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Can someone explain to me where this proof goes wrong? (Twin Prime Conjecture)

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Can someone explain to me where this proof goes wrong? (Twin Prime Conjecture)

Can the twin prime conjecture be solved in this way?What is wrong with this proposed proof of the twin prime conjecture?How to pigeonhole the primes between $p_n$ and $p_{n+1}^2$ for twin prime conjecture?Possible method to prove infinite twin prime conjectureTwin prime conjecture proof errorWhy can the sieve of eratosthenes not be used to confirm the twin primes conjecture?what's the wrong when we use Euclid logic to prove the twin prime conjecture?A twin prime theorem, and a reformulation of the twin prime conjectureTwin prime conjecture and gaps between primesIterated Twin Prime conjecture

1

1

$begingroup$

Euclid's theorem states:

Consider any finite list of prime numbers $p_1, p_2, ..., p_n$. It will be shown that at least one additional prime number not in this list exists. Let $P$ be the product of all the prime numbers in the list: $P = p_1p_2...p_n$. Let $q = P + 1$. Then $q$ is either prime or not.

If $q$ is prime, then there is at least one more prime that is not in the list. If $q$ is not prime, then some prime factor $p$ divides $q$. If this factor $p$ were in our list, then it would divide $P$ (since $P$ is the product of every number in the list); but $p$ divides $P + 1 = q$. If $p$ divides $P$ and $q$, then $p$ would have to divide the difference of the two numbers, which is $(P + 1) − P$ or just $1$. Since no prime number divides $1$, $p$ cannot be on the list. This means that at least one more prime number exists beyond those in the list. This proves that for every finite list of prime numbers there is a prime number not in the list, and therefore there must be infinitely many prime numbers.

---

My question:

Does this theorem also hold if you let $q = P - 1$?

Wouldn't $P-1$ also be necessarily a new prime number? And if so, it and $P+1$ would be a set of twin primes.

---

So the proof would be:

Assume there are a finite number of twin primes such that $p_{n+1} - p_n = 2$.

Then, from the final set of twin primes, choose the larger of these two primes $p_{n+1}$. Calculate $S=p_1p_2...p_{n+1}$. So you now have a product of all primes up to $p_{n+1}$. Call this $S$. $S + 1$ is a prime number and so is $S - 1$. This is a new set of twin primes not in our original list, thus there cannot be a finite list of twin primes.

Of course, if $S - 1$ is not prime, then this falls apart.

proof-verification prime-numbers prime-twins

share|cite|improve this question

edited 2 mins ago

YuiTo Cheng

2,0452637

asked 3 hours ago

Jeffrey ScottJeffrey Scott

61

New contributor

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

$endgroup$

• 
  
  
  

  
  6
  

  
  
  
  
  
  

  
  $begingroup$
  There’s absolutely no reason why S+1 or S-1 should be a prime number though, it merely has an unlisted prime factor.
  $endgroup$
  – Noe Blassel
  3 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  By the way, take a look at the edits. It's a courtesy to other contributors to use MathJax to format your posts. If you're not familiar with it, it's not hard to learn -- I've been on this site for less than two months and it has become second nature.
  $endgroup$
  – Robert Shore
  3 hours ago
  

  
  
  
  

add a comment | 

1

1

$begingroup$

Euclid's theorem states:

Consider any finite list of prime numbers $p_1, p_2, ..., p_n$. It will be shown that at least one additional prime number not in this list exists. Let $P$ be the product of all the prime numbers in the list: $P = p_1p_2...p_n$. Let $q = P + 1$. Then $q$ is either prime or not.

If $q$ is prime, then there is at least one more prime that is not in the list. If $q$ is not prime, then some prime factor $p$ divides $q$. If this factor $p$ were in our list, then it would divide $P$ (since $P$ is the product of every number in the list); but $p$ divides $P + 1 = q$. If $p$ divides $P$ and $q$, then $p$ would have to divide the difference of the two numbers, which is $(P + 1) − P$ or just $1$. Since no prime number divides $1$, $p$ cannot be on the list. This means that at least one more prime number exists beyond those in the list. This proves that for every finite list of prime numbers there is a prime number not in the list, and therefore there must be infinitely many prime numbers.

