Is there a proof of an infinite number of prime numbers using the irrationality of $e$?












4














That the set of prime integers is infinite can be proved using the irrationality of $pi$; see this wikipedia link. It analyzes the representation



$tag 1 {displaystyle {frac {pi }{4}}={frac {3}{4}}times {frac {5}{4}}times {frac {7}{8}}times {frac {11}{12}}times {frac {13}{12}}times {frac {17}{16}}times {frac {19}{20}}times {frac {23}{24}}times {frac {29}{28}}times {frac {31}{32}}times cdots }$



It 'seems only fair' that the same thing can be done using $e$:




Question 1: Has a proof that there are an infinite number of primes been
constructed that uses the irrationality of $e$?




If the existence of such a proof is not available, then




Question 1-1: Is a proof available using any properties of $e$?




If again, no answers, then




Question 2: Can someone show that the set of prime integers is
infinite using properties of Euler's constant?




My work



I found this representation of $e$,



$tag 2 {displaystyle e=1+{cfrac {2}{1+{cfrac {1}{6+{cfrac {1}{10+{cfrac {1}{14+{cfrac {1}{18+{cfrac {1}{22+{cfrac {1}{26+ddots ,}}}}}}}}}}}}}}.}$



Note that with $text{(1)}$ there is a 'corresponding' sequence



$tag 3 4,8,12,16,dots$



and that with $text{(2)}$ we can see



$tag 4 6, 10,14,18,dots$



I just find this interesting; perhaps it supplies a 'connection'.



We know that eventually every prime number will divide a term in the $text{(4)}$ sequence.



If the only primes are contained in the finite set $mathcal P = {2,3,5, dots, p}$, then let $beta = 2 times 3 times 5 times dots times p$.



If we analyze $text{(2)}$ using base $beta$, the expansion of $e$ would eventually be repetitive or simply terminate.



(the statement in bold is an unproven bold statement)










share|cite|improve this question






















  • It's hard to see why one would want to prove it that way, as the usual $1+prod_{i=1}^n p_i$ argument does it easily.
    – Richard Martin
    Nov 22 at 14:46












  • Or, better still, try and figure it out from what I have just said.
    – Richard Martin
    Nov 22 at 14:50










  • @RichardMartin Ok - Euclid's proof. Just interested in seeing a 'later stage' proof.
    – CopyPasteIt
    Nov 22 at 14:52










  • @RichardMartin Someone putting up the wiki article thought it was interesting enough to put down the $pi$ proof...
    – CopyPasteIt
    Nov 22 at 14:53






  • 2




    @RichardMartin More proofs = more fun. But seriously, new proofs to existing theorems are interesting because of any novel ideas they might contain, not because they achieve the same conclusion.
    – Klangen
    Nov 23 at 9:12
















4














That the set of prime integers is infinite can be proved using the irrationality of $pi$; see this wikipedia link. It analyzes the representation



$tag 1 {displaystyle {frac {pi }{4}}={frac {3}{4}}times {frac {5}{4}}times {frac {7}{8}}times {frac {11}{12}}times {frac {13}{12}}times {frac {17}{16}}times {frac {19}{20}}times {frac {23}{24}}times {frac {29}{28}}times {frac {31}{32}}times cdots }$



It 'seems only fair' that the same thing can be done using $e$:




Question 1: Has a proof that there are an infinite number of primes been
constructed that uses the irrationality of $e$?




If the existence of such a proof is not available, then




Question 1-1: Is a proof available using any properties of $e$?




If again, no answers, then




Question 2: Can someone show that the set of prime integers is
infinite using properties of Euler's constant?




My work



I found this representation of $e$,



$tag 2 {displaystyle e=1+{cfrac {2}{1+{cfrac {1}{6+{cfrac {1}{10+{cfrac {1}{14+{cfrac {1}{18+{cfrac {1}{22+{cfrac {1}{26+ddots ,}}}}}}}}}}}}}}.}$



Note that with $text{(1)}$ there is a 'corresponding' sequence



$tag 3 4,8,12,16,dots$



and that with $text{(2)}$ we can see



$tag 4 6, 10,14,18,dots$



I just find this interesting; perhaps it supplies a 'connection'.



