Proof of Lemma: Every nonzero integer can be written as a product of primesComplete induction proof that every $n > 1$ can be written as a product of primesWhat's wrong with this proof of the infinity of primes?Induction Proof - Primes and Euclid's LemmaEuclid's proof of Infinitude of Primes: If a prime divides an integer, why would it have to divide 1?Proof or disproof that every integer can be written as the sum of a prime and a square.Prove two subsequent primes cannot be written as a product of two primesProof by well ordering: Every positive integer greater than one can be factored as a product of primes.Difficult Q: Show that every integer $n$ can be written in the form $n = a^2 b$….product of distinct primesWhy is the proof not right ? Every positive integer can be written as a product of primes?Proof by well ordering: Every positive integer greater than one can be factored as a product of primes. Part II

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Proof of Lemma: Every nonzero integer can be written as a product of primes


Complete induction proof that every $n > 1$ can be written as a product of primesWhat's wrong with this proof of the infinity of primes?Induction Proof - Primes and Euclid's LemmaEuclid's proof of Infinitude of Primes: If a prime divides an integer, why would it have to divide 1?Proof or disproof that every integer can be written as the sum of a prime and a square.Prove two subsequent primes cannot be written as a product of two primesProof by well ordering: Every positive integer greater than one can be factored as a product of primes.Difficult Q: Show that every integer $n$ can be written in the form $n = a^2 b$….product of distinct primesWhy is the proof not right ? Every positive integer can be written as a product of primes?Proof by well ordering: Every positive integer greater than one can be factored as a product of primes. Part II













2












$begingroup$


I'm new to number theory. This might be kind of a silly question, so I'm sorry if it is.



I encountered the classic lemma about every nonzero integer being the product of primes in a textbook about number theory. In this textbook there is also a proof for it provided, and I'd like to understand why it is that the proof actually works.



The proof is as follows:




Assume, for contradiction, that there is an integer $N$ that cannot be written as a product of primes. Let $N$ be the smallest positive integer with this property. Since $N$ cannot itself be prime we must have $N = mn$, where $1 < m$, $n < N$. However, since $m$, $n$ are positive and smaller than $N$ they must each be a product of primes. But then so is $N = mn$. This is a contradiction.




I feel like this proof kind of presupposes the lemma. I think this line of reasoning could be strengthened using induction, and I've seen other proofs of this lemma that use induction. Can someone help me out? What am I missing and why do I think that this proof of the lemma is circular?










share|cite|improve this question









New contributor




Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







$endgroup$







  • 2




    $begingroup$
    That argument is by induction. the result is easy to check for small numbers, so assume it holds up to $N-1$. Then $N$ is either prime, in which case we are done, or it factors as $atimes b$ with $1<a≤b<N-1$ and you can apply the inductive hypothesis to $a,b$. Same argument.
    $endgroup$
    – lulu
    2 hours ago






  • 1




    $begingroup$
    There is nothing missing in this proof. It is just fine. And why “two primes”?
    $endgroup$
    – José Carlos Santos
    2 hours ago










  • $begingroup$
    @JoséCarlosSantos Typo. Fixed.
    $endgroup$
    – Alena Gusakov
    1 hour ago










  • $begingroup$
    It's not circular, but it could be a lot clearer. It's not strictly necessary to say $n > 1$, since $m$ is positive and $mn$ is also positive.
    $endgroup$
    – Robert Soupe
    1 hour ago















2












$begingroup$


I'm new to number theory. This might be kind of a silly question, so I'm sorry if it is.



I encountered the classic lemma about every nonzero integer being the product of primes in a textbook about number theory. In this textbook there is also a proof for it provided, and I'd like to understand why it is that the proof actually works.



The proof is as follows:




Assume, for contradiction, that there is an integer $N$ that cannot be written as a product of primes. Let $N$ be the smallest positive integer with this property. Since $N$ cannot itself be prime we must have $N = mn$, where $1 < m$, $n < N$. However, since $m$, $n$ are positive and smaller than $N$ they must each be a product of primes. But then so is $N = mn$. This is a contradiction.




