Thank you for your interest in my views on the set-theoretic multiverse. Yes, indeed, the well-foundedness mirage axiom you mention is probably the most controversial of my multiverse axioms, and so allow me to explain a little about it. The axiom expresses in a strong way the idea that we don't actually have a foundationally robust absolute concept of the finite in mathematics. Specifically, the axiom asserts that every universe of set theory is ill-founded even in its natural numbers from the perspective of another, better universe. Thus, every set-theoretic background in which we might seek to undertake our mathematical activity is nonstandard with respect to another universe. My intention in posing the axiom so provocatively was to point out what I believe is the unsatisfactory nature of our philosophical account of the finite. In preliminary defense of the axiom, let me point out that whatever attitude toward one might harbor, nevertheless the axiom cannot be seen as incoherent or inconsistent, because Victoria Gitman and I have proved that all of my multiverse axioms are true in the multiverse consisting of the countable computably saturated models of ZFC. So the axiom is neither contradictory nor incoherent. See [A natural model of the multiverse axioms](http://jdh.hamkins.org/naturalmodelofmultiverseaxioms/). You might be interested in the brief essay I wrote on the topic, [A question for the mathematics oracle](http://jdh.hamkins.org/question-for-the-math-oracle/), published in the proceedings of the Singapore workshop on Infinity and Truth. For an interesting and entertaining interlude, the workshop organizers had requested that everyone at the workshop pose a specific question that might be asked of an all-knowing mathematical oracle, who would truthfully answer. My question was whether in mathematics we really do have a absolute concept of the finite. To explain a bit more, the naive view of the natural numbers in mathematics is that they are the numbers, $0$, $1$, $2$, **and so on.** The natural numbers, with all the usual arithmetic structure, are taken by many to have a definite absolute nature; arithmetic truth assertions are taken to have a definite absolute nature, in comparison for example with the comparatively less sure footing of set-theoretic truth assertions. To be sure, many mathematicians and philosophers have proposed a demarcation between arithmetic and analysis, where the claims of number theory and arithmetic are said to have a definite absolute nature, while the assertions of higher levels of set theory, beginning with claims about the set of sets of natural numbers, are less definite. Nik Weaver, for example, has suggested that classical logic is appropriate for the arithmetic realm and intuitionistic logic for the latter realm, and a similar position is advocated by Solomon Feferman and others. But what exactly does this phrase, "and so on" really mean in the naive account of the finite? It seems truly to be doing all the work, and I find it basically inadequate to the task. The situation is more subtle and problematic than seems to me to be typically acknowledged. Why do people find their conception of the finite to be so clear and absolute? It seems hopelessly vague to me. Of course, within the axiomatic system of ZFC or other systems, we have a clear definition of what it means to be finite. The issue is not that, but rather the extent to which these internal accounts of finiteness agree with the naive pre-reflective accounts of the finite as used in the meta-theory. Some mathematicians point to the various categoricity arguments as an explanation of why it is meaningful to speak of the natural numbers as a definite mathematical structure. Dedekind proved, after all, that there is up to isomorphism only one model $\langle\mathbb{N},S,0\rangle$ of the second-order Peano axioms, where $0$ is not a successor, the successor function $S$ is one-to-one, and $\mathbb{N}$ is the unique subset of $\mathbb{N}$ containing $0$ and closed under successor. But to my way of thinking, this categoricity argument merely pushes off the problem from arithmetic to set theory, basing the absoluteness of arithmetic on the absoluteness of the concept of an arbitrary set of natural numbers. But how does that give one any confidence? We already know very well, after all, about failures of absoluteness in set theory. Different models of set theory can disagree about whether the continuum