set theory Set theory is the branch of mathematical logic that studies sets, which can be informally described as collections of objects. Although objects of any kind can be collected into a set, set theory, as a branch of mathematics, is mostly conce ...

, an amorphous set is an

infinite Infinite may refer to: Mathematics * Infinite set, a set that is not a finite set *Infinity, an abstract concept describing something without any limit Music *Infinite (group), a South Korean boy band *''Infinite'' (EP), debut EP of American m ...

set Set, The Set, SET or SETS may refer to: Science, technology, and mathematics Mathematics *Set (mathematics), a collection of elements *Category of sets, the category whose objects and morphisms are sets and total functions, respectively Electro ...

which is not the

disjoint union In mathematics, a disjoint union (or discriminated union) of a family of sets (A_i : i\in I) is a set A, often denoted by \bigsqcup_ A_i, with an injection of each A_i into A, such that the images of these injections form a partition of A ( ...

of two infinite subsets..

Existence

Amorphous sets cannot exist if the

axiom of choice In mathematics, the axiom of choice, or AC, is an axiom of set theory equivalent to the statement that ''a Cartesian product of a collection of non-empty sets is non-empty''. Informally put, the axiom of choice says that given any collection ...

is assumed. Fraenkel constructed a permutation model of Zermelo–Fraenkel with Atoms in which the set of atoms is an amorphous set. After Cohen's initial work on forcing in 1963, proofs of the consistency of amorphous sets with Zermelo–Fraenkel were obtained.

Additional properties

Every amorphous set is

Dedekind-finite In mathematics, a set ''A'' is Dedekind-infinite (named after the German mathematician Richard Dedekind) if some proper subset ''B'' of ''A'' is equinumerous to ''A''. Explicitly, this means that there exists a bijective function from ''A'' ont ...

, meaning that it has no bijection to a proper subset of itself. To see this, suppose that

S

is a set that does have a bijection

f

to a proper subset. For each natural number

i\ge 0

define

S_i

to be the set of elements that belong to the image of the

i

-fold composition of with itself but not to the image of the

(i+1)

-fold composition. Then each

S_i

is non-empty, so the union of the sets

S_i

with even indices would be an infinite set whose complement in

S

is also infinite, showing that

S

cannot be amorphous. However, the converse is not necessarily true: it is consistent for there to exist infinite Dedekind-finite sets that are not amorphous.. No amorphous set can be

linearly ordered In mathematics, a total or linear order is a partial order in which any two elements are comparable. That is, a total order is a binary relation \leq on some set X, which satisfies the following for all a, b and c in X: # a \leq a ( reflexive) ...

.. In particular this is the combination of the implications

\text\Rightarrow\text\Rightarrow\Delta_3

which de la Cruz et al. credit respectively to and . Because the image of an amorphous set is itself either amorphous or finite, it follows that every function from an amorphous set to a linearly ordered set has only a finite image. The cofinite filter on an amorphous set is an

ultrafilter In the mathematical field of order theory, an ultrafilter on a given partially ordered set (or "poset") P is a certain subset of P, namely a maximal filter on P; that is, a proper filter on P that cannot be enlarged to a bigger proper filter o ...

. This is because the complement of each infinite subset must not be infinite, so every subset is either finite or cofinite.

Variations

\Pi

is a

partition Partition may refer to: Computing Hardware * Disk partitioning, the division of a hard disk drive * Memory partition, a subdivision of a computer's memory, usually for use by a single job Software * Partition (database), the division of a ...

of an amorphous set into finite subsets, then there must be exactly one integer

n(\Pi)

such that

\Pi

has infinitely many subsets of size

n

; for, if every size was used finitely many times, or if more than one size was used infinitely many times, this information could be used to coarsen the partition and split

\Pi

into two infinite subsets. If an amorphous set has the additional property that, for every partition

\Pi

n(\Pi)=1

, then it is called strictly amorphous or strongly amorphous, and if there is a finite upper bound on

n(\Pi)

then the set is called bounded amorphous. It is consistent with ZF that amorphous sets exist and are all bounded, or that they exist and are all unbounded.

References

{{Set theory Axiom of choice Cardinal numbers