Sniffnoy may have more examples, but here are some that I know:
Every subset of the real line is Lebesgue-measurable.
Every subset of the real line has the Baire property (in much the same vein as the preceding one).
The axiom of determinacy (a statement in infinitary game theory).
Adding the first two to ZF + DC (dependent choice) is consistent (assuming that ZFC + Con(ZFC) is consistent, as just about everybody believes), and this gives a “dream universe” for analysis in which, for example, any everywhere-defined linear operator between Hilbert spaces is bounded.
Adding the first two to ZF + DC (dependent choice) is consistent (assuming that ZFC + Con(ZFC) is consistent, as just about everybody believes)
This isn’t quite right. The consistency of ZF + DC + “every subset of R is Lebesgue measurable” is equivalent to the consistency of an inaccessible cardinal, which is a much stronger assumption then the consistency of ZFC + Con(ZFC).
Sniffnoy may have more examples, but here are some that I know:
Every subset of the real line is Lebesgue-measurable.
Every subset of the real line has the Baire property (in much the same vein as the preceding one).
The axiom of determinacy (a statement in infinitary game theory).
Adding the first two to ZF + DC (dependent choice) is consistent (assuming that ZFC + Con(ZFC) is consistent, as just about everybody believes), and this gives a “dream universe” for analysis in which, for example, any everywhere-defined linear operator between Hilbert spaces is bounded.
This isn’t quite right. The consistency of ZF + DC + “every subset of R is Lebesgue measurable” is equivalent to the consistency of an inaccessible cardinal, which is a much stronger assumption then the consistency of ZFC + Con(ZFC).
Sorry, my mistake. Still, set theorists usually believe this.