The pair of square numbers that gives 73 is 8 and 1, as (8^2 = 64) and (1^2 = 1). When you add these together, (64 + 1 = 73). Therefore, the square numbers 64 and 1 combine to equal 73.
9 is not a prime. 73 is a prime.
There is an infinite number of combinations to do this. The most obvious is 1 x 73
The square root of 73 lies between the whole numbers 8 and 9. This is because (8^2 = 64) and (9^2 = 81), and since 73 is between 64 and 81, (\sqrt{73}) falls between 8 and 9.
The square root of 73 lies between the integers 8 and 9. This is because (8^2 = 64) and (9^2 = 81), so (8 < \sqrt{73} < 9).
1 x 73, 73 x 1 = 73
The square root of 73 is between 8 and 9.
9 is not a prime. 73 is a prime.
17 and 19
The two square numbers that make 73 are 64 (8^2) and 9 (3^2). To find this, you can start by taking the square root of 73, which is approximately 8.544. The closest square numbers to this are 64 and 81, with 64 being the square of 8 and 81 being the square of 9.
There is an infinite number of combinations to do this. The most obvious is 1 x 73
The square root of 73 lies between the whole numbers 8 and 9. This is because (8^2 = 64) and (9^2 = 81), and since 73 is between 64 and 81, (\sqrt{73}) falls between 8 and 9.
1 and 73
The square root of 73 lies between the integers 8 and 9. This is because (8^2 = 64) and (9^2 = 81), so (8 < \sqrt{73} < 9).
1 x 73, 73 x 1 = 73
A reversible prime is a number such as 37, where reversing the order of the digits gives 73 which is also a prime.
1 and 73
Three equivalent ratios for 73 can be found by multiplying or dividing by the same number. For example, multiplying by 2 gives 146, so one ratio is 73:146. Dividing by 1 gives 73:73, and multiplying by 3 gives 219, resulting in another ratio of 73:219. Thus, the ratios are 73:73, 73:146, and 73:219.