Why or why not?
According to wikipedia, no. It needs two distinct divisors. So 2 is the first prime number.
No. Integer primes are required to have exactly two positive divisors. One only has itself.
The alternate, more general definition allows a number p to be a prime whenever two conditions are met:
[ol]
[li]There’s no product ab such p divides ab with zero remainder, but p does not divide a and p does not divide b.[/li][li]There’s no number q such that pq = 1.[/li][/ol]
One satisfies the first requirement, but clearly not the second.
Note that one is also not composite. It falls into a separate class known as units, which are those integers that have reciprocals. In the positive integers, one is the only unit, but in the unrestricted integers negative one is also a unit. Just for completeness, let me mention that zero falls in a fourth category, the so-called zero divisors.
I’m not a math person (and you obviously are), but did you mean to say that units are those numbers that are their own reciprocals? Or those numbers that have reciprocals that are also integers? Doesn’t every number have a reciprocal?
In case it’s not clear why one would have both these conditions, note that taken together, they are equivalent to the single clean condition:
[ol]
[li]Whenever p divides a product of finitely many numbers, then p divides one of those numbers.[/li][/ol]
The first condition above is the case for binary products, the second condition is the case for nullary products, and, as usual, these two cases suffice to cover everything else as well.
On edit, to jackelope: Units (in some ring, or whatever context) are those numbers that have reciprocals (in that ring, or whatever context). So within the context of the integers, the units are those integers which have integer reciprocals. Within the context of something else, the units are those whatever elses that have reciprocals that are whatever elses (as the context is one in which we are only talking about whatever elses). In some contexts, everything (non-zero) has a reciprocal (e.g., real numbers), but in many other contexts (e.g., linear transformations upon two-dimensional space, with addition given pointwise and multiplication given by composition, for one natural, if mathy, example) many things don’t.
Thanks, Indistinguishable. That makes sense.
Interesing. I always thought 1 was a prime number because I thought the definition of a prime number is any number that can only be divided by 1 or itself without any remainder. 1 passes that test if you don’t mind that 1 is being divided by 1 in both cases.
Of course I’m no mathematician or really all that good at math at all so there you go.
Nit pick: That was a staff report, and not from Cecil.
I literally just got up and am not so swift this morning, so I am not getting the joke: Not-even, of course, is a mouse. Can anyone fill me in?
“Not-Even, a mouse” equals “not even a mouse”?
Thank you.
Just for the record, 0 is definitely an even number. An even number is, by definition, twice some number and 0 = 2*0 eminently qualifies.
One other comment on the article: Dex is taking the natural numbers to be {1, 2, 3, …}, but a lot of people will regard the natural numbers as {0, 1, 2, 3, …}.
The reason that 1 is not prime has nothing to do with the number of divisors!
1 is a unit in that it can be multiplied be another number (in this case, itself 1) to equal 1. By definition, a unit cannot be prime.
One is not a prime number by definition. What needs to be asked is “why does the definition of prime excludes one?”. The answer to that is that we wish every natural number to have a unique prime factorization. That’s not possible if we can add any number of ones onto the factorization.
For example, without a prime one, 60 = 2[sup]2[/sup] x 3 x 5. That’s unique. If one is prime, we also have 60 = 1 x 2[sup]2[/sup] x 3 x 5 = 1[sup]2[/sup] x 2[sup]2[/sup] x 3 x 5, etc. There’s no unique factorization.
I suspect a lot of other mathematical theorems would have to be rewritten, with “Let p be a prime” changed to “Let p be a prime greater than 1.”
Are you joking? I can’t imagine why someone would say this if he or she wasn’t joking.
Some ring theoretical notions of prime elements or prime ideals might not mention the number of divisors but that’s not being discussed here. The topic of this thread is prime numbers and the the number theoretical definition of such certainly does mention the number of divisors.
Your link does not work.
This should work:
The problem is that if you have a parenthesis at the end of a URL, even if it’s not supposed to be part of the URL, it screws up things. Indeed, if a link doesn’t work, I would suggest that posters try messing around with things like removing and moving parentheses rather than immediately complaining that it doesn’t work. Usually the problem is something small like this.