Q: What is the prime factorization of the number 123,282,266?

 A:
  • The prime factors are: 2 x 17 x 89 x 131 x 311
    • or also written as { 2, 17, 89, 131, 311 }
  • Written in exponential form: 21 x 171 x 891 x 1311 x 3111

Why is the prime factorization of 123,282,266 written as 21 x 171 x 891 x 1311 x 3111?

What is prime factorization?

Prime factorization or prime factor decomposition is the process of finding which prime numbers can be multiplied together to make the original number.

Finding the prime factors of 123,282,266

To find the prime factors, you start by dividing the number by the first prime number, which is 2. If there is not a remainder, meaning you can divide evenly, then 2 is a factor of the number. Continue dividing by 2 until you cannot divide evenly anymore. Write down how many 2's you were able to divide by evenly. Now try dividing by the next prime factor, which is 3. The goal is to get to a quotient of 1.

If it doesn't make sense yet, let's try it...

Here are the first several prime factors: 2, 3, 5, 7, 11, 13, 17, 19, 23, 29...

Let's start by dividing 123,282,266 by 2

123,282,266 ÷ 2 = 61,641,133 - No remainder! 2 is one of the factors!
61,641,133 ÷ 2 = 30,820,566.5 - There is a remainder. We can't divide by 2 evenly anymore. Let's try the next prime number
61,641,133 ÷ 3 = 20,547,044.3333 - This has a remainder. 3 is not a factor.
61,641,133 ÷ 5 = 12,328,226.6 - This has a remainder. 5 is not a factor.
61,641,133 ÷ 7 = 8,805,876.1429 - This has a remainder. 7 is not a factor.
...
Keep trying increasingly larger numbers until you find one that divides evenly.
...
61,641,133 ÷ 17 = 3,625,949 - No remainder! 17 is one of the factors!
3,625,949 ÷ 17 = 213,291.1176 - There is a remainder. We can't divide by 17 evenly anymore. Let's try the next prime number
3,625,949 ÷ 19 = 190,839.4211 - This has a remainder. 19 is not a factor.
3,625,949 ÷ 23 = 157,649.9565 - This has a remainder. 23 is not a factor.
3,625,949 ÷ 29 = 125,032.7241 - This has a remainder. 29 is not a factor.
...
Keep trying increasingly larger numbers until you find one that divides evenly.
...
3,625,949 ÷ 89 = 40,741 - No remainder! 89 is one of the factors!
40,741 ÷ 89 = 457.764 - There is a remainder. We can't divide by 89 evenly anymore. Let's try the next prime number
40,741 ÷ 97 = 420.0103 - This has a remainder. 97 is not a factor.
40,741 ÷ 101 = 403.3762 - This has a remainder. 101 is not a factor.
40,741 ÷ 103 = 395.5437 - This has a remainder. 103 is not a factor.
...
Keep trying increasingly larger numbers until you find one that divides evenly.
...
40,741 ÷ 131 = 311 - No remainder! 131 is one of the factors!
311 ÷ 131 = 2.374 - There is a remainder. We can't divide by 131 evenly anymore. Let's try the next prime number
311 ÷ 137 = 2.2701 - This has a remainder. 137 is not a factor.
311 ÷ 139 = 2.2374 - This has a remainder. 139 is not a factor.
311 ÷ 149 = 2.0872 - This has a remainder. 149 is not a factor.
...
Keep trying increasingly larger numbers until you find one that divides evenly.
...
311 ÷ 311 = 1 - No remainder! 311 is one of the factors!

The orange divisor(s) above are the prime factors of the number 123,282,266. If we put all of it together we have the factors 2 x 17 x 89 x 131 x 311 = 123,282,266. It can also be written in exponential form as 21 x 171 x 891 x 1311 x 3111.

Factor Tree

Another way to do prime factorization is to use a factor tree. Below is a factor tree for the number 123,282,266.

123,282,266
Factor Arrows
261,641,133
Factor Arrows
173,625,949
Factor Arrows
8940,741
Factor Arrows
131311

More Prime Factorization Examples

123,282,264123,282,265123,282,267123,282,268
23 x 31 x 71 x 733,823151 x 791 x 312,107131 x 41,094,089122 x 30,820,5671

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