Axiom Of Choice

This non-implication, Form 270 \( \not \Rightarrow \) Form 101, whose code is 4, is constructed around a proven non-implication as follows:

An (optional) implication of code 1 or code 2 is given. In this case, it's Code 2: 9824, whose string of implications is: 14 \(\Rightarrow\) 270
A proven non-implication whose code is 3. In this case, it's Code 3: 1414, Form 14 \( \not \Rightarrow \) Form 369 whose summary information is:

Hypothesis Statement

Form 14 BPI: Every Boolean algebra has a prime ideal. 

Conclusion Statement

Form 369 If \(\Bbb R\) is partitioned into two sets, at least one of them has cardinality \(2^{\aleph_0}\).
An (optional) implication of code 1 or code 2 is given. In this case, it's Code 2: 7083, whose string of implications is: 101 \(\Rightarrow\) 100 \(\Rightarrow\) 369

Hypothesis	Statement
Form 14	<p> <strong>BPI:</strong> Every Boolean algebra has a prime ideal. </p>

Conclusion	Statement
Form 369	<p> If \(\Bbb R\) is partitioned into two sets, at least one of them has cardinality \(2^{\aleph_0}\). </p>

The conclusion Form 270 \( \not \Rightarrow \) Form 101 then follows.

Finally, the
List of models where hypothesis is true and the conclusion is false:

Name	Statement
\(\cal M1\) Cohen's original model	Add a denumerable number of generic reals (subsets of \(\omega\)), \(a_1\), \(a_2\), \(\cdots\), along with the set \(b\) containing them