I feel like this proof kind of presupposes the lemma. I think this line of reasoning could be strengthened using induction, and I've seen other proofs of this lemma that use induction. Can someone help me out? What am I missing and why do I think that this proof of the lemma is circular?










share|cite|improve this question









New contributor




Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







$endgroup$







  • 2




    $begingroup$
    That argument is by induction. the result is easy to check for small numbers, so assume it holds up to $N-1$. Then $N$ is either prime, in which case we are done, or it factors as $atimes b$ with $1<a≤b<N-1$ and you can apply the inductive hypothesis to $a,b$. Same argument.
    $endgroup$
    – lulu
    2 hours ago






  • 1




    $begingroup$
    There is nothing missing in this proof. It is just fine. And why “two primes”?
    $endgroup$
    – José Carlos Santos
    2 hours ago










  • $begingroup$
    @JoséCarlosSantos Typo. Fixed.
    $endgroup$
    – Alena Gusakov
    1 hour ago










  • $begingroup$
    It's not circular, but it could be a lot clearer. It's not strictly necessary to say $n > 1$, since $m$ is positive and $mn$ is also positive.
    $endgroup$
    – Robert Soupe
    1 hour ago













2












2








2





$begingroup$


I'm new to number theory. This might be kind of a silly question, so I'm sorry if it is.



I encountered the classic lemma about every nonzero integer being the product of primes in a textbook about number theory. In this textbook there is also a proof for it provided, and I'd like to understand why it is that the proof actually works.



The proof is as follows:




Assume, for contradiction, that there is an integer $N$ that cannot be written as a product of primes. Let $N$ be the smallest positive integer with this property. Since $N$ cannot itself be prime we must have $N = mn$, where $1 < m$, $n < N$. However, since $m$, $n$ are positive and smaller than $N$ they must each be a product of primes. But then so is $N = mn$. This is a contradiction.




I feel like this proof kind of presupposes the lemma. I think this line of reasoning could be strengthened using induction, and I've seen other proofs of this lemma that use induction. Can someone help me out? What am I missing and why do I think that this proof of the lemma is circular?










share|cite|improve this question









New contributor




Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







$endgroup$




I'm new to number theory. This might be kind of a silly question, so I'm sorry if it is.



I encountered the classic lemma about every nonzero integer being the product of primes in a textbook about number theory. In this textbook there is also a proof for it provided, and I'd like to understand why it is that the proof actually works.



The proof is as follows:




Assume, for contradiction, that there is an integer $N$ that cannot be written as a product of primes. Let $N$ be the smallest positive integer with this property. Since $N$ cannot itself be prime we must have $N = mn$, where $1 < m$, $n < N$. However, since $m$, $n$ are positive and smaller than $N$ they must each be a product of primes. But then so is $N = mn$. This is a contradiction.




I feel like this proof kind of presupposes the lemma. I think this line of reasoning could be strengthened using induction, and I've seen other proofs of this lemma that use induction. Can someone help me out? What am I missing and why do I think that this proof of the lemma is circular?







elementary-number-theory prime-numbers proof-explanation integers






share|cite|improve this question









New contributor




Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.











share|cite|improve this question









New contributor




Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.









share|cite|improve this question




share|cite|improve this question








edited 1 hour ago









Robert Soupe

11.4k21950




11.4k21950






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Check out our Code of Conduct.









asked 2 hours ago









Alena GusakovAlena Gusakov

112




112




New contributor




Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.





New contributor





Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.






Alena Gusakov is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







  • 2




    $begingroup$
    That argument is by induction. the result is easy to check for small numbers, so assume it holds up to $N-1$. Then $N$ is either prime, in which case we are done, or it factors as $atimes b$ with $1<a≤b<N-1$ and you can apply the inductive hypothesis to $a,b$. Same argument.
    $endgroup$
    – lulu
    2 hours ago






  • 1




    $begingroup$
    There is nothing missing in this proof. It is just fine. And why “two primes”?
    $endgroup$
    – José Carlos Santos
    2 hours ago










  • $begingroup$
    @JoséCarlosSantos Typo. Fixed.
    $endgroup$
    – Alena Gusakov
    1 hour ago










  • $begingroup$
    It's not circular, but it could be a lot clearer. It's not strictly necessary to say $n > 1$, since $m$ is positive and $mn$ is also positive.
    $endgroup$
    – Robert Soupe
    1 hour ago












  • 2




    $begingroup$
    That argument is by induction. the result is easy to check for small numbers, so assume it holds up to $N-1$. Then $N$ is either prime, in which case we are done, or it factors as $atimes b$ with $1<a≤b<N-1$ and you can apply the inductive hypothesis to $a,b$. Same argument.
    $endgroup$
    – lulu
    2 hours ago






