer

    \(−10,000\) and \(10,000\)

    Square Root of a Real Number

    Think of finding the square root of a number as the inverse of squaring a number. In other words, to determine the square root of \(25\) the question is, “What number squared equals \(25\)?” Actually, there are two answers to this question, \(5\) and \(−5\).

    \(5^{2}=25\quad\text{and}(-5)^{2}=25\)

    When asked for the square root of a number, we implicitly mean the principal (nonnegative) square root. Therefore we have,

    \(\sqrt{a^{2}}=a\), if \(a\geq 0\) or more generally \(\sqrt{a^{2}}=|a|\)

    As an example, \(\sqrt{25}=5\), which is read “square root of \(25\) equals \(5\).” The symbol \(√\) is called the radical sign and \(25\) is called the radicand. The alternative textual notation for square roots follows:

    \(\sqrt{16}=text{sqrt}(16)=4\)

    It is also worthwhile to note that

    \(\sqrt{1}=1\quad\text{and}\quad\sqrt{0}=0\)

    This is the case because \(1^{2}=1\) and \(0^{2}=0\).

    Example \(\PageIndex{2}\)

    Simplify:

    \(\sqrt{10,000}\).

    Solution:

    \(10,000\) is a perfect square because \(100⋅100=10,000\).

    \(\begin{aligned} \sqrt{10,000}&=\sqrt{(100)^{2}} \\ &=100 \end{aligned}\)

    Answer:

    \(100\)

    Example \(\PageIndex{3}\)

    Simplify:

    \(\sqrt{\frac{1}{9}}\).

    Solution:

    Here we notice that \(\frac{1}{9}\) is a square because \(\frac{1}{3}⋅\frac{1}{3}=\frac{1}{9}\).

    \(\begin{aligned} \sqrt{\frac{1}{9}}&=\sqrt{\left(\frac{1}{3} \right)^{2}} \\ &=\frac{1}{3} \end{aligned}\)

    Answer:

    \(\frac{1}{3}\)

    Given \(a\) and \(b\) as positive real numbers, use the following property to simplify square roots whose radicands are not squares:

    \(\sqrt{a\cdot b}=\sqrt{a}\cdot\sqrt{b}\)

    The idea is to identify the largest square factor of the radicand and then apply the property shown above. As an example, to simplify \(\sqrt{8}\) notice that \(8\) is not a perfect square. However, \(8=4⋅2\) and thus has a perfect square factor other than \(1\). Apply the property as follows:

    \(\begin{aligned} \sqrt{8}&=\sqrt{4\cdot 2} \\ &=\color{Cerulean}{\sqrt{4}}\color{black}{\cdot\sqrt{2}} \\ &=\color{Cerulean}{2}\color{black}{\cdot\sqrt{2}}\\&=2\sqrt{2} \end{aligned}\)

    Here \(2\sqrt{2}\) is a simplified irrational number. You are often asked to find an approximate answer rounded off to a certain decimal place. In that case, use a calculator to find the decimal approximation using either the original problem or the simplified equivalent.

    \(\sqrt{8}=2\sqrt{2}\approx 2.83\)

    On a calculator, try \(2.83\wedge 2\). What do you expect? Why is the answer not what you would expect?

    It is important to mention that the radicand must be positive. For example, \(\sqrt{−9}\) is undefined since there is no real number that when squared is negative. Try taking the square root of a negative number on your calculator. What does it say?

    Note

    Taking the square root of a negative number is defined later in the course.

    Example \(\PageIndex{4}\)

    Simplify and give an approximate answer rounded to the nearest hundredth:

    \(\sqrt{75}\).

    Solution:

    The radicand \(75\) can be factored as \(25 ⋅ 3\) where the factor \(25\) is a perfect square.

