There exists an explicit bijection (due to Cayley, that has built up a very nice table to describe this) between the positive roots of the lattice $E_7$ and $\mathbb{F}_2^6 \setminus \{0\}$ (where $\mathbb{F}_2$ is the field with two elements. Btw, this also preserves orthogonality. There is also a relation between $E_8$ and $\mathbb{F}_2^8 \setminus \{0\}$. Is there an explicit description of the features of this relation in the literature?
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$\begingroup$ I don't understand: $E_8$ has 120 positive roots, but $2^8-1=255$. $\endgroup$– abxCommented Aug 12, 2022 at 13:55
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$\begingroup$ Yes, you are right, I am quite confused. The reduction modulo 2 of $E_8$ must have a quadratic form with values in $\mathbb{F}_2$ hence there is a non trivial map from $W(E_8)$ to the orthogonal group $O^+(8,\mathbb{F}_2)$ (with kernel $\pm 1$). So what is the relation with $\mathbb{F}_2^8$? $\endgroup$– IMeasyCommented Aug 12, 2022 at 14:07
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5$\begingroup$ The positive roots correspond to vectors with $q=1$ for the induced quadratic form. This is described for instance in Exercise 1 of Bourbaki Lie groups and Lie algebras, ch. VI, §4. $\endgroup$– abxCommented Aug 12, 2022 at 14:21
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1$\begingroup$ A construction of the E8 root system is described here: en.wikipedia.org/wiki/E8_(mathematics)#E8_root_system $\endgroup$– Sam HopkinsCommented Aug 12, 2022 at 17:27
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$\begingroup$ I have edited the question to make a better link with the answers. $\endgroup$– IMeasyCommented Aug 13, 2022 at 16:04
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1 Answer
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Let $L$ denote the root lattice of $E_8$. The group $W(E_8)$ acts (linearly) on $L/2L \cong \mathbb{F}_2^8$, and hence as a permutation of $2^8=256$ elements. This permutation action has the following three orbits:
- $\{0\}$, an orbit of size 1.
- The classes represented by roots, an orbit of size 120. There are 240 roots in $L$, but each root is equivalent to its negative mod $2L$. In particular, each element of this orbit is represented by a unique positive root.
- The frames, an orbit of size 135. The $E_8$ lattice has $240\cdot9$ vectors of length$^2=4$, and each one is congruent to 16 such vectors (including itself). For example, in a rather standard basis (in which $E_8 \supset D_8 \subset \mathbb{Z}^8$), the vector $(2,0^7)$ is congruent to the 16 vectors $(0^a, \pm 2, 0^{7-a})$.
Incidentally, the stabilizer of a root is $W(E_7)$, whereas the stabilizer of a frame is $W(D_8)$. You do indeed find that $\#W(E_8) = 120\cdot \#W(E_7) = 135 \cdot \#W(D_8)$.
For further details, see for example Section 8.1.2 of Berkeley lectures on Lie and quantum groups. (That section is based on lectures by Richard Borcherds, an expert in lattices.)
answered Aug 13, 2022 at 0:08