Which pairs of mutually contradicting conjectures are there?

The Eilenberg-Ganea Conjecture and the Whitehead Conjecture can’t both be true. This was shown by Bestvina and Brady in their 1997 paper. As far as I am aware, both conjectures are still open.

The first Hardy-Littlewood conjecture and the second Hardy-Littlewood conjecture were found to be incompatible in joint work by Douglas Hensley and Ian Richards as recounted by Richards in this paper. The official publication of the Hensley–Richards result seems to be D. Hensley and I Richards, Primes in Intervals, Acta Arithmetics 25 (1974), 375-391.

There are at least two (to my knowledge) conjectured values of $\limsup \frac{p_{n+1}-p_n}{\log^2 p_n}$, depending on which random model of the prime numbers you choose for your heuristic; see e.g. Cramér's conjecture and Terence Tao's blogpost

The following came to mind:

• Alon, N.; Shpilka, A.; Umans, C. (April 2011). "On Sunflowers and Matrix Multiplication"

It is shown that some plausible conjectures are incompatible:

• a strengthening of the conjecture that matrix multiplication is possible in $n^{2+o(1)}$ time,
• the sunflower conjecture from extremal combinatorics.

This is perhaps not quite what the question is asking for, but it was mentioned in a comment and seems at least tangentially relevant. There are examples of axioms going beyond ZF that contradict each other and yet are both "taken seriously." These axioms are not exactly conjectures in the usual sense of the word, but sometimes people will advocate for them as "basic axioms" to be adjoined to ZF.

1. The (full) axiom of choice contradicts various other axioms such as the axiom of determinacy and the axiom that "all sets of reals are Lebesgue measurable." Although it is standard mathematical practice to accept the axiom of choice as a basic axiom of mathematics, these other axioms are not necessarily treated as being straightforwardly false, in part because they can be compatible with a weak version of choice.
2. The existence of measurable cardinals (or even of sharps) is incompatible with $V = L$, the axiom of constructibility. Large cardinal axioms are widely "accepted" by set theorists, but $V=L$ has a few advocates.
3. Forcing axioms are incompatible with V = Ultimate L (the former imply $2^{\aleph_0} = \aleph_2$ and the latter implies $2^{\aleph_0} = \aleph_1$). There is a nice Quanta Magazine article that gives a nontechnical overview.

It is an open question whether or not there can be elliptic curves over $\mathbb{Q}$ of arbitrarily large Mordell-Weil rank. This article, which suggests that the ranks should be uniformly bounded, discusses some of the history and how public opinion seems to have shifted between boundedness and unboundedness.

There are two competing and contradicting conjectures aiming at geometrically characterizing varieties defined over a number a field that admit a potentially dense set of rational points.

A projective variety $X$ defined over a number field $K$ has a potentially dense set of rational points (PD for short) if there exists a finite extension $L \supset K$ such that $X(L)$ is Zariski dense.

In a paper of Harris and Tschinkel the following conjecture was reported (stemming from questions and observations made by Colliot Thélène and Abramovich): a projective variety $X$ has PD if and only if $X$ is weakly special, namely no birational model of an étale cover of $X$ dominates a positive dimensional variety of general type.

Campana proposed a different characterization using his theory of special variety, conjecturing that $X$ has PD if and only if $X$ is special. Here $X$ is special if for every rank 1 saturated coherent sheaf $\mathcal{F} \subset \Omega_X^p$ one has that the Itaka dimension $\kappa(X,\mathcal{F}) < p$. Or, in other words, $X$ does not dominate any Campana orbifold of general type.

Bogomolov and Tschinkel were among the first to construct examples of weakly special varieties that are not special. Hence the two conjectures cannot hold at the same time.

Campana and Păun proved soon after that the complex analytic analogue of the Weakly-Special conjecture does not hold. Similar results were obtained for the function field version. Campana showed that Lang-Vojta conjecture (varieties of (log) general type do not have PD) contradicts the weakly special conjecture. But, at the present, we don't have a non conditional disproof of the Weakly special conjecture, even though it is believed not to be the correct characterization.

More recently a preprint of Bartsch, Campana, Javanpeykar and Wittenberg showed that the Weakly special Conjecture contradicts the abc conjecture (via the orbifold version of the Mordell Conjecture).

References:

• Finn Bartsch, Frédéric Campana, Ariyan Javanpeykar, and Olivier Wittenberg. The weakly special conjecture contradicts orbifold mordell, and thus abc. ArXiv preprint:2410.06643, 2024.
• Fedor Bogomolov and Yuri Tschinkel. Special elliptic fibrations. In The Fano Conference, pages 223–234. Univ. Torino, Turin, 2004.
• Frédéric Campana. Orbifolds, special varieties and classification theory. Ann. Inst. Fourier (Grenoble),54(3):499–630, 2004.
• Joe Harris and Yuri Tschinkel. Rational points on quartics. Duke Math. J., 104(3):477–500, 2000.
• Erwan Rousseau, Amos Turchet, and Julie Tzu-Yueh Wang. Nonspecial varieties and generalised Lang–Vojta conjectures. Forum of Mathematics, Sigma, 9:1–29, 2021.

I don't know if things have moved on since it was active but this question: Is Thompson's Group F amenable? discusses the amenability of Thompson's Group F. There have been claimed proofs both that it is amenable and that it is not so I suppose both statements have been conjectures for some meaning of the term.

The function $s(n)$ is defined, for integers $n\ge2$, to be the sum of all the proper divisors of $n$, that is, all the divisors other than $n$ itself. E.g., $s(6)=1+2+3=6$.

The aliquot sequence of $n$ is the sequence $n,s(n),s(s(n)),s(s(s(n))),\dotsc$.

The Catalan-Dickson Conjecture holds that all aliquot sequences are bounded.

The Guy-Selfridge Conjecture holds that most sequences for even $n$ are unbounded.

Catalan's statement, dated 18 April 1888, can be found at https://www.aliquot.de/literatur/catalan.pdf It can also be found in Catalan's Mélanges Mathématiques, https://archive.org/details/mlangesmathm00catauoft/page/n7/mode/2up?view=theater page 240. A citation for Dickson is Theorems and tables on the sums of divisors of a number, Quart. J. Math., v. 44, 1913, pp. 264-296.

Guy and Selfridge have several papers on aliquot sequences. I'm not sure where their conjecture appears.

I thank Lola Thompson for reminding me of this pair of contradicting conjectrures, in a talk she gave at a recent conference.

Lovász conjecture – Every finite connected vertex-transitive graph contains a Hamiltonian path. While László Babai expressed opposite conjecture. (Quote from Pak, Igor; Radoičić, Radoš (2009), "Hamiltonian paths in Cayley graphs")

In a survey article [B, §3.3], Babai is sharply critical of the Lovász conjecture: “In my view these beliefs only reflect that Hamiltonicity obstacles are not well understood; and indeed, vertex-transitive graphs may provide a testing ground for the power of such obstacles.” Babai conjectured that for some $c > 0$, there exist infinitely many Cayley graphs without cycles of length $\geq (1-c)n$. Clearly, Babai’s conjecture contradicts the Lovász conjecture. In a different direction, it it [sic] worth noting Thomassen’s work [Th] suggesting that there might be only finitely many counterexamples.