---

My question:

Does this theorem also hold if you let $q = P - 1$?

Wouldn't $P-1$ also be necessarily a new prime number? And if so, it and $P+1$ would be a set of twin primes.

---

So the proof would be:

Assume there are a finite number of twin primes such that $p_{n+1} - p_n = 2$.

Then, from the final set of twin primes, choose the larger of these two primes $p_{n+1}$. Calculate $S=p_1p_2...p_{n+1}$. So you now have a product of all primes up to $p_{n+1}$. Call this $S$. $S + 1$ is a prime number and so is $S - 1$. This is a new set of twin primes not in our original list, thus there cannot be a finite list of twin primes.

Of course, if $S - 1$ is not prime, then this falls apart.

proof-verification prime-numbers prime-twins

share|cite|improve this question

edited 2 mins ago

YuiTo Cheng

2,0452637

asked 3 hours ago

Jeffrey ScottJeffrey Scott

61

New contributor

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

$endgroup$

• 
  
  
  

  
  6
  

  
  
  
  
  
  

  
  $begingroup$
  There’s absolutely no reason why S+1 or S-1 should be a prime number though, it merely has an unlisted prime factor.
  $endgroup$
  – Noe Blassel
  3 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  By the way, take a look at the edits. It's a courtesy to other contributors to use MathJax to format your posts. If you're not familiar with it, it's not hard to learn -- I've been on this site for less than two months and it has become second nature.
  $endgroup$
  – Robert Shore
  3 hours ago
  

  
  
  
  

add a comment | 

$begingroup$

Euclid's theorem states:

Consider any finite list of prime numbers $p_1, p_2, ..., p_n$. It will be shown that at least one additional prime number not in this list exists. Let $P$ be the product of all the prime numbers in the list: $P = p_1p_2...p_n$. Let $q = P + 1$. Then $q$ is either prime or not.

If $q$ is prime, then there is at least one more prime that is not in the list. If $q$ is not prime, then some prime factor $p$ divides $q$. If this factor $p$ were in our list, then it would divide $P$ (since $P$ is the product of every number in the list); but $p$ divides $P + 1 = q$. If $p$ divides $P$ and $q$, then $p$ would have to divide the difference of the two numbers, which is $(P + 1) − P$ or just $1$. Since no prime number divides $1$, $p$ cannot be on the list. This means that at least one more prime number exists beyond those in the list. This proves that for every finite list of prime numbers there is a prime number not in the list, and therefore there must be infinitely many prime numbers.

---

My question:

Does this theorem also hold if you let $q = P - 1$?

Wouldn't $P-1$ also be necessarily a new prime number? And if so, it and $P+1$ would be a set of twin primes.

---

So the proof would be:

Assume there are a finite number of twin primes such that $p_{n+1} - p_n = 2$.

Then, from the final set of twin primes, choose the larger of these two primes $p_{n+1}$. Calculate $S=p_1p_2...p_{n+1}$. So you now have a product of all primes up to $p_{n+1}$. Call this $S$. $S + 1$ is a prime number and so is $S - 1$. This is a new set of twin primes not in our original list, thus there cannot be a finite list of twin primes.

Of course, if $S - 1$ is not prime, then this falls apart.

proof-verification prime-numbers prime-twins

share|cite|improve this question

edited 2 mins ago

YuiTo Cheng

2,0452637

asked 3 hours ago

Jeffrey ScottJeffrey Scott

61

New contributor

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

$endgroup$

share|cite|improve this question

edited 2 mins ago

YuiTo Cheng

2,0452637

asked 3 hours ago

Jeffrey ScottJeffrey Scott

61

New contributor

Jeffrey Scott 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

edited 2 mins ago

YuiTo Cheng

2,0452637

asked 3 hours ago

Jeffrey ScottJeffrey Scott

61

New contributor

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

edited 2 mins ago

YuiTo Cheng

2,0452637

edited 2 mins ago

YuiTo Cheng

2,0452637

asked 3 hours ago

Jeffrey ScottJeffrey Scott

61

New contributor

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

asked 3 hours ago

Jeffrey ScottJeffrey Scott

61

1 Answer
1

active

oldest

votes

5

$begingroup$

Remember, your original argument doesn't show that $P+1$ is itself prime. It shows that $P+1$ has a prime factor that you haven't already accounted for. So while you could make the same argument for $P-1$, you'd also reach the same conclusion, not that $P-1$ is itself necessarily prime, but only that it has some prime factor not in your original list. So that's of no help in proving the Twin Prime Conjecture.

