Powers, Roots & Indices (AQA GCSE Maths)

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Powers & Roots

What are powers/indices?

  • Powers of a number is when that number is multiplied by itself repeatedly
    • 51 means 5
    • 52 means 5 × 5
    • 53 means 5 × 5 × 5
    • Therefore the powers of 5 are 5, 25, 125, etc
  • The big number on the bottom is sometimes called the base number
  • The small number that is raised is called the index or the exponent
  • Any non-zero number to the power of 0 is equal to 1
    • 50 = 1

What are roots?

  • Roots of a number are the opposite of powers
  • A square root of 25 is a number that when squared equals 25
    • The two square roots are 5 and -5 
    • Every positive number has two square roots
      • They will have the same digits but one is positive and one is negative
    • The notation square root of blank end root  refers to the positive square root of a number
      • square root of 25 equals 5
      • You can show both roots at once using the plus or minus symbol ±
      • Square roots of 25 are plus-or-minus square root of 25 equals plus-or-minus 5
    • The square root of a negative number is not a real number
    • The positive square root can be written as an index of 1 half so 25 to the power of 1 half end exponent equals 5
  • cube root of 125 is a number that when cubed equals 125
    • A cube root of 125 is 5
    • Every positive and negative number always has a cube root
    • The notation cube root of blank refers to the cube root of a number
      • cube root of 125 equals 5
    • The cube root can be written as an index of 1 third so 125 to the power of 1 third end exponent equals 5
  • A nth root of a number (n-th root of blank)is a number that when raised to the power n equals the original number
    • If n is even then they work the same way as square roots
      • Every positive number will have a positive and negative nth root
      • The notation n-th root of blank refers to the positive nth root of a number
    • If n is odd then they work the same way as cube roots
      • Every positive and negative number will have an nth root
    • The nth root can be written as an index of 1 over n
  • If you know your powers of numbers then you can use them to find roots of numbers
    • e.g. 2 to the power of 5 equals 32 means fifth root of 32 equals 2
      • You could write this using an index 32 to the power of 1 fifth end exponent equals 2
  • You can also estimate roots by finding the closest powers
    • e.g. 2 cubed equals 8 and 3 cubed equals 27 therefore 2 less than cube root of 20 less than 3

What are reciprocals?

  • The reciprocal of a number is the number that you multiply it by to get 1
    • The reciprocal of 2 is 1 half
    • The reciprocal of 0.25 or 1 fourth is 4
    • The reciprocal of 3 over 2 is 2 over 3
  • The reciprocal of a number can be written as a power with an index of -1
    • 5-1 means the reciprocal of 5
  • This idea can be extended to other negative indices
    • 5-2 means the reciprocal of 52

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Laws of Indices

What are the laws of indices?

  • There are lots of very important laws (or rules)
  • It is important that you know and can apply these
  • Understanding the explanations will help you remember them
Law Description Why
a to the power of 1 equals a anything to the power 1 is itself 6 to the power of 1 equals 6
a to the power of m cross times a to the power of n equals a to the power of m plus n end exponent to multiply indices with the same base, add their powers 4 cubed cross times 4 squared
equals open parentheses 4 cross times 4 cross times 4 close parentheses cross times open parentheses 4 cross times 4 close parentheses
equals 4 to the power of 5
a to the power of m divided by a to the power of n equals a to the power of m over a to the power of n equals a to the power of m minus n end exponent to divide indices with the same base, subtract their powers 7 to the power of 5 divided by 7 cubed
equals fraction numerator 7 cross times 7 cross times up diagonal strike 7 cross times up diagonal strike 7 cross times up diagonal strike 7 over denominator up diagonal strike 7 cross times up diagonal strike 7 cross times up diagonal strike 7 end fraction
equals 7 squared
open parentheses a to the power of m close parentheses to the power of n equals a to the power of m n end exponent to raise indices to a new power, multiply their powers open parentheses 14 cubed close parentheses squared
equals open parentheses 14 cross times 14 cross times 14 close parentheses cross times open parentheses 14 cross times 14 cross times 14 close parentheses
equals 14 to the power of 6
a to the power of 0 equals 1 anything to the power 0 is 1 8 to the power of 0
equals 8 to the power of 2 minus 2 end exponent equals 8 squared divided by 8 squared
equals 8 squared over 8 squared equals 1
a to the power of negative n end exponent equals 1 over a to the power of n a negative power is "1 over" the positive power 11 to the power of negative 3 end exponent
equals 11 to the power of 0 minus 3 end exponent equals 11 to the power of 0 divided by 11 cubed
equals 11 to the power of 0 over 11 cubed equals 1 over 11 cubed
a to the power of 1 over n end exponent equals n-th root of a a power of an nth is an nth root open parentheses 5 to the power of 1 half end exponent close parentheses squared equals 5 to the power of 1 half cross times 2 end exponent equals 5 to the power of 1 equals 5
so space space space 5 to the power of 1 half end exponent equals square root of 5
a to the power of m over n end exponent equals open parentheses n-th root of a close parentheses to the power of m equals n-th root of a to the power of m end root space

a fractional power of m over n means either

- do the the nth root first, then raise it to the power m

or

- raise it to the power m, then take the nth root

(depending on what's easier)

