## The Classification of (Possible) Root Systems

At long last, we can state the classification of irreducible root systems up to isomorphism. We’ve shown that for each such root system we can construct a connected Dynkin diagram, which determines a Cartan matrix, which determines the root system itself, up to isomorphism. So what he have to find now is a list of Dynkin diagrams which can possibly arise from a root system. And so today we state the

CLASSIFICATION THEOREM

If is an irreducible root system, then its Dynkin diagram is in one of four infinite families, or one of five “exceptional” diagrams. The four infinite families are

The series. These consist of a single long string of roots with single edges connecting them. The diagrams are indexed by the number of roots, starting at :

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The series. These look like the series, except the last two roots are connected by a double edge, with the last root shorter. The diagrams are indexed by the number of roots, starting at :

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The series. These look like the series, except the last root is longer. The diagrams are indexed by the number of roots, starting at :

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The series. These look like the series, except the end is split into two roots. The diagrams are indexed by the number of roots, starting at :

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The exceptional diagrams are

The series. These have a string of roots connected by single edges. On the third root from the end of the string, a single edge branches off to another root on the side. The diagrams are indexed by the number of roots, for , , and :

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The diagram. This consists of four roots in a row. The first two and last two are connected by a single edge, while the middle two are connected by a double edge:

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The diagram. This consists of two roots, connected by a triple edge:

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Our proof will take a number of steps, winnowing down the possible diagrams to this collection. We will spread it over the next week. But over the weekend, you can amuse yourself by working out the Cartan matrices for each of these Dynkin diagrams.

OK, I’m going to have to reread this sequence on root systems again, and more carefully. When I saw your classification of root systems into 4 infinite families and 5 exceptions, my mind went “hey, those look suspiciously like the classification of Lie groups I barely understand…”. Wikipedia confirms that suspicion.

I wondered where you were going with the root systems stuff.

Comment by Blaise Pascal | February 19, 2010 |

Root systems come up in many places, Blaise, and can be motivated and described just in terms of high school notions of spatial transformations. But I might talk about Lie groups eventuallyđ

Comment by John Armstrong | February 19, 2010 |

At long last, as we’ve been thinkin’, we come to Dynkin.

Comment by Jonathan Vos Post | February 20, 2010 |

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Awesome stuff! I have benefited immensely from your posts, thank you for all the work you have put in.

Comment by Sangeeta Bhatia | July 27, 2012 |