**LET A BE ANY NUMBER EXCEPT 0 AND M AND N BE TWO NATURAL NUMBERS. THEN,**

## First Law of Exponents:

*am × an = a m + n*

### Example 1:

32 × 33 = 32 + 3 = 35 = 243

### Example 2:

*24 × 24 = 28 = 256*

## Second Law of Exponents:

*am / an = am – n*

### Example:

*36/32 = 36 – 2 = 34 = 81*

## Third Law of Exponents:

If a is any number except 0, then

a0 = 1.

### Example 1:

50 = 1

x0 = 1, if x is any number except 0.

### Example 2:

*93/93 = 93 – 3 = 90 = 1*

## Fourth Law of Exponents:

*(am) n = (a)m × n*

### Example 1:

*(22)3 = (2)2 × 3 = 2 6 = 64*

## Fifth Law of Exponents:

*(ab)m = am × bm*

### Example 1:

*(10)5 = (2 × 5)5 = 25 × 55*

## Sixth Law of Exponents:

*(a /b) m = am/bm*

### Example:

*(3/5)3 = 33 / 53 = 27/125*

Very Important rules on exponents:

1. (a) ?m = 1/am

### Example:

*(2) ?4 = 1/24 = 1/16*

*2. (1/a) ?m = 1/ (1/a) m = am*

### Example:

*(1/3) 4 = 34*

*3. (a/b)- m = (b/a) m*

### Example:

*(2/3)?4 = (3/2)4 = 34/24 = 81/16*

*4. (am) 1/n = (am/n )*

### Example:

*(26)1/3 = (26 ×1/3) = 26×1/3 = 22 = 4, *nth root of a number Or A Surd:

Let a be a positive number and n a positive integer. Then the nth root of a is denoted as: nva or (a) 1/n, a1/n is called a Surd of order n.

### Examples:

- the 2nd root of 25 is denoted as 2√25.
*And (25)1/2 = (52)1/2 = 52×1/2 = 52×1/2 = 5* - the 3rd root of 27 is 3√27.
*And (27)1/3 = (27)1/3 = (33)1/3 = 33×1/3 = 33×1/3 = 3* - The 4th root of 16 is 4√16.
*And 4√16 = (16)1/4 = (24)1/4 = 24×1/4 = 24×1/4 = 2* - The mth root of am is m√am = (am)1/m = am×1/m = a

nth root of a negative number: Let a be a negative number, then the nth root of a will exist only if n is a positive odd integer, not when n is a positive even integer.

### Example:

*3rd root of -8 is 3√-8. **And 3√-8 = (-8)1/3 = (-23)1/3 = (-2) 3×1/3 = 23×1/3 = 2. *But, 2nd root of -4 does not exist, since 2 is an even integer and if the exponent is even the base can’t be negative.

**Note:**

the nth root of a positive number “a” is not defined in real numbers if n is an even integer, but nth root of the positive number “a” exists in the set of complex numbers even if n is an even integer. The Table summarizes all the laws of exponents.