    \(\begin{aligned} \sqrt{75}&=\sqrt{25\cdot 3}&\color{Cerulean}{The\:largest\:perfect\:square} \\ &=\color{Cerulean}{\sqrt{25}}\color{black}{\cdot\sqrt{3}}&\color{Cerulean}{factor\:of\:75\:is\:25.} \\ &=\color{Cerulean}{5}\color{black}{\cdot\sqrt{3}} \\ &=5\sqrt{3} &\color{Cerulean}{Exact\:answer} \\ &\approx 8.66 &\color{Cerulean}{Approximate\:answer} \end{aligned}\)

    Answer:

    \(\sqrt{75}\approx 8.66\)

    As a check, calculate (\sqrt{75}\) and \(5\sqrt{3}\) on a calculator and verify that the both results are approximately \(8.66\).

    Example \(\PageIndex{5}\)

    Simplify:

    \(\sqrt{180}\).

    Solution:

    \(\begin{aligned} \sqrt{180}&=\sqrt{36\cdot 5} \\ &=\color{Cerulean}{\sqrt{36}}\color{black}{\cdot\sqrt{5}} \\ &=\color{Cerulean}{6}\color{black}{\cdot\sqrt{5}} \\ &=6\sqrt{5} \end{aligned}\)

    Since the question did not ask for an approximate answer, we present the exact answer.

    Answer:

    \(6\sqrt{5}\)

    Example \(\PageIndex{6}\)

    Simplify:

    \(-5\sqrt{162}\).

    Solution:

    \(\begin{aligned} -5\sqrt{162}&=-5\cdot\sqrt{81\cdot 2} \\ &=-5\cdot\color{Cerulean}{\sqrt{81}}\color{black}{\cdot\sqrt{2}} \\ &=-5\cdot\color{Cerulean}{9}\color{black}{\cdot\sqrt{2}} \\ &=-45\cdot\sqrt{2} \\ &=-45\sqrt{2} \end{aligned}\)

    Answer:

    \(-45\sqrt{2}\)

    Exercise \(\PageIndex{4}\)

    Simplify and give an approximate answer rounded to the nearest hundredth:

    \(\sqrt{128}\).

    Answer

    \(8\sqrt{2}≈11.31\)

    A right triangle is a triangle where one of the angles measures \(90°\). The side opposite the right angle is the longest side, called the hypotenuse, and the other two sides are called legs. Numerous real-world applications involve this geometric figure. The Pythagorean theorem states that given any right triangle with legs measuring \(a\) and \(b\) units, the square of the measure of the hypotenuse c is equal to the sum of the squares of the measures of the legs: \(a^{2}+b^{2}=c^{2}\). In other words, the hypotenuse of any right triangle is equal to the square root of the sum of the squares of its legs.

    1.6: Exponents and Square Roots (3)

    Figure \(\PageIndex{1}\)

    Example \(\PageIndex{7}\)

    If the two legs of a right triangle measure \(3\) units and \(4\) units, then find the length of the hypotenuse.

    Solution:

    Given the lengths of the legs of a right triangle, use the formula \(c=\sqrt{a^{2}+b^{2}}\) to find the length of the hypotenuse.

    1.6: Exponents and Square Roots (4)

    Figure \(\PageIndex{2}\)

    \(\begin{aligned} c&=\sqrt{a^{2}+b^{2}} \\ c&=\sqrt{3^{2}+4^{2}} \\ &=\sqrt{9+16} \\ &=\sqrt{25} \\ &=5 \end{aligned}\)

    Answer:

    \(c=5\) units

    When finding the hypotenuse of a right triangle using the Pythagorean theorem, the radicand is not always a perfect square.

    Example \(\PageIndex{8}\)

    If the two legs of a right triangle measure \(2\) units and \(6\) units, find the length of the hypotenuse.

    Solution:

    1.6: Exponents and Square Roots (5)

    Figure \(\PageIndex{3}\)

    \(\begin{aligned} c&=\sqrt{a^{2}+b^{2}} \\ &=\sqrt{2^{2}+6^{2}} \\ &=\sqrt{4+36} \\ &=\sqrt{40} \\ &=\sqrt{4\cdot 10} \\&=\sqrt{4}\cdot\sqrt{10} \\ &=2\cdot\sqrt{10} \end{aligned}\)

    Answer:

