Thank you for this link. A few months ago I stumbled across your paper, Common sense for concurrency and strong paraconsistency using unstratified inference and reflection and found it entirely remarkable. I look forward to reading the new paper you linked.
> There are true statements that are unprovable within the system.
I really don't like this, and it verges on being flat-out incorrect: the first incompleteness theorem does not say this at all. It says that there are sentences (and indeed it constructs one, the so-called Gödel Sentence) that cannot be proven or refuted within the system.
For first-order theories it follows from the contraposition of Gödel's completeness theorem that there exist (classical) models of the theory where this sentence holds and models where it doesn't: the existence of models where the sentence does not hold means that this must be a very different meaning of "true" to the one used in common parlance.
In higher-order logics, which do not have a completeness theorem, it makes sense to talk about true statements which are unprovable: there can exist tautologies, sentences which hold in all models of a theory, which cannot be proven from the axioms of a higher-order theory (and you don't need the incompleteness theorem for this); on the other hand, in a first-order theory all tautologies are provable.
Sentences which cannot be proven or refuted within a theory are said to be logically independent of the theory. Famously, the Axiom of Choice is independent of the axioms of Zermelo–Fraenkel set theory: it's up to mathematicians to decide whether they accept the Axiom of Choice. If they do, they can work in ZF+C; if not, they can work in ZF. Neither system is "more true" from a purely logical perspective, so I really don't like describing logically independent sentences as "true but unprovable": it almost certainly doesn't mean what people think it means.
The first incompleteness theorem could perhaps be stated better for a lay audience as:
No recursive set of axioms can capture our notion of arithmetic it its entirety.
This is a limitation on how we can use axiom systems to represent mathematical objects: even more informally, we might say:
Truth is subjective in sufficiently complex systems.
> so I really don't like describing logically independent sentences as "true but unprovable":
I don't see a particular problem with it. It can be "true but unprovable" within a given system. I feel like you may be arguing semantics, but the sentence is still clear and accurate to me, while your lay audience definition is less clear and steps further away from the theorems than necessary
Yeah, I am; it really depends on how you define "true". I prefer this to be interpreted as "true in all models" so sentences are "true" when they are tautological consequences of a theory.
Using this definition, all "true" sentences are provable in first-order logic.
The (usual) Gödel sentence is true in the intended model of arithmetic, but I don't really like this property being referred to as "truth" without qualification.
> "true but unprovable" within a given system
Not sure about this: I don't think you can really say something is "true in a system" if it isn't provable. You can only assert its truth by saying it's "true in the intended model" without qualification, or by doing some meta-reasoning in a more powerful system outside the original one.
> Question: Can a sentence be provably true in one arithmetic system but not another?
The answer is yes!
ZFC |- AC
but
ZF |/- AC
and both ZFC and ZF can encode arithmetic.
But there's an issue here: no-one really talks about the "truth" of the Axiom of Choice as though it's a concrete thing: it's a very controversial axiom, and although most mathematicians accept it, quite a few don't. Constructivist mathematicians don't accept it, and it's provably equivalent to the law of the excluded middle, so it can't be used in intuitionistic logics.
Now you might counter and say that AC isn't the Gödel sentence for ZFC, and the Gödel sentence for PA is true in the intended model. But that's a different matter from whether it's provable from an axiomatic foundation. The reason I think this matters is because mathematicians work with proofs! Most mathematicians aren't working in foundations, and rely on proofs to the extent that they don't even consider the truth of statements which cannot be proven.
> If so that means there are provably true sentences which exist, but not provably true with the axioms that I have at my disposal right now?
The issue is that provability is completely contingent on the set of axioms you use: provability isn't a universal notion. Of course if you add something which is unprovable (such as the Gödel sentence) to PA, you get a new system which can prove more things: but this system has its own unprovable Gödel sentence.
I'd also question what you mean by "provably true": a sentence is provable from a theory when there exists a derivation in some proof calculus of the sentence starting from the axioms of the theory. "True" is much harder to pin down, and we wouldn't usually say "provably true". "True" can mean "true in the intended model", "true in all models", or even just "provable from a set of axioms".
The Gödel sentence is "true but unprovable" only in the sense that it is true in the intended model: it is not a tautology.
I think most people who have had a brief exposure to mathematics would consider "true in all models" (i.e. tautological truth) to be what is meant by "true", so I don't like it being used to mean "true in the intended model" without qualification.
The Axiom of Choice is not an example of Gödel's true-but-unprovable statements, because Gödel's statements are true in all models (as you said) but AoC is NOT true in all models. The Continuum Hypothesis isn't an example either for the same reason.
This is wrong, and I said the exact opposite of this: there are non-standard models of PA in which G_F is false.
There is a fundamental difference between Gödel sentences and AoC, which is that the Gödel sentence is Pi_1, which means its independence implies its truth in the standard model.
I'm just not really a fan of unqualified "true" meaning "true in the standard model"; I think if you're doing a course purely on the incompleteness theorems for an audience without much exposure to mathematical logic, using "true to refer to "truth in the standard model" is not a good idea and is likely to lead to misconceptions.
Perhaps the fact that you think G_F is true in all models is evidence in favour of my claim?
https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3603021