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English Pages 18
I0.
I0. i. of the diagram
Buildings of ty]~e F 4 .
A total ordering (resp. a numbering from I to 4) of the vertices
F4
is called natural if two consecutive vertices are joined by a
single or double stroke (resp. if the ordering determined by this numbering is natural).
Let of the vertices of a chamber of type
&
A
be a building of type
F 4 . We choose a natural ordering
diagr & , and number them from I to 4 accordingly. Let
and, for
I' C (1,2,3,4) , let
I' . By 3.12 and 6.3,
St X34
and
XI.
St X12
denote the face of
C C
o be
of
are flag complexes of projective
planes; in view of 7.10 and 7.11 applied to the polar spaces whose flag complexes are
St X 4
and
St X 1
(cf. 3.12 and 7.4), these planes are Moufang and self-dual.
We shall denote the associated alternative division rings (cf. k(~o)
and
K(~,o)
respectively.
[9]
, 7.1) by
(Notice that, because of the self-duality~ these
rings do not depend on how we number the vertices of
diagr St X54
or
diagr St Xl2
to define the projective planes in question). The polar space of rank 2 associated by 7.4 with the building diagram
St X14
for the obvious ordering of the vertices of its
(2 < 3) will be denoted by
10.2.
S(A,o) .
The main purpose of w I0 is to prove the following theorem,
which gives a complete classification of the buildings of type
THEOREM.
Let
k
be a field and
K
a division algebra over
We assume that one of the followin~ conditions is satisfied:
(i)
K = k
and
char k ? # 2
;
(ii)
K
i.s a separable quadratic extension of
(iii)
K
is a quaternion algebra over
(iv)
K
is a Cayley algebra over
k ;
k ;
F4 .
k;
k .
201
1 (v)
Let
char k = 2
nK : K ~ k
and
form
S(k,K)
K • k 4 -~k
(I)
K , and in the cases (i) and (v) the function
2
be the polar space of rank 2 associated with the quadratic
defined by
F4
and
x I, x 2, x 3, x 4 e k . Then, there exists a buildin6
and a natural orderin6
o(k,K)
up to isomorphism.
o(k,K))
K ~ K(~(k,K),
o(k,K)) . If
- and the
(~(k~K), o(k,K))
(k',K')
(A(k,K),
Conversely, this pair determines uniquely the field
k ~ k(A(k,K),
the ~air
A(k~K) of
of the vertices of its diagram, so that
S(A(k,K), o(k,K)) ~ S(k,K) . This property characterizes the pair
with
x~--~ x
(Xo, x I, x 2, x 3, x~) ~-. nK(xo)-x z x3 + x 2 x 4
fo__~r x 0 e K type
k 2.
denote the quadratic form which is, in the cases (ii) to (iv) th__~e
norm form of the al6ebra Finally, let
kCKc
k -algebra
o(k,K)
k
o(k~K)) - indeed
K , whose ring structure is given by
denotes the opposite of the ordering
is not isomorlohic to any pair
satisfying one of the conditions
(A(k~,K~),
(i) to (v), unless
o(k,K)
o(k~KI)),
(k,K)
is of
type (v), in which case we have the isomorphism
I
i
(n(k,K), 3(k,K)) ~ (n(~,~), o(K,k2))
Given an arbitrary buildin~ of the vertices of
~
of type
diagr ~ , a field
F 4 , there exists a natural ordering k
and a division algebra
fying one of the conditions (i) t2o (v), so that
o(k,~))
(~,o)
K
over
is isomorphic to
.
The proof will be given in 10.3 and 10.12.
k
o satis-
(A(k,K),
202
10.3.
Existence of
10.3.1.
(a(k,K), o(k,K))
In the cases (i) to (iv), we can repeat, mutatis mutandis ,
what has been said in 9.2. There again exists the possibility of explicit constructions, for instance along the llne of [32], VIII to XI, and an other approach, by means of the classification theory of algebraic simple groups. This time, we have to consider the following types of groups (cf. fig. 8; as before, the notations are derived from those of [96], table II, by omitting always the second index) : F~ (split groups of type
F 4 ),
2E~
@
(quasi-split groups of type
@
!