    \(c=2\sqrt{10}\) units

    Key Takeaways

    • When using exponential notation \(a^{n}\), the base \(a\) is used as a factor \(n\) times.
    • When the exponent is \(2\), the result is called a square. When the exponent is \(3\), the result is called a cube.
    • Memorize the squares of the integers up to \(15\) and the cubes of the integers up to \(10\). They will be used often as you progress in your study of algebra.
    • When negative numbers are involved, take care to associate the exponent with the correct base. Parentheses group a negative number raised to some power.
    • A negative base raised to an even power is positive.
    • A negative base raised to an odd power is negative.
    • The square root of a number is a number that when squared results in the original number. The principal square root is the positive square root.
    • Simplify a square root by looking for the largest perfect square factor of the radicand. Once a perfect square is found, apply the property \(\sqrt{a⋅b}=\sqrt{a}⋅\sqrt{b}\), where \(a\) and \(b\) are nonnegative, and simplify.
    • Check simplified square roots by calculating approximations of the answer using both the original problem and the simplified answer on a calculator to verify that the results are the same.
    • Find the length of the hypotenuse of any right triangle given the lengths of the legs using the Pythagorean theorem.

    Exercise \(\PageIndex{5}\) Square of a Number

    Simplify.

    1. \(10^{2}\)
    2. \(12^{2}\)
    3. \((−9)^{2}\)
    4. \(−12^{2}\)
    5. \(11^{2}\)
    6. \((−20)^{2}\)
    7. \(0^{2}\)
    8. \(1^{2}\)
    9. \(−(−8)^{2}\)
    10. \(−(13)^{2}\)
    11. \((\frac{1}{2})^{2}\)
    12. \((−\frac{2}{3})^{2}\)
    13. \(0.5^{2}\)
    14. \(1.25^{2}\)
    15. \((−2.6)^{2}\)
    16. \(−(−5.1)^{2}\)
    17. \((2\frac{1}{3})^{2}\)
    18. \((5\frac{3}{4})^{2}\)
    Answer

    1. \(100\)

    3. \(81\)

    5. \(121\)

    7. \(0\)

    9. \(−64\)

    11. \(\frac{1}{4}\)

    13. \(.25\)

    15. \(6.76\)

    17. \(5\frac{4}{9}\)

    Exercise \(\PageIndex{6}\) Square of a Number

    If \(s\) is the length of the side of a square, then the area is given by \(A=s^{2}\).

    1. Determine the area of a square given that a side measures \(5\) inches.
    2. Determine the area of a square given that a side measures \(2.3\) feet.
    3. List all the squares of the integers \(0\) through \(15\).
    4. List all the squares of the integers from \(−15\) to \(0\).
    5. List the squares of all the rational numbers in the set \(\{0, \frac{1}{3}, \frac{2}{3}, 1, \frac{4}{3}, \frac{5}{3}, 2\}\).
    6. List the squares of all the rational numbers in the set \(\{0, \frac{1}{2}, 1, \frac{3}{2}, 2, \frac{5}{2}\}\).
    Answer

    1. \(25\) square inches

    3. \(\{0, 1, 4, 9, 16, 25, 36, 49, 64, 81, 100, 121, 144, 169, 196, 225\}\)

    5. \(\{0, \frac{1}{9}, \frac{4}{9}, 1, \frac{16}{9}, \frac{25}{9}, 4\}\)

    Exercise \(\PageIndex{7}\) Integer Exponents

    Simplify.

    1. \(5^{3}\)
    2. \(2^{6}\)
    3. \((−1)^{4}\)
    4. \((−3)^{3}\)
    5. \(−1^{4}\)
    6. \((−2)^{4}\)
    7. \(−7^{3}\)
    8. \((−7)^{3}\)
    9. \(−(−3)^{3}\)
    10. \(−(−10)^{4}\)
    11. \((−1)^{20}\)
    12. \((−1)^{21}\)
    13. \((−6)^{3}\)
    14. \(−3^{4}\)
    15. \(1^{100}\)
    16. \(0^{100}\)
    17. \(−(\frac{1}{2})^{3}\)
    18. \((\frac{1}{2})^{6}\)
    19. \((\frac{5}{2})^{3}\)
    20. \((−\frac{3}{4})^{4}\)
    21. List all the cubes of the integers \(−5\) through \(5\).
    22. List all the cubes of the integers from \(−10\) to \(0\).
    23. List all the cubes of the rational numbers in the set \(\{−\frac{2}{3}, −\frac{1}{3}, 0, \frac{1}{3}, \frac{2}{3}\}\).
    24. List all the cubes of the rational numbers in the set \(\{−\frac{3}{7}, −\frac{1}{7}, 0, \frac{1}{7}, \frac{3}{7}\}\).
    Answer

