We got strong numerical evidence for the root numbers and analytic ranks of quadruples of elliptic curves over the rationals.
Related to this question.
Let $k,k_1,k_2$ be squarefree pairwise coprime integers.
Assume $|k|>1$ and $|k_1|>1$ and $|k_2|>1$.
Define the elliptic curves over the rationals:
$$E_0:x^3+k x=y^2, E_1: x^3+k k_1^2 x,E_2: x^3+k k_2^2 x =y^2, E_3: x^3+k k_1^2 k_2^2 x=y^2$$
If necessary, assume widely believed conjectures like BSD, Parity, GRH.
Which of the following conjectures are true:
(1) The root number of at least one of the $E_i$ is $-1$.
(2) The analytic rank of at least one of the $E_i$ is odd.
(3) The analytic rank of at least one of the $E_i$ is positive.
For $k_1=2,k_2=3$, all of the above hold up to $k=2000$ and reportedly Elkies verified stronger claim to $10^4$.
Here is sage code in case someone want to verify
#Author Georgi Guninski, Tue Aug 13 02:08:24 PM UTC 2024
lim=100 #upper bound for k
def BSD_r00t(lim,k_1,k_2):
#returns True if all conjectures pass, else (False,"reason")
assert abs(k_1)>1 and abs(k_2)>1,"luser error |k_i|=1"
assert gcd(k_1,k_2)==1,"luser error coprime k_1,k_2"
assert ZZ(k_1).is_squarefree(),"luser error k_1 squarefree"
assert ZZ(k_2).is_squarefree(),"luser error k_2 squarefree"
for k in range(2,lim):
if gcd(k,k_1*k_2) != 1: continue
Ei=[EllipticCurve([k*m^2,0]) for m in [1,k_1,k_2,k_1*k_2]]
r00t=[E.root_number() for E in Ei]
ran=[E.analytic_rank() for E in Ei]
ranmod2=[i%2 for i in ran]
print(k,ran,ranmod2,r00t)
if not -1 in r00t: return (False,"r00t")
if max(ran)==0: return (False,"analytic rank")
if max(ranmod2)==0: return (False,"parity")
return True,[]
res=BSD_r00t(lim,2,3)
print("result=",res)