  • 1




    $begingroup$
    There is nothing missing in this proof. It is just fine. And why “two primes”?
    $endgroup$
    – José Carlos Santos
    2 hours ago










  • $begingroup$
    @JoséCarlosSantos Typo. Fixed.
    $endgroup$
    – Alena Gusakov
    1 hour ago










  • $begingroup$
    It's not circular, but it could be a lot clearer. It's not strictly necessary to say $n > 1$, since $m$ is positive and $mn$ is also positive.
    $endgroup$
    – Robert Soupe
    1 hour ago







2




2




$begingroup$
That argument is by induction. the result is easy to check for small numbers, so assume it holds up to $N-1$. Then $N$ is either prime, in which case we are done, or it factors as $atimes b$ with $1<a≤b<N-1$ and you can apply the inductive hypothesis to $a,b$. Same argument.
$endgroup$
– lulu
2 hours ago




$begingroup$
That argument is by induction. the result is easy to check for small numbers, so assume it holds up to $N-1$. Then $N$ is either prime, in which case we are done, or it factors as $atimes b$ with $1<a≤b<N-1$ and you can apply the inductive hypothesis to $a,b$. Same argument.
$endgroup$
– lulu
2 hours ago




1




1




$begingroup$
There is nothing missing in this proof. It is just fine. And why “two primes”?
$endgroup$
– José Carlos Santos
2 hours ago




$begingroup$
There is nothing missing in this proof. It is just fine. And why “two primes”?
$endgroup$
– José Carlos Santos
2 hours ago












$begingroup$
@JoséCarlosSantos Typo. Fixed.
$endgroup$
– Alena Gusakov
1 hour ago




$begingroup$
@JoséCarlosSantos Typo. Fixed.
$endgroup$
– Alena Gusakov
1 hour ago












$begingroup$
It's not circular, but it could be a lot clearer. It's not strictly necessary to say $n > 1$, since $m$ is positive and $mn$ is also positive.
$endgroup$
– Robert Soupe
1 hour ago




$begingroup$
It's not circular, but it could be a lot clearer. It's not strictly necessary to say $n > 1$, since $m$ is positive and $mn$ is also positive.
$endgroup$
– Robert Soupe
1 hour ago










2 Answers
2






active

oldest

votes


















2












$begingroup$

The proof is not circular, the key is in the second sentence: Let N be the smallest positive integer with this property.



We are allowed to say a least $N$ exists because of the well-ordering principle.






share|cite|improve this answer









$endgroup$












  • $begingroup$
    I don't know if it's because of the well-ordering principle ... that's like using a hammer to slice through butter. One does not need the full strength of the AOC to prove such a simple statement.
    $endgroup$
    – Don Thousand
    1 hour ago










  • $begingroup$
    @Don What's AOC? I presume you're not talking about Alexandria Ocasio-Cortez.
    $endgroup$
    – Robert Soupe
    1 hour ago










  • $begingroup$
    @RobertSoupe: Axiom of choice. The more usual abbreviation is AC.
    $endgroup$
    – Nate Eldredge
    17 mins ago











  • $begingroup$
    @DonThousand: I think "well-ordering principle" here refers to the statement "the usual ordering on the natural numbers is a well order". The Axiom of Choice equivalent is "every set admits an ordering which is a well order" - that wouldn't really even help with this proof, since it would only tell us that there is some ordering of the natural numbers which is a well order - it doesn't tell us that the usual ordering is one.
    $endgroup$
    – Nate Eldredge
    15 mins ago


















2












$begingroup$

Although the proof by contradiction is correct, your feeling of unease is fine, because the direct proof by induction is so much clearer:




Take an integer $N$. If $N$ is prime, there is nothing to prove. Otherwise, we must have $N = mn$, where $1 < m, n < N$. By induction, since $m, n$ are smaller than $N$, they must each be a product of primes. Then so is $N = mn$. Done.







share|cite|improve this answer









$endgroup$












    Your Answer





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    2 Answers
    2






    active

    oldest

    votes








    2 Answers
    2






    active

    oldest

    votes









    active

    oldest

    votes






    active

    oldest

    votes









    2












    $begingroup$

    The proof is not circular, the key is in the second sentence: Let N be the smallest positive integer with this property.



