Wikipedia:Reference desk/Archives/Mathematics/2024 March 16

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March 16

Smallest triangular number with prime signature the same as A025487(n)

Smallest triangular number with prime signature the same as (sequence A025487 in the OEIS)(n), or 0 if no such number exists. (there is a similar sequence (sequence A081978 in the OEIS) in OEIS)

For n = 1 through n = 29, this sequence is: (I have not confirmed the n = 15 term is 0, but it seems that it is 0, i.e. it seems that there is no triangular number of the form p^3*q^2 with p, q both primes)

1, 3, 0, 6, 0, 28, 0, 136, 66, 0, 36, 496, 276, 0, 0, 118341, 120, 0, 1631432881, 300, 8128, 210, 0, 528, 0, 29403, 1176, 32896, 630

Is it possible to extend this sequence to n = 100? 1.165.194.85 (talk) 00:51, 16 March 2024 (UTC)

This paper by Cohn implies that there are no prime solutions ${\displaystyle (p,q)}$ to ${\displaystyle p^{3}+1=2q^{2}}$ and ${\displaystyle 2p^{2}+1=q^{3}}$. If anyone here can prove that the elliptic curves ${\displaystyle y^{2}=x^{3}\pm 4}$ have no nontrivial integral points (for ${\displaystyle -4}$ that would be ${\displaystyle (2,\pm 2)}$ and ${\displaystyle (5,\pm 11)}$, while for ${\displaystyle 4}$ that would be ${\displaystyle (0,\pm 2)}$), then that implies that there are no triangular numbers of the form ${\displaystyle p^{3}q^{2}}$ at all. GalacticShoe (talk) 06:22, 16 March 2024 (UTC)

I'm not sure what you mean by "at all". If you drop the requirement that q is prime then there are many solutions, for example 242⋅243/2 = 3³33², 12167⋅12168/2 = 23³78². --RDBury (talk) 08:42, 16 March 2024 (UTC)

Sorry, shoulda clarified; no triangular numbers of the form ${\displaystyle p^{3}q^{2}}$ at all where ${\displaystyle p,q}$ are prime. Naturally, the two cases mentioned earlier (the latter example of which I hastily posted before remembering that I completely forgot about the prime signature part) are either not covered by Cohn's paper, with the ${\displaystyle 242}$ case being invalid since we spread powers of ${\displaystyle 3}$ among the cube and the square, or they are one of Cohn's special case, as with ${\displaystyle 12167}$. GalacticShoe (talk) 09:51, 16 March 2024 (UTC)

Thanks for the clarification. I don't have access to the Cohn paper, but it seems to me that the p³+1=2q² is trivial to exclude, and similarly for p³-1=2q². That leaves 2p³±1=q². Using brute force I found 2⋅23³+2=156² but none, even when p is only required to be odd and q can be anything, where the difference is one. Note that this generates the 12167 example, but that's not the way I found it. I'm not sure how y²=x³±4 is related, but I'm no expert on elliptic curves so I may have to take your word on that. In any case, given that the p³q² is proving so difficult, it seems unlikely that getting to n=100 is feasible. Finding entries where there is a solution should only require a computer search, but if none are found then proving that there are none to be found can be difficult. It seems ironic that while there is apparently no p³q² solution, there is a p⁵q², though this seems less likely at first glance. RDBury (talk) 18:24, 16 March 2024 (UTC)

The ${\displaystyle y^{2}=x^{3}\pm 4}$ condition arises because, if we write ${\displaystyle x=2p}$ and ${\displaystyle y=2q}$, then an integer solution to ${\displaystyle y^{2}=x^{3}\pm 4}$ implies ${\displaystyle (2q)^{2}=(2p)^{3}\pm 4\Rightarrow 4q^{2}=8p^{3}\pm 4\Rightarrow q^{2}=2p^{3}\pm 1}$ is a rational, possibly integer solution to the equalities we are looking at. All integer solutions to ${\displaystyle q^{2}=2p^{3}\pm 1}$ can be generated this way, so the lack of a nontrivial integer solution to ${\displaystyle y^{2}=x^{3}\pm 4}$ (or the existence only of solutions where ${\displaystyle x,y}$ are odd) would rule out any further triangular numbers of the form ${\displaystyle p^{2}q^{3}}$ with ${\displaystyle p,q}$ prime. GalacticShoe (talk) 21:33, 16 March 2024 (UTC)

Right, I should have seen that. The 2p³+1=q² case may be easier than I thought; it reduces to 2p³=(q+1)(q-1). You can rule out p=2, q=2, giving q odd, but then by unique factorization q±1 divides p, which is impossible. I thought of applying a similar trick to 2p³-1=q², or 2p³=(q+i)(q-i), and using unique factorization over Gaussian integers. But I quickly got bogged down with this. --RDBury (talk) 02:10, 17 March 2024 (UTC)

A similar disproof is that after proving ${\displaystyle p=2}$ and ${\displaystyle q=2}$ impossible by simple casework, ${\displaystyle q}$ odd implies that ${\displaystyle (q+1)(q-1)}$ is a multiple of ${\displaystyle 4}$, which ${\displaystyle 2p^{3}}$ cannot be. I imagine that ${\displaystyle 2p^{3}-1=q^{2}}$ is indeed not as simple to pin down. GalacticShoe (talk) 02:45, 17 March 2024 (UTC)