    1. \(125\)

    3. \(1\)

    5. \(−1\)

    7. \(−343\)

    9. \(27\)

    11. \(1\)

    13. \(−216\)

    15. \(1\)

    17. \(−\frac{1}{8}\)

    19. \(\frac{12}{58}\)

    21. \(\{−125, −64, −27, −8, −1, 0, 1, 8, 27, 64, 125\}\)

    23. \(\{−\frac{8}{27}, −\frac{1}{27}, 0, \frac{1}{27}, \frac{8}{27}\}\)

    Exercise \(\PageIndex{8}\) Square Root of a Number

    Determine the exact answer in simplified form.

    1. \(\sqrt{121}\)
    2. \(\sqrt{81}\)
    3. \(\sqrt{100}\)
    4. \(\sqrt{169}\)
    5. \(−\sqrt{25}\)
    6. \(−\sqrt{144}\)
    7. \(\sqrt{12}\)
    8. \(\sqrt{27}\)
    9. \(\sqrt{45}\)
    10. \(\sqrt{50}\)
    11. \(\sqrt{98}\)
    12. \(\sqrt{2000}\)
    13. \(\sqrt{\frac{1}{4}}\)
    14. \(\sqrt{\frac{9}{16}}\)
    15. \(\sqrt{\frac{5}{9}}\)
    16. \(\sqrt{\frac{8}{36}}\)
    17. \(\sqrt{0.64}\)
    18. \(\sqrt{0.81}\)
    19. \(\sqrt{30^{2}}\)
    20. \(\sqrt{15^{2}}\)
    21. \(\sqrt{(−2)^{2}}\)
    22. \(\sqrt{(−5)^{2}}\)
    23. \(\sqrt{−9}\)
    24. \(\sqrt{−16}\)
    25. \(3\sqrt{16}\)
    26. \(5\sqrt{18}\)
    27. \(−2\sqrt{36}\)
    28. \(−3\sqrt{32}\)
    29. \(6\sqrt{200}\)
    30. \(10\sqrt{27}\)
    Answer

    1. \(11\)

    3. \(10\)

    5. \(−5\)

    7. \(2\sqrt{3}\)

    9. \(3\sqrt{5}\)

    11. \(7\sqrt{2}\)

    13. \(\frac{1}{2}\)

    15. \(5\sqrt{3}\)

    17. \(0.8\)

    19. \(30\)

    21. \(2\)

    23. Not real

    25. \(12\)

    27. \(−12\)

    29. \(60\sqrt{2}\)

    Exercise \(\PageIndex{9}\) Square Root of a Number

    Approximate the following to the nearest hundredth.

    1. \(\sqrt{2}\)
    2. \(\sqrt{3}\)
    3. \(\sqrt{10}\)
    4. \(\sqrt{15}\)
    5. \(2\sqrt{3}\)
    6. \(5\sqrt{2}\)
    7. \(−6\sqrt{5}\)
    8. \(-4\sqrt{6}\)
    9. \(\sqrt{79}\)
    10. \(\sqrt{54}\)
    11. \(−\sqrt{162}\)
    12. \(−\sqrt{86}\)
    13. If the two legs of a right triangle measure \(6\) units and \(8\) units, then find the length of the hypotenuse.
    14. If the two legs of a right triangle measure \(5\) units and \(12\) units, then find the length of the hypotenuse.
    15. If the two legs of a right triangle measure \(9\) units and \(12\) units, then find the length of the hypotenuse.
    16. If the two legs of a right triangle measure \(\frac{3}{2}\) units and \(2\) units, then find the length of the hypotenuse.
    17. If the two legs of a right triangle both measure \(1\) unit, then find the length of the hypotenuse.
    18. If the two legs of a right triangle measure \(1\) unit and \(5\) units, then find the length of the hypotenuse.
    19. If the two legs of a right triangle measure \(2\) units and \(4\) units, then find the length of the hypotenuse.
    20. If the two legs of a right triangle measure \(3\) units and \(9\) units, then find the length of the hypotenuse.
    Answer