    We are allowed to say a least $N$ exists because of the well-ordering principle.






    share|cite|improve this answer









    $endgroup$












    • $begingroup$
      I don't know if it's because of the well-ordering principle ... that's like using a hammer to slice through butter. One does not need the full strength of the AOC to prove such a simple statement.
      $endgroup$
      – Don Thousand
      1 hour ago










    • $begingroup$
      @Don What's AOC? I presume you're not talking about Alexandria Ocasio-Cortez.
      $endgroup$
      – Robert Soupe
      1 hour ago










    • $begingroup$
      @RobertSoupe: Axiom of choice. The more usual abbreviation is AC.
      $endgroup$
      – Nate Eldredge
      17 mins ago











    • $begingroup$
      @DonThousand: I think "well-ordering principle" here refers to the statement "the usual ordering on the natural numbers is a well order". The Axiom of Choice equivalent is "every set admits an ordering which is a well order" - that wouldn't really even help with this proof, since it would only tell us that there is some ordering of the natural numbers which is a well order - it doesn't tell us that the usual ordering is one.
      $endgroup$
      – Nate Eldredge
      15 mins ago















    2












    $begingroup$

    The proof is not circular, the key is in the second sentence: Let N be the smallest positive integer with this property.



    We are allowed to say a least $N$ exists because of the well-ordering principle.






    share|cite|improve this answer









    $endgroup$












    • $begingroup$
      I don't know if it's because of the well-ordering principle ... that's like using a hammer to slice through butter. One does not need the full strength of the AOC to prove such a simple statement.
      $endgroup$
      – Don Thousand
      1 hour ago










    • $begingroup$
      @Don What's AOC? I presume you're not talking about Alexandria Ocasio-Cortez.
      $endgroup$
      – Robert Soupe
      1 hour ago










    • $begingroup$
      @RobertSoupe: Axiom of choice. The more usual abbreviation is AC.
      $endgroup$
      – Nate Eldredge
      17 mins ago











    • $begingroup$
      @DonThousand: I think "well-ordering principle" here refers to the statement "the usual ordering on the natural numbers is a well order". The Axiom of Choice equivalent is "every set admits an ordering which is a well order" - that wouldn't really even help with this proof, since it would only tell us that there is some ordering of the natural numbers which is a well order - it doesn't tell us that the usual ordering is one.
      $endgroup$
      – Nate Eldredge
      15 mins ago













    2












    2








    2





    $begingroup$

    The proof is not circular, the key is in the second sentence: Let N be the smallest positive integer with this property.



    We are allowed to say a least $N$ exists because of the well-ordering principle.






    share|cite|improve this answer









    $endgroup$



    The proof is not circular, the key is in the second sentence: Let N be the smallest positive integer with this property.



    We are allowed to say a least $N$ exists because of the well-ordering principle.







    share|cite|improve this answer












    share|cite|improve this answer



    share|cite|improve this answer










    answered 2 hours ago









    Edgar Jaramillo RodriguezEdgar Jaramillo Rodriguez

    1065




    1065











    • $begingroup$
      I don't know if it's because of the well-ordering principle ... that's like using a hammer to slice through butter. One does not need the full strength of the AOC to prove such a simple statement.
      $endgroup$
      – Don Thousand
      1 hour ago










    • $begingroup$
      @Don What's AOC? I presume you're not talking about Alexandria Ocasio-Cortez.
      $endgroup$
      – Robert Soupe
      1 hour ago










    • $begingroup$
      @RobertSoupe: Axiom of choice. The more usual abbreviation is AC.
      $endgroup$
      – Nate Eldredge
      17 mins ago











    • $begingroup$
      @DonThousand: I think "well-ordering principle" here refers to the statement "the usual ordering on the natural numbers is a well order". The Axiom of Choice equivalent is "every set admits an ordering which is a well order" - that wouldn't really even help with this proof, since it would only tell us that there is some ordering of the natural numbers which is a well order - it doesn't tell us that the usual ordering is one.
      $endgroup$
      – Nate Eldredge
      15 mins ago
















    • $begingroup$
      I don't know if it's because of the well-ordering principle ... that's like using a hammer to slice through butter. One does not need the full strength of the AOC to prove such a simple statement.
      $endgroup$
      – Don Thousand
      1 hour ago










    • $begingroup$
      @Don What's AOC? I presume you're not talking about Alexandria Ocasio-Cortez.
      $endgroup$
      – Robert Soupe
      1 hour ago