We know that eventually every prime number will divide a term in the $text{(4)}$ sequence.



If the only primes are contained in the finite set $mathcal P = {2,3,5, dots, p}$, then let $beta = 2 times 3 times 5 times dots times p$.



If we analyze $text{(2)}$ using base $beta$, the expansion of $e$ would eventually be repetitive or simply terminate.



(the statement in bold is an unproven bold statement)










share|cite|improve this question






















  • It's hard to see why one would want to prove it that way, as the usual $1+prod_{i=1}^n p_i$ argument does it easily.
    – Richard Martin
    Nov 22 at 14:46












  • Or, better still, try and figure it out from what I have just said.
    – Richard Martin
    Nov 22 at 14:50










  • @RichardMartin Ok - Euclid's proof. Just interested in seeing a 'later stage' proof.
    – CopyPasteIt
    Nov 22 at 14:52










  • @RichardMartin Someone putting up the wiki article thought it was interesting enough to put down the $pi$ proof...
    – CopyPasteIt
    Nov 22 at 14:53






  • 2




    @RichardMartin More proofs = more fun. But seriously, new proofs to existing theorems are interesting because of any novel ideas they might contain, not because they achieve the same conclusion.
    – Klangen
    Nov 23 at 9:12














4












4








4







That the set of prime integers is infinite can be proved using the irrationality of $pi$; see this wikipedia link. It analyzes the representation



$tag 1 {displaystyle {frac {pi }{4}}={frac {3}{4}}times {frac {5}{4}}times {frac {7}{8}}times {frac {11}{12}}times {frac {13}{12}}times {frac {17}{16}}times {frac {19}{20}}times {frac {23}{24}}times {frac {29}{28}}times {frac {31}{32}}times cdots }$



It 'seems only fair' that the same thing can be done using $e$:




Question 1: Has a proof that there are an infinite number of primes been
constructed that uses the irrationality of $e$?




If the existence of such a proof is not available, then




Question 1-1: Is a proof available using any properties of $e$?




If again, no answers, then




Question 2: Can someone show that the set of prime integers is
infinite using properties of Euler's constant?




My work



I found this representation of $e$,



$tag 2 {displaystyle e=1+{cfrac {2}{1+{cfrac {1}{6+{cfrac {1}{10+{cfrac {1}{14+{cfrac {1}{18+{cfrac {1}{22+{cfrac {1}{26+ddots ,}}}}}}}}}}}}}}.}$



Note that with $text{(1)}$ there is a 'corresponding' sequence



$tag 3 4,8,12,16,dots$



and that with $text{(2)}$ we can see



$tag 4 6, 10,14,18,dots$



I just find this interesting; perhaps it supplies a 'connection'.



We know that eventually every prime number will divide a term in the $text{(4)}$ sequence.



If the only primes are contained in the finite set $mathcal P = {2,3,5, dots, p}$, then let $beta = 2 times 3 times 5 times dots times p$.



If we analyze $text{(2)}$ using base $beta$, the expansion of $e$ would eventually be repetitive or simply terminate.



(the statement in bold is an unproven bold statement)










share|cite|improve this question













That the set of prime integers is infinite can be proved using the irrationality of $pi$; see this wikipedia link. It analyzes the representation



$tag 1 {displaystyle {frac {pi }{4}}={frac {3}{4}}times {frac {5}{4}}times {frac {7}{8}}times {frac {11}{12}}times {frac {13}{12}}times {frac {17}{16}}times {frac {19}{20}}times {frac {23}{24}}times {frac {29}{28}}times {frac {31}{32}}times cdots }$



It 'seems only fair' that the same thing can be done using $e$:




Question 1: Has a proof that there are an infinite number of primes been
constructed that uses the irrationality of $e$?




If the existence of such a proof is not available, then




Question 1-1: Is a proof available using any properties of $e$?




If again, no answers, then




Question 2: Can someone show that the set of prime integers is
infinite using properties of Euler's constant?




