18
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If you know it, also try to include the precise reason why the proof is fallacious. To start this off, let me post the one that most people know already:

  1. Let $a = b$.
  2. Then $a^2 = ab$
  3. $a^2 - b^2 = ab - b^2$
  4. Factor to $(a-b)(a+b) = b(a-b)$
  5. Then divide out $(a-b)$ to get $a+b = b$
  6. Since $a = b$, then $b+b = b$
  7. Therefore $2b = b$
  8. Reduce to $2 = 1$

As @jan-gorzny pointed out, in this case, line 5 is wrong since $a = b$ implies $a-b = 0$, and so you can't divide out $(a-b)$.

  • 1
    Community wiki, as there is no one answer?2010-07-20
  • 0
    Ah, I thought I checked it when I posted. Edited.2010-07-20
  • 0
    Perhaps you should also request the answers to include why the particular post is a fallacy. In this case, line 5 is wrong since a=b implies a-b = 0, and so you can't divide out (a-b)2010-07-20
  • 1
    are you looking for more "classic fake proofs" of this type, or something along the lines of "common misconceptions in mathematics"?2010-07-20
  • 0
    @Katie Good point, I just updated the title.2010-07-20
  • 2
    The example given isn't fallacious or fake, it is perfectly acceptable apart from relying on an undefined operation (division by 0). It is however a great example of *why* division by 0 is left undefined, namely that it makes the arithmetic system inconsistent and therefore you can prove anything (such as 1 = 2)2010-07-20
  • 2
    So 1+1 can be equal to 5 for very large values of 2?2013-04-02

4 Answers 4

15

Wikipedia has a long list of these:

http://en.wikipedia.org/wiki/Mathematical_fallacy

5

Well, one I've read quite some time ago (sorry, can't give a reference) is a proof that any bag that contains peas either contains only green or only yellow peas.

The proof goes by induction:

Assume the bag holds only one pea. That pea is of course either green or yellow. Therefore for only one pea, the statement is true.

Now assume we've proven it for $n$ peas, and we are given a bag of $n+1$ peas. In that case, we first take one pea out, so we now have a bag of $n$ peas, so by assumption, they all have the same colour. To find out that colour, we take another pea out, and put our first pea back in. Then by looking at the other pea, we can determine the colour of the peas in the sack, and since there are again $n$ peas in the sack, the one we had removed first also has the same colour as the others.

  • 0
    Similar to [this "proof"](http://www.math.toronto.edu/mathnet/falseProofs/sameAge.html), which has an attached explanation.2014-02-08
4

The two envelopes problem is a good one.

See also:

Card doubling paradox

and:

https://mathoverflow.net/questions/9037

4

The odd number $N = 198585576189 = 3^2 \cdot 7^2 \cdot 11^2 \cdot 13^2 \cdot 22021$ has an interesting property—it is perfect:

$$\sigma(N) = (1 + 3 + 3^2)(1 + 7 + 7^2)(1 + 11 + 11^2)(1 + 13 + 13^2)(1 + 22021) = 397171152378 = 2N$$

Now, where is the catch? (This one was found by René Descartes. It is also the only known odd number to have this property.)

We pretend that the number $22021 = 19^2 \cdot 61$ is prime.