    • $begingroup$
      @RobertSoupe: Axiom of choice. The more usual abbreviation is AC.
      $endgroup$
      – Nate Eldredge
      17 mins ago











    • $begingroup$
      @DonThousand: I think "well-ordering principle" here refers to the statement "the usual ordering on the natural numbers is a well order". The Axiom of Choice equivalent is "every set admits an ordering which is a well order" - that wouldn't really even help with this proof, since it would only tell us that there is some ordering of the natural numbers which is a well order - it doesn't tell us that the usual ordering is one.
      $endgroup$
      – Nate Eldredge
      15 mins ago















    $begingroup$
    I don't know if it's because of the well-ordering principle ... that's like using a hammer to slice through butter. One does not need the full strength of the AOC to prove such a simple statement.
    $endgroup$
    – Don Thousand
    1 hour ago




    $begingroup$
    I don't know if it's because of the well-ordering principle ... that's like using a hammer to slice through butter. One does not need the full strength of the AOC to prove such a simple statement.
    $endgroup$
    – Don Thousand
    1 hour ago












    $begingroup$
    @Don What's AOC? I presume you're not talking about Alexandria Ocasio-Cortez.
    $endgroup$
    – Robert Soupe
    1 hour ago




    $begingroup$
    @Don What's AOC? I presume you're not talking about Alexandria Ocasio-Cortez.
    $endgroup$
    – Robert Soupe
    1 hour ago












    $begingroup$
    @RobertSoupe: Axiom of choice. The more usual abbreviation is AC.
    $endgroup$
    – Nate Eldredge
    17 mins ago





    $begingroup$
    @RobertSoupe: Axiom of choice. The more usual abbreviation is AC.
    $endgroup$
    – Nate Eldredge
    17 mins ago













    $begingroup$
    @DonThousand: I think "well-ordering principle" here refers to the statement "the usual ordering on the natural numbers is a well order". The Axiom of Choice equivalent is "every set admits an ordering which is a well order" - that wouldn't really even help with this proof, since it would only tell us that there is some ordering of the natural numbers which is a well order - it doesn't tell us that the usual ordering is one.
    $endgroup$
    – Nate Eldredge
    15 mins ago




    $begingroup$
    @DonThousand: I think "well-ordering principle" here refers to the statement "the usual ordering on the natural numbers is a well order". The Axiom of Choice equivalent is "every set admits an ordering which is a well order" - that wouldn't really even help with this proof, since it would only tell us that there is some ordering of the natural numbers which is a well order - it doesn't tell us that the usual ordering is one.
    $endgroup$
    – Nate Eldredge
    15 mins ago











    2












    $begingroup$

    Although the proof by contradiction is correct, your feeling of unease is fine, because the direct proof by induction is so much clearer:




    Take an integer $N$. If $N$ is prime, there is nothing to prove. Otherwise, we must have $N = mn$, where $1 < m, n < N$. By induction, since $m, n$ are smaller than $N$, they must each be a product of primes. Then so is $N = mn$. Done.







    share|cite|improve this answer









    $endgroup$

















      2












      $begingroup$

      Although the proof by contradiction is correct, your feeling of unease is fine, because the direct proof by induction is so much clearer:




      Take an integer $N$. If $N$ is prime, there is nothing to prove. Otherwise, we must have $N = mn$, where $1 < m, n < N$. By induction, since $m, n$ are smaller than $N$, they must each be a product of primes. Then so is $N = mn$. Done.







      share|cite|improve this answer









      $endgroup$















        2












        2








        2





        $begingroup$

        Although the proof by contradiction is correct, your feeling of unease is fine, because the direct proof by induction is so much clearer:




        Take an integer $N$. If $N$ is prime, there is nothing to prove. Otherwise, we must have $N = mn$, where $1 < m, n < N$. By induction, since $m, n$ are smaller than $N$, they must each be a product of primes. Then so is $N = mn$. Done.







        share|cite|improve this answer









        $endgroup$



        Although the proof by contradiction is correct, your feeling of unease is fine, because the direct proof by induction is so much clearer:




        Take an integer $N$. If $N$ is prime, there is nothing to prove. Otherwise, we must have $N = mn$, where $1 < m, n < N$. By induction, since $m, n$ are smaller than $N$, they must each be a product of primes. Then so is $N = mn$. Done.








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