(more info)

Math for the people, by the people.

Main Menu

sections Encyclopædia
Papers
Books
Expositions

meta Requests (210)
Orphanage
Unclass'd (1)
Unproven (473)
Corrections (34)
Classification

talkback Polls
Forums
Feedback
Bug Reports

downloads Snapshots
PM Book

information News
Docs
Wiki
ChangeLog
TODO List
Legalese
About

Entry average rating: No information on entry rating

Banach-Tarski paradox

(Theorem)

The -dimensional ball can be split in a finite number of pieces which can be pasted together to give two balls of the same volume as the first!

Let us formulate the theorem formally. We say that a set $A\subset \mathbb{R}^n$ is decomposable in pieces $A_1,\ldots, A_N$ if there exist some isometries $\theta_1,\ldots,\theta_N$ of $\mathbb{R}^n$ such that $A=\theta_1(A_1)\cup\ldots\cup \theta_N(A_N)$ while $\theta_1(A_1),\ldots,\theta_N(A_N)$ are all disjoint.

We then say that two sets $A,B\subset \mathbb{R}^n$ are equi-decomposable if both and are decomposable in the same pieces $A_1,\ldots,A_N$ .

Theorem 1 (Banach-Tarski) The unit ball $\mathbb{B}^3\subset \mathbb{R}^3$ is equi-decomposable to the union of two disjoint unit balls.

Comments

The actual number of pieces needed for this decomposition is not so large. Say that ten pieces are enough.

Also it is not important that the set considered is a ball. Every two set with non empty interior are equi-decomposable in $\mathbb{R}^3$ . Also the ambient space can be chosen larger. The theorem is true in all $\mathbb{R}^n$ with $n\ge 3$ but it is not true in $\mathbb{R}^2$ nor in $\mathbb{R}$ .

Where is the paradox? We are saying that a piece of (say) gold can be cut and pasted to obtain two pieces equal to the previous one. And we may divide these two pieces in the same way to obtain four pieces and so on...

We believe that this is not possible since the weight of the piece of gold does not change when I cut it.

A consequence of this theorem is, in fact, that it is not possible to define the volume for all subsets of the -dimensional space. In particular the volume cannot be computed for some of the pieces in which the unit ball is decomposed (some of them are not measurable).

The existence of non-measurable sets is proved more simply and in all dimension by Vitali Theorem. However Banach-Tarski paradox says something more. It says that it is not possible to define a measure on all the subsets of $\mathbb{R}^3$ even if we drop the countable additivity and replace it with a finite additivity:

$\displaystyle \mu(A\cup B) = \mu(A) + \mu (B)\quad \forall A,B\ \mathrm{disjoint}.$

Another point to be noticed is that the proof needs the axiom of choice. So some of the pieces in which the ball is divided are not constructable.

See http://www.math.metu.edu.tr/˜berkman/choice/ for more details.

"Banach-Tarski paradox" is owned by paolini.

(view preamble)

Also defines:

decomposable, equi-decomposable

Attachments:: proof of Banach-Tarski paradox (Proof) by GrafZahl

Log in to rate this entry.
(view current ratings)

Cross-references: point, additivity, countable additivity, even, measure, Vitali Theorem, dimension, measurable, subsets, consequence, weight, divide, cut, paradox, NOR, interior, decomposition, union, unit ball, disjoint, isometries, theorem, volume, finite, ball
There are 4 references to this entry.

This is version 9 of Banach-Tarski paradox, born on 2003-07-17, modified 2006-09-01.
Object id is 4464, canonical name is BanachTarskiParadox.
Accessed 10508 times total.

Classification:

AMS MSC:	03B99 (Mathematical logic and foundations :: General logic :: Miscellaneous)
	28A99 (Measure and integration :: Classical measure theory :: Miscellaneous)

Pending Errata and Addenda

None.[ View all 4 ]

Discussion

forum policy

Interact