9 to the power of 3 over 2 end exponent equals 9 to the power of 1 half cross times 3 end exponent equals open parentheses 9 to the power of 1 half end exponent close parentheses cubed equals open parentheses square root of 9 close parentheses cubed
or space space 9 to the power of 3 over 2 end exponent equals 9 to the power of 3 cross times 1 half end exponent equals open parentheses 9 cubed close parentheses to the power of 1 half end exponent equals square root of 9 cubed end root
open parentheses a over b close parentheses to the power of n equals a to the power of n over b to the power of n a power outside a fraction applies to both the numerator and the denominator open parentheses 5 over 6 close parentheses to the power of 3 space end exponent
equals 5 over 6 cross times 5 over 6 cross times 5 over 6
equals 5 cubed over 6 cubed
open parentheses a over b close parentheses to the power of negative n end exponent equals open parentheses b over a close parentheses to the power of n equals b to the power of n over a to the power of n flipping the fraction inside changes a negative power into a positive power open parentheses 5 over 6 close parentheses to the power of negative 2 end exponent equals 1 over open parentheses 5 over 6 close parentheses squared equals 1 divided by open parentheses 5 over 6 close parentheses squared equals 1 divided by 5 squared over 6 squared
equals 1 cross times 6 squared over 5 squared equals 6 squared over 5 squared equals open parentheses 6 over 5 close parentheses squared

How do I apply more than one of the laws of indices?

  • Powers can include negatives and fractions
    • These can be dealt with in any order
    • However the following order is easiest as it avoids large numbers
  • If there is a negative sign in the power then deal with that first
    • Take the reciprocal of the base number
    • open parentheses 8 over 27 close parentheses to the power of negative 2 over 3 end exponent equals open parentheses 27 over 8 close parentheses to the power of 2 over 3 end exponent
  • Next deal with the denominator of the fraction of the power
    • Take the root of the base number
    • open parentheses 27 over 8 close parentheses to the power of 2 over 3 end exponent equals open parentheses fraction numerator cube root of 27 over denominator cube root of 8 end fraction close parentheses squared equals open parentheses 3 over 2 close parentheses squared
  • Finally deal with the numerator of the fraction of the power
    • Take the power of the base number
    • open parentheses 3 over 2 close parentheses squared equals 3 squared over 2 squared equals 9 over 4

How do I deal with different bases?

  • Sometimes expressions involve different base values
  • You can use index laws to change the base of a term to simplify an expression involving terms with different bases
    • For example begin mathsize 20px style 9 to the power of 4 equals left parenthesis 3 squared right parenthesis to the power of 4 equals 3 to the power of 2 cross times 4 end exponent equals 3 to the power of 8 end style
    • Using the above can then help with problems like 9 to the power of 4 divided by 3 to the power of 7 equals 3 to the power of 8 divided by 3 to the power of 7 equals 3 to the power of 8 minus 7 end exponent equals 3 to the power of 1 equals space 3

Examiner Tip

  • Index laws only work with terms that have the same base, so something like 23 × 52 cannot be simplified using index laws

Worked example

(a)table row cell blank to the power of blank end cell row blank end table
Without using a calculator, write fraction numerator 7 cubed cross times 7 squared over denominator 7 to the power of 8 end fraction in the form 1 over 7 to the power of k where k is a positive whole number.

Use a to the power of m cross times a to the power of n equals a to the power of m plus n end exponent on the numerator.
 

7 cubed cross times 7 squared equals 7 to the power of 3 plus 2 end exponent equals 7 to the power of 5
 

Use a to the power of m divided by a to the power of n equals a to the power of m minus n end exponent
 

7 to the power of 5 over 7 to the power of 8 equals 7 to the power of 5 minus 8 end exponent equals 7 to the power of negative 3 end exponent
 

Use a to the power of negative n end exponent equals 1 over a to the power of n.
 

7 to the power of negative 3 end exponent equals 1 over 7 cubed
 

The value of k is 3.

bold 1 over bold 7 to the power of bold 3 

(b)table row blank row blank end table
Without using a calculator, simplify open parentheses 4 over 25 close parentheses to the power of negative 3 over 2 end exponent.

Flip the fraction to change the negative outside power into a positive outside power, open parentheses a over b close parentheses to the power of negative n end exponent equals open parentheses b over a close parentheses to the power of n.
 

open parentheses 4 over 25 close parentheses to the power of negative 3 over 2 end exponent equals open parentheses 25 over 4 close parentheses to the power of 3 over 2 end exponent
 

Use that a power outside a fraction applies to both the numerator and denominator, open parentheses a over b close parentheses to the power of n equals a to the power of n over b to the power of n.
 

open parentheses 25 over 4 close parentheses to the power of 3 over 2 end exponent equals 25 to the power of begin display style 3 over 2 end style end exponent over 4 to the power of begin display style 3 over 2 end style end exponent
 

Use that a fractional power of m over n is the nth root all to the power m,  a to the power of m over n end exponent equals open parentheses n-th root of a close parentheses to the power of m.
 

25 to the power of 3 over 2 end exponent equals open parentheses square root of 25 close parentheses cubed equals 5 cubed equals 125  and   4 to the power of 3 over 2 end exponent equals open parentheses square root of 4 close parentheses cubed equals 2 cubed equals 8
 

bold 125 over bold 8

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Dan

Author: Dan

Expertise: Maths

Dan graduated from the University of Oxford with a First class degree in mathematics. As well as teaching maths for over 8 years, Dan has marked a range of exams for Edexcel, tutored students and taught A Level Accounting. Dan has a keen interest in statistics and probability and their real-life applications.