My work



I found this representation of $e$,



$tag 2 {displaystyle e=1+{cfrac {2}{1+{cfrac {1}{6+{cfrac {1}{10+{cfrac {1}{14+{cfrac {1}{18+{cfrac {1}{22+{cfrac {1}{26+ddots ,}}}}}}}}}}}}}}.}$



Note that with $text{(1)}$ there is a 'corresponding' sequence



$tag 3 4,8,12,16,dots$



and that with $text{(2)}$ we can see



$tag 4 6, 10,14,18,dots$



I just find this interesting; perhaps it supplies a 'connection'.



We know that eventually every prime number will divide a term in the $text{(4)}$ sequence.



If the only primes are contained in the finite set $mathcal P = {2,3,5, dots, p}$, then let $beta = 2 times 3 times 5 times dots times p$.



If we analyze $text{(2)}$ using base $beta$, the expansion of $e$ would eventually be repetitive or simply terminate.



(the statement in bold is an unproven bold statement)







soft-question prime-numbers alternative-proof continued-fractions eulers-constant






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share|cite|improve this question











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asked Nov 22 at 14:40









CopyPasteIt

3,9891627




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  • It's hard to see why one would want to prove it that way, as the usual $1+prod_{i=1}^n p_i$ argument does it easily.
    – Richard Martin
    Nov 22 at 14:46












  • Or, better still, try and figure it out from what I have just said.
    – Richard Martin
    Nov 22 at 14:50










  • @RichardMartin Ok - Euclid's proof. Just interested in seeing a 'later stage' proof.
    – CopyPasteIt
    Nov 22 at 14:52










  • @RichardMartin Someone putting up the wiki article thought it was interesting enough to put down the $pi$ proof...
    – CopyPasteIt
    Nov 22 at 14:53






  • 2




    @RichardMartin More proofs = more fun. But seriously, new proofs to existing theorems are interesting because of any novel ideas they might contain, not because they achieve the same conclusion.
    – Klangen
    Nov 23 at 9:12


















  • It's hard to see why one would want to prove it that way, as the usual $1+prod_{i=1}^n p_i$ argument does it easily.
    – Richard Martin
    Nov 22 at 14:46












  • Or, better still, try and figure it out from what I have just said.
    – Richard Martin
    Nov 22 at 14:50










  • @RichardMartin Ok - Euclid's proof. Just interested in seeing a 'later stage' proof.
    – CopyPasteIt
    Nov 22 at 14:52










  • @RichardMartin Someone putting up the wiki article thought it was interesting enough to put down the $pi$ proof...
    – CopyPasteIt
    Nov 22 at 14:53






  • 2




    @RichardMartin More proofs = more fun. But seriously, new proofs to existing theorems are interesting because of any novel ideas they might contain, not because they achieve the same conclusion.
    – Klangen
    Nov 23 at 9:12
















It's hard to see why one would want to prove it that way, as the usual $1+prod_{i=1}^n p_i$ argument does it easily.
– Richard Martin
Nov 22 at 14:46






It's hard to see why one would want to prove it that way, as the usual $1+prod_{i=1}^n p_i$ argument does it easily.
– Richard Martin
Nov 22 at 14:46














Or, better still, try and figure it out from what I have just said.
– Richard Martin
Nov 22 at 14:50




Or, better still, try and figure it out from what I have just said.
– Richard Martin
Nov 22 at 14:50












@RichardMartin Ok - Euclid's proof. Just interested in seeing a 'later stage' proof.
– CopyPasteIt
Nov 22 at 14:52




@RichardMartin Ok - Euclid's proof. Just interested in seeing a 'later stage' proof.
– CopyPasteIt
Nov 22 at 14:52












@RichardMartin Someone putting up the wiki article thought it was interesting enough to put down the $pi$ proof...
– CopyPasteIt
Nov 22 at 14:53




@RichardMartin Someone putting up the wiki article thought it was interesting enough to put down the $pi$ proof...
– CopyPasteIt
Nov 22 at 14:53




2




2




@RichardMartin More proofs = more fun. But seriously, new proofs to existing theorems are interesting because of any novel ideas they might contain, not because they achieve the same conclusion.
– Klangen
Nov 23 at 9:12




@RichardMartin More proofs = more fun. But seriously, new proofs to existing theorems are interesting because of any novel ideas they might contain, not because they achieve the same conclusion.
– Klangen
Nov 23 at 9:12















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