Hessenberg theorem (set theory)

The von Hessenberg theorem , named after the German mathematician Gerhard Hessenberg , is a mathematical theorem from the field of set theory , more precisely the theory of cardinal numbers . It essentially states that an infinite cardinal number is equal to its square in so-called cardinal number arithmetic .

• For every ordinal number is equal to the Cartesian product .${\ displaystyle \ alpha}$${\ displaystyle \ aleph _ {\ alpha}}$ ${\ displaystyle \ aleph _ {\ alpha} \ times \ aleph _ {\ alpha}}$

The -th stands for an infinite cardinal number, see Aleph function . This theorem applies in ZF, i.e. in Zermelo-Fraenkel set theory without the axiom of choice . ${\ displaystyle \ aleph _ {\ alpha}}$${\ displaystyle \ alpha}$

• Every infinite quantity is equal to the Cartesian product , because with the axiom of choice every quantity is equal to one . For finite sets this theorem is known to be wrong.${\ displaystyle X}$${\ displaystyle X \ times X}$${\ displaystyle \ aleph _ {\ alpha}}$
• If an infinite cardinal number and a natural number, then is . According to the axiom of choice, every infinite cardinal number is a and according to Hessenberg's theorem it follows , the rest then follows by induction .${\ displaystyle \ kappa}$${\ displaystyle n \ in \ mathbb {N} \ setminus \ {0 \}}$${\ displaystyle \ kappa ^ {n} = \ kappa}$${\ displaystyle \ aleph _ {\ alpha}}$${\ displaystyle \ kappa ^ {2} = \ kappa}$
• If and are infinite cardinal numbers, then we have . This follows immediately from the obvious inequalities${\ displaystyle \ kappa}$${\ displaystyle \ lambda}$${\ displaystyle \ kappa + \ lambda = \ kappa \ cdot \ lambda = \ max \ {\ kappa, \ lambda \}}$