So if ${\displaystyle y^{2}=x^{3}\pm 4}$ has no integer solution other than ${\displaystyle (0,\pm 2)}$, ${\displaystyle (2,\pm 2)}$, ${\displaystyle (5,\pm 11)}$, than a(15) in the above sequence is 0? How about a(30), a(31), a(32), …? Do you have the status for a(n) for all ${\displaystyle n\leq 100}$? (sequence A081978 in the OEIS) has the proof for which some prime signatures do not exists for triangular numbers such as ${\displaystyle p^{6}q^{2}}$ (i.e. a(33) = 0), see the comment of Jinyuan Wang in Aug 22 2020. (You can also check whether a(1) ~ a(29) which I have listed above are correct) (a(n) is the smallest triangular number with prime signature the same as (sequence A025487 in the OEIS)(n), or a(n) is 0 if no such number exists) 61.224.130.152 (talk) 03:21, 18 March 2024 (UTC)

I mentioned this a few paragraphs back. Given that finding the value of a single entry is turning out to be a project in itself, and that it seems unlikely that computations will get any easier going on, I don't see getting to 100 as feasible. A081978 is asking for less information, and even so it took some high powered number theory to get it's values. --RDBury (talk) 15:36, 18 March 2024 (UTC)

So which a(n) for ${\displaystyle n\leq 100}$ are known to be 0? And which a(n) for ${\displaystyle n\leq 100}$ have known nonzero values? I want the status for ${\displaystyle n\leq 100}$. 203.73.106.200 (talk) 08:37, 25 March 2024 (UTC)

Now I use a PARI/GP program to compute, after the PARI/GP programs in (sequence A046523 in the OEIS) and (sequence A025487 in the OEIS):

a(n)=my(f=vecsort(factor(n)[, 2], , 4), p); prod(i=1, #f, (p=nextprime(p+1))^f[i])

isA025487(n)=my(k=valuation(n, 2), t); n>>=k; forprime(p=3, default(primelimit), t=valuation(n, p); if(t>k, return(0), k=t); if(k, n/=p^k, return(n==1)))

b(n)=for(k=1,2^24,if(a(k*(k+1)/2)==n,return(k*(k+1)/2)))

for(k=1,2^12,if(isA025487(k),print(k, ",",b(k))))

The result is (∞ loop for a(n)=0, but some zeros a(n) are not confirmed, and instead only conjectured):

1,1

2,3

4,0 (there is no triangular number which is a square of a prime)

6,6

8,0 (triangular number cannot be nth power if n>2)

12,28

16,0 (triangular number cannot be nth power if n>2)

24,136

30,66

32,0 (triangular number cannot be nth power if n>2)

36,36

48,496

60,276

64,0 (triangular number cannot be nth power if n>2)

72,0 (not confirmed, but must be > 10^15 if nonzero, see https://www.numbersaplenty.com/both_Achilles_and_triangular.html)

96,118341

120,120

128,0 (triangular number cannot be nth power if n>2)

144,1631432881

180,300

192,8128

210,210

216,0 (triangular number cannot be nth power if n>2)

240,528

256,0 (triangular number cannot be nth power if n>2)

288,29403

360,1176

384,32896

420,630

432,0 (not confirmed, but must be > 10^15 if nonzero, see https://www.numbersaplenty.com/both_Achilles_and_triangular.html)

480,2080

512,0 (triangular number cannot be nth power if n>2)

576,0 (see Jinyuan Wang proof on Aug 22 2020 in (sequence A081978 in the OEIS))

720,209628

768,86086881

840,6216

864,0 (not confirmed, but must be > 10^15 if nonzero, see https://www.numbersaplenty.com/both_Achilles_and_triangular.html)

900,2172602007770041 (after (sequence A081978 in the OEIS))

960,8256

1024,0 (triangular number cannot be nth power if n>2)

1080,93096

1152,0 (not confirmed, but must be > 10^15 if nonzero, see https://www.numbersaplenty.com/both_Achilles_and_triangular.html)

1260,4950

1296,0 (triangular number cannot be nth power if n>2)

1440,2016

1536,774860661

1680,4560

1728,0 (triangular number cannot be nth power if n>2)

1800,0 (not confirmed, but must be > 10^15 if nonzero, see https://www.numbersaplenty.com/both_Achilles_and_triangular.html)

1920,295296

2048,0 (triangular number cannot be nth power if n>2)

2160,3240

2304,0 (it seems that we can use the Jinyuan Wang proof on Aug 22 2020 for 576 in (sequence A081978 in the OEIS) to prove that it is 0)

2310,3570

2520,9180

2592,0 (not confirmed, but must be > 10^15 if nonzero, see https://www.numbersaplenty.com/both_Achilles_and_triangular.html)

2880,662976

3072,38009927549623740385753 (after (sequence A081978 in the OEIS))

3360,51040

3456,0 (not confirmed, but must be > 10^15 if nonzero, see https://www.numbersaplenty.com/both_Achilles_and_triangular.html)

3600,41616

3840,130816

4096,0 (triangular number cannot be nth power if n>2)

220.132.230.56 (talk) 14:12, 26 March 2024 (UTC)