    1. \(1.41\)

    3. \(3.16\)

    5. \(3.46\)

    7. \(−13.42\)

    9. \(8.89\)

    11. \(−12.73\)

    13. \(10\) units

    15. \(15\) units

    17. \(\sqrt{2}\) units

    19. \(2\sqrt{5}\) units

    Exercise \(\PageIndex{10}\) Discussion Board Topics

    1. Why is the result of an exponent of \(2\) called a square? Why is the result of an exponent of \(3\) called a cube?
    2. Research and discuss the history of the Pythagorean theorem.
    3. Research and discuss the history of the square root.
    4. Discuss the importance of the principal square root.
    Answer

    1. Answers may vary

    3. Answers may vary

    1.6: Exponents and Square Roots (2024)

    FAQs

    Is an exponent of 1 2 the same as square root? ›

    Any exponent of (1/2) is actually the square root of that number. Hence, x to the power of 1/2 can be written as √x.

    How do you solve square roots with exponents? ›

    1) If the expression consists of a variable raised to an even power, the square root of the expression equals the variable raised to one-half of that power. Examples: 2) If the variable contains an odd power, express it as the product of two factors, one having an exponent 1 and the other with an even exponent.

    What is the square root of 1.69 simplified? ›

    Answer and Explanation:

    The square root of 1.69 is 1.3. To find this, we can use the definition of a square root and a little trial and error.

    What is 1.5 square root? ›

    √(1.5) ≈ 1.2241,

    and the real value, provided by our calculator, is √(1.5) ≈ 1.2247.

    What exponent is equal to square root? ›

    The square root of a number is the same as raising that number to the power of 1/2. This is because of the exponent formula: n√x = x^(1/n). When n = 2, we call it square root . For example, √n = n^(1/2), where n is a positive integer .

    What is 1 2 with an exponent of 2? ›

    Answer: 1/2 to the power of 2 is 1/4 or 0.25. Let's solve this question by using the exponent rules.

    What is the rule for roots and powers? ›

    How do you solve roots with power? Roots can be transformed in powers by raising the radicand to the power of a fraction, in which the numerator is the exponent (usually 1) of the radicand and the denominator will be the index of the radical. For example, the square root of 2 will be the power 2^1/2.

    How do you convert exponents to roots? ›

    Convert from Exponential to Radical Form:

    Remember the denominator of the fractional exponent will become the root of the radical, and the numerator will become the power. Create the power first and then the root. Create the root first and then the power. Either way, you will have a correct answer.

    Is 1.69 a perfect square? ›

    The square root of a perfect square decimal is either a terminating decimal or a repeating decimal. Use a calculator to find the square root of each number. The square root is the terminating decimal 1.3. So, 1.69 is a perfect square.

    What is a √ 169? ›

    What is the Square root of 169? The square root of 169 is 13, i.e. √169 = 13.

    How is √2 solved? ›

    √2 = 1.41421356237309504880168872420969807856967187537694

    For general use, its value is truncated and is used as 1.414 to make calculations easy. The fraction 99/70 is also sometimes used as the value of √2.

    Why is the power of 0.5 square root? ›

    Equations like x + 3 = 7 all have simple solutions in our list of known numbers. But when we try to solve x + 3 = 2 we don't say, “There is no answer”. Thus the one-half power is the inverse of squaring, that is the one-half power is the same as the square root.

    Is a fraction exponent a square root? ›

    You can do the same thing with multiplying anything with the denominator 2, the numerator just tells you how many times to add. “Are fractional exponents just a notation for square roots.” No. the exponent 1/2 means square root.

    Can square root be written as 1/2? ›

    Square root of a number x is written as √x not 1/2 . Therefore , 1/2 means on 1 divided by 2 . It is the number raise to 1/2 that is the square root of the number.

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