That's a factor pair.
The easiest way is to write the number and a factor of the number. 12 and 24 have an LCM of 24.
Two (assuming you are talking about real numbers). In general, for any given positive number, there will be two real numbers whose absolute value is that given number. In the case of complex numbers, the answer is "infinitely many" - all the numbers on a circle centered on the origin, with that radius, have that absolute value.
Give two numbers whose sum is equal to the given
3 and 84.
That's a factor pair.
The easiest way is to write the number and a factor of the number. 12 and 24 have an LCM of 24.
Two (assuming you are talking about real numbers). In general, for any given positive number, there will be two real numbers whose absolute value is that given number. In the case of complex numbers, the answer is "infinitely many" - all the numbers on a circle centered on the origin, with that radius, have that absolute value.
Give two numbers whose sum is equal to the given
Yes, if a periodic table that includes atomic numbers, as most periodic tables do, is available for reference
3 and 84.
The answer is: 3
You can 'factor' a number to find the numbers whose products make that number.
There are no two numbers whose product is 23 and whose sum is 10. 23 is a prime number, and the only numbers whose product is 23 are 23 and 1. A prime number can only be divided by itself and 1.
There are no 5 odd numbers whose sum is 50. (The sum of 5 odd numbers is an odd number whereas 50 is an even number.)
Fluorine (whose atomic number is 9) and Boron (whose atomic number is 5).
A sequence is a function ! whose domian is the set of natural numbers