The quotient of two nonzero integers is the definition of a rational number. There are nonzero numbers other than integers (imaginary, rational non-integers) that the quotient of would not be a rational number. If the two nonzero numbers are rational themselves, then the quotient will be rational. (For example, 4 divided by 2 is 2: all of those numbers are rational).
For numbers with ordinary multiplication defined on them, they are the same.
Like denominator is the same denominator as the nonzero numbers.
Five. All nonzero numbers are significant.
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The product of two nonzero whole numbers will be a nonzero whole number.
The LCf of any two nonzero whole numbers is one because every nonzero whole number can be divided by it.
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All nonzero numbers are significant.
The quotient of two nonzero integers is the definition of a rational number. There are nonzero numbers other than integers (imaginary, rational non-integers) that the quotient of would not be a rational number. If the two nonzero numbers are rational themselves, then the quotient will be rational. (For example, 4 divided by 2 is 2: all of those numbers are rational).
A set of non-zero numbers.
One is a factor of all nonzero numbers.
Every nonzero number has multiples. Every set of nonzero numbers has an LCM.
Yes, as long as the two nonzero numbers are themselves rational. (Since a rational number is any number that can be expressed as the quotient of two rational numbers, or any number that can be written as a fraction using only rational numbers.) If one of the nonzero numbers is not rational, the quotient will most likely be irrational.
its negative
All nonzero numbers are significant.
a nonzero is two numbers added together anad they cannot zero