hypothesis holds, whether the axiom of choice holds, and so with innumerable examples of non-absoluteness. Different models of set theory can disagree on their natural number structures, and even when they agree on their natural numbers, they can still disagree on their theories of arithmetic truth (see [Satisfaction is not absolute](http://jdh.hamkins.org/satisfaction-is-not-absolute/)). So we know all about how mathematical truth assertions can seem to be non-absolute in set theory. Skolem pointed out that there are models of set theory $M_1$, $M_2$ and $M_3$ with a set $A$ in common, such that $M_1$ thinks $A$ is finite; $M_2$ thinks $A$ is countably infinite and $M_3$ thinks $A$ is uncountable. For example, let $M_3$ be any countable model of set theory, and let $M_1$ be an ultrapower by a ultrafilter on $\mathbb{N}$ in $M_3$, and let $A$ be a nonstandard natural number of $M_1$. So $M_1$ thinks $A$ is finite, but $M_3$ thinks $A$ has size continuum. If $M_2$ is a forcing extension of $M_3$, we can arrange that $A$ is countably infinite in $M_2$. No amount of set-theoretic information in our set-theoretic background could ever establish that our current conception of the natural numbers, whatever it is, is the truly standard one, since whatever we assert to be true is also true in some nonstandard models, whose natural numbers are not standard. The well-foundedness mirage axiom asserts that this phenomenon is universal: all universes are wrong about well-foundedness. I have discussed my multiverse views in several papers. >> <cite authors="Hamkins, Joel David">_Hamkins, Joel David_, [**The set-theoretic multiverse**](http://jdh.hamkins.org/themultiverse/), Rev. Symb. Log. 5, No. 3, 416-449 (2012). [Doi:10.1017/S1755020311000359](http://dx.doi.org/10.1017/S1755020311000359), [ZBL1260.03103](https://zbmath.org/?q=an:1260.03103).</cite> >> <cite authors="Hamkins, Joel David">_Hamkins, Joel David_, [**A multiverse perspective on the axiom of constructibility**](http://jdh.hamkins.org/multiverse-perspective-on-constructibility/), Chong, Chitat (ed.) et al., Infinity and truth. Based on talks given at the workshop, Singapore, July 25--29, 2011. Hackensack, NJ: World Scientific (ISBN 978-981-4571-03-6/hbk; 978-981-4571-05-0/ebook). Lecture Notes Series. Institute for Mathematical Sciences. National University of Singapore 25, 25-45 (2014). [DOI:10.1142/9789814571043_0002](http://dx.doi.org/10.1142/9789814571043_0002), [ZBL1321.03061](https://zbmath.org/?q=an:1321.03061).</cite> >> <cite authors="Gitman, Victoria; Hamkins, Joel David">_Gitman, Victoria; Hamkins, Joel David_, [**A natural model of the multiverse axioms**](http://jdh.hamkins.org/naturalmodelofmultiverseaxioms/), Notre Dame J. Formal Logic 51, No. 4, 475-484 (2010). [DOI:10.1215/00294527-2010-030](http://dx.doi.org/10.1215/00294527-2010-030), [ZBL1214.03035](https://zbmath.org/?q=an:1214.03035).</cite> >> <cite authors="Hamkins, Joel David; Ruizhi Yang">_Hamkins, Joel David; Yang, Ruizhi_, [**Satisfaction is not absolute**](http://jdh.hamkins.org/satisfaction-is-not-absolute/), to appear in the Review of Symbolic Logic.</cite> But finally, to address your specific question. Of course, there are specific finite numbers that will be finite with respect to any alternative set-theoretic background. As Michael Greinecker points out in the comments, the number 35253586543 has that value regardless of your meta-mathematical position. So of course, there are many proofs that are standard finite with respect to any of the alternative foundations. Meanwhile, I find it very interesting to consider the situation where different foundational systems disagree on what is provable. In very recent work of mine, for example, we are looking at the theory of set-theoretic and arithmetic potentialism, where different foundational systems disagree on what is true or provable. For example, recently with Hugh Woodin, I have proved that there is a universal finite set $\{x\mid\varphi(x)\}$, a set that ZFC proves is finite, and which is empty in any transitive model of set theory, but if the set is $y$ in some countable model of set theory $M$ and $z$ is any finite set in $M$ with $y\subset z$, then there is a top-extension of $M$ to a model $N$ inside of which the set is exactly $z$. The key to the proof is playing with the non-absolute nature of truth between $M$ and its various top-extensions. [![enter image description here][1]][1] [1]: https://i.sstatic.net/0Hfom.jpg