Similarly, you don't know that $S+1$ or $S-1$ is prime. You just know that they have prime factors that aren't on your original list of twin primes, but that doesn't help you.

share|cite|improve this answer

answered 3 hours ago

Robert ShoreRobert Shore

2,960218

$endgroup$

• 
  
  
  

  
  2
  

  
  
  
  
  
  

  
  $begingroup$
  Ah you're right. 2 * 3 * 5 * 7 = 210. But 209 is not prime.
  $endgroup$
  – Jeffrey Scott
  3 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  Glad I could help. Acceptances of answers that you find useful are always welcome.
  $endgroup$
  – Robert Shore
  2 hours ago
  

  
  
  
  

add a comment | 

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5

$begingroup$

Remember, your original argument doesn't show that $P+1$ is itself prime. It shows that $P+1$ has a prime factor that you haven't already accounted for. So while you could make the same argument for $P-1$, you'd also reach the same conclusion, not that $P-1$ is itself necessarily prime, but only that it has some prime factor not in your original list. So that's of no help in proving the Twin Prime Conjecture.

Similarly, you don't know that $S+1$ or $S-1$ is prime. You just know that they have prime factors that aren't on your original list of twin primes, but that doesn't help you.

share|cite|improve this answer

answered 3 hours ago

Robert ShoreRobert Shore

2,960218

$endgroup$

• 
  
  
  

  
  2
  

  
  
  
  
  
  

  
  $begingroup$
  Ah you're right. 2 * 3 * 5 * 7 = 210. But 209 is not prime.
  $endgroup$
  – Jeffrey Scott
  3 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  Glad I could help. Acceptances of answers that you find useful are always welcome.
  $endgroup$
  – Robert Shore
  2 hours ago
  

  
  
  
  

add a comment | 

5

$begingroup$

Remember, your original argument doesn't show that $P+1$ is itself prime. It shows that $P+1$ has a prime factor that you haven't already accounted for. So while you could make the same argument for $P-1$, you'd also reach the same conclusion, not that $P-1$ is itself necessarily prime, but only that it has some prime factor not in your original list. So that's of no help in proving the Twin Prime Conjecture.

Similarly, you don't know that $S+1$ or $S-1$ is prime. You just know that they have prime factors that aren't on your original list of twin primes, but that doesn't help you.

share|cite|improve this answer

answered 3 hours ago

Robert ShoreRobert Shore

2,960218

$endgroup$

• 
  
  
  

  
  2
  

  
  
  
  
  
  

  
  $begingroup$
  Ah you're right. 2 * 3 * 5 * 7 = 210. But 209 is not prime.
  $endgroup$
  – Jeffrey Scott
  3 hours ago
  

  
  
  
  


• 
  
  
  

  
  

  
  
  
  
  
  

  
  $begingroup$
  Glad I could help. Acceptances of answers that you find useful are always welcome.
  $endgroup$
  – Robert Shore
  2 hours ago
  

  
  
  
  

add a comment | 

$begingroup$

Remember, your original argument doesn't show that $P+1$ is itself prime. It shows that $P+1$ has a prime factor that you haven't already accounted for. So while you could make the same argument for $P-1$, you'd also reach the same conclusion, not that $P-1$ is itself necessarily prime, but only that it has some prime factor not in your original list. So that's of no help in proving the Twin Prime Conjecture.

Similarly, you don't know that $S+1$ or $S-1$ is prime. You just know that they have prime factors that aren't on your original list of twin primes, but that doesn't help you.

share|cite|improve this answer

answered 3 hours ago

Robert ShoreRobert Shore

2,960218

$endgroup$

share|cite|improve this answer

answered 3 hours ago

Robert ShoreRobert Shore

2,960218

answered 3 hours ago

Robert ShoreRobert Shore

2,960218

answered 3 hours ago

Robert ShoreRobert Shore

2,960218