Factors of 63 are 1, 3, 7, 9, 21, 63. Including 1 and 63 itself, there are 6 distinct factors for 63.
The prime factors of 63 are 3, 7, and its factor pairs are (1, 63), (3, 21), (7, 9). We've put this below in a table for easy sharing.
| Factors of 63: | 1, 3, 7, 9, 21, 63 |
| Prime Factors of 63: | 3, 7 |
| Factor Pairs of 63: | (1, 63), (3, 21), (7, 9) |
How to calculate factors?
To be a factor of 63, a number must divide 63 exactly, leaving no remainder. In other words, when 63 is divided by this number, the quotient is a whole number. These factors, also known as divisors, define the structure of 63 and are key in understanding its mathematical properties.
Below, we outline how to calculate the factorization of 63 using four methods: basic factorization, prime factorization, the division method, or using GCD and LCM. We also include a detailed analysis of factor pairs and a factor tree to illustrate the breakdown.
Method 1: Basic Factorization
Basic Factorization is a method to find the factors of a number by systematically testing each whole number from 2 up to the number itself to see which ones divides with zero remainder (evenly). The process is somewhat time consuming if a number is high, that's why you should master divisibility rules, to make the process faster.
Here's the breakdown for 63:
| Divisor | Is it a factor of 63? | Verification |
|---|---|---|
| 1 | Yes, 1 is a factor of every number. | 1 × 63 = 63 |
| 2 | No, 63 is not an even number so it's not divisible by 2. | - |
| 3 | Yes, the sum of its digits (9) is divisible by 3. | 3 × 21 = 63 |
| 4 | No, the last two digits (63) do not form a number divisible by 4. | - |
| 5 | No, last digit is 3, so not divisible by 5. | - |
| 6 | No, 63 is not divisible by both 2 and 3. | - |
| 7 | Yes, 63 divided by 7 equals 9 with no remainder. | 7 × 9 = 63 |
| 8 | No, the last three digits (63) do not form a number divisible by 8. | - |
| 9 | Yes, the sum of its digits (9) is divisible by 9. | 9 × 7 = 63 |
| 10 | No, last digit is 3, so not divisible by 10. | - |
| 11 | No, the difference between sums of alternating digits (3) is not divisible by 11. | - |
| 12 | No, 63 is not divisible by both 3 and 4. | - |
| ... | continue with all the other numbers. |
Method 2: Prime Factorization
Prime numbers are natural numbers greater than 1 that have no positive divisors other than 1 and themselves. This means a prime number cannot be formed by multiplying two smaller natural numbers. For example:
- 2 is a prime number because its only divisors are 1 and 2.
- 3 is prime for the same reason—it can only be divided evenly by 1 and 3.
- 4 is not prime because it can be divided by 1, 2, and 4.
- 5, 7, 11, and 13 are also prime numbers.
Prime numbers are fundamental in mathematics because they are the "building blocks" of whole numbers. Any natural number greater than 1 can be expressed as a product of prime numbers, which is known as its prime factorization.
How to do prime factorization of 63
You start by dividing 63 to each prime number, multiple times, until the remainder is 0. Then you move on to the next prime number. To save time, you should test with up to \( \sqrt63 \)
| Prime Number | Is it a factor of 63? | Verification |
|---|---|---|
| 2 | No, 63 is not divisible by 2. | - |
| 3 | Yes, 63 is divisible by 3. | 63 ÷ 3 = 21, R0 |
| 3 | Yes, the result 21 is divisible by 3. | 21 ÷ 3 = 7, R0 |
| 3 | No, the result 7 is not divisible by 3. | - |
| 7 | 7 is a prime number. | 7 is prime. |
Method 3: Division Method
The Division Method is a systematic approach to finding all the factors of a 63 by performing successive divisions. This method involves dividing 63 by every integer from 1 up to 63 and identifying the numbers that divide exactly without leaving a remainder. In the table below we've ommitted the numbers that don't divide 63, and only kept those that do:
| Divisor | Verification |
|---|---|
| 1 | 63 ÷ 1 = 63 |
| 3 | 63 ÷ 3 = 21 |
| 7 | 63 ÷ 7 = 9 |
| 9 | 63 ÷ 9 = 7 |
| 21 | 63 ÷ 21 = 3 |
| 63 | 63 ÷ 63 = 1 |
Using the division method, we calculated that factors of 63 are 1, 3, 7, 9, 21, 63.
Factor Tree of 63
The factor tree of 63 shows the step-by-step breakdown of 63 into its prime factors. Each branch of the tree represents a division of 63 into two factors until all resulting factors are prime numbers. This visual representation helps identify the building blocks of 63 and highlights the structure of its prime factorization.
| 63 | ||
| | | \ | |
| 3 | 21 | |
| | | \ | |
| 3 | 7 |
Factor Pairs of 63 (Visualization)
Factor pairs of 63 are sets of two numbers that, when multiplied together, result in 63. Factor pairs are symmetric and mirror around the square root of 63, such as (1, 63) and (63, 1), and can be both positive and negative pairs as long as their product equals 63.
| Negative factor pairs | Positive factor pairs |
|---|---|
| (-1, -63) | (1, 63) |
| (-3, -21) | (3, 21) |
| (-7, -9) | (7, 9) |
All factor pairs of 63 are (1, 63), (3, 21), (7, 9), (-1, -63), (-3, -21), (-7, -9).
Why Should I Care About Factors of 63?
Turns out, factors aren’t just about boring math equations—they’re like secret superpowers hiding inside numbers! Knowing them can help you split things up, share with friends, or even spot hidden patterns. Want to know how? Check out these real-life examples that show just how cool factors really are:
- Sharing Apples: You have 63 apples and want to share them equally among your 1 friends. Each friend will get 63 apples because 1 × 63 = 63.
- Cooking Dinner: You have 63 pieces of chicken to cook. If each person gets 1 pieces, you’ll need to serve 63 people because 1 × 63 = 63.
- Dividing Up a Cake: You have a cake divided into 63 pieces. If each person gets 3 pieces, you’ll serve 21 people because 3 × 21 = 63.
- Arranging Chairs for a Concert: You have 63 chairs for a concert. If you arrange them into 1 rows, each row will have 63 chairs because 1 × 63 = 63.
- Baking Brownies: You have 63 brownies to cut into pieces. If you want each person to get 1 pieces, you’ll serve 63 people because 1 × 63 = 63.