@
E 6 ),
E9
and
E~8
'. @
,
,
r
fig. 8
The theorem 2 and proposition 5 of [96] imply that, over a given field of each one of these types are classified up to central isogeny by a which, according to the type in question, is the field split group of type
F4
over
k
K
itself (there is only one k
(the
E6 ), a division quaternion
algebra, or a division Cayley algebra. We shall denote respectively by ~
k -algebra
k ), a separable quadratic extension of
splitting field of the given quasi-split group of type
k , the groups
= F4 ,
~6 ' ~
and
the ad~oint group of the considered types correspondingto a given
algebra
K . By [8], 6.13 or 6.14 (cf. also [8~], p. 184), all these groups have
203
relative root systems of type its building over
F 4 . Let
k . The vertices of
G
be one of them and let
diagr ~(k,K)
o = o(k,K)
the notations of lO. 1,
St X.. iJ
(ordering from left to right). With
is the building over
L.. 13
is obtained by removing the orbits
G , and its anisotropic kernel is the same as that of ([96], theorem 2) and therefore also quotient of L~. ij
k
of the derived group
of a Levi subgroup of a parabolic subgroup of type
The index of
G (cf. [96], 2.5.1);
be the ordering of these vertices corresponding to the ordering of
the distinguished orbits indicated on fig. 8
Lij
be
are in canonical one to one
correspondence with the distinguished orbits in the index of let
& = ~(k,K)
Lij
St X..
ij i
of
and
G j
(5.2 (iii), 5.4). from the index of
G ; this determines
up to isomorphism. Let
Lij
L~.
by its maximal normal anisotropic subgroup; replacing
be the Lij
by
has no influence on the building (5.5) and amounts to neglecting those connected
components of the index of G~/~
, one has
Lij
L!. iO = L.. iO
which contain no distinguished orbit (actually,
unless
G = ~
and
for
ij = 34 ). Let us also recall
0
that two centrally isogenous groups have the same building (5.4). Now~ a glance at fig. 8
shows that, up to central isogeny,
' LI4
orthogonal group of the quadratic form 10.2 (I), is either the algebraic group whose group of (if
G = ~
) the group
~6
is the neutral component of the LI2 '
is the group
k -rational points is
studied in 5.12. Consequently,
(&,o)
SL 5
!
and
SS(K)
L34 or
has the required
properties:
(1)
s(a,o)
~ S(k,K)
10.3.2.
,
k(~,o)
~ k
,
K(a,o)
~ K
The existence of case (v) in 10.2 is part of a more general
phenomenon related with the existence of strictly special isogenies (9.7.3), and which we now proceed to describe.
Let a field
k
G
be an adjoint split algebraic simple group of type
of characteristic
p , with
X
over
204
X = B n , Cn
or
or
Fh
X = G2
and
and
p = 2
P = 3
,
-I and let G 9 N
K
be a field such that
its normalizer,
B
kc
K C kp
,
G
slonal tmipotent group on which
T
and we call
the set of all
(resp.
U a C B . Let for
a r r
generated by
T(k9
r
)
T(k9
~" ) , N(k,K) 9 all
finally
G(k,K) = X(k,K)
and all
Ua(K )
for
relative to
U (k)
for
a
a ~ r
t ~ T
the group
and all
the group generated by
a c r
a
such that
r
(resp.
r
is denoted by r
)
Ua 9
such that
a(t) s k
(resp.
B(k,K)
the group
9
Ua(K )
T(k,K) , all
)
T . The one-dimen-
(resp.
N(k).T(k,K)
a e r
k -split torus of
T , and
operates through a root
be the group of all
(resp.
a maximal
a Borel subgroup containing
the set of all "long" (resp. "short") roots of
r
T
for Ua(k )
a e
~,,+
for
K )
, and
a c r
9 Straightforward computations, analogous to those of
[17] and using the commutation relations of the
B(k 9 =T(k,K). ~
U(k).
a~r '+
Ua's
II
given there, p. 279 show that
Ua(*)
ace ,,+
where the factors of the product in the right-hand side can be put in an arbitrary order (for this assertion, cf. [8], 3.5)9 and that BN -pair of type
X
in
G(k9
(B(k,K) ,
N(k,K))
.
It is readily verified that i
(2)
Bn(k,K) ~ C n ( K , Z ) ~ P ~ ( q )
cf. 8.2.8), where the quadratic form
q : K • k2n-~k
is defined by
q(x O, x I, ..., X2n) = x20 + x I x 2 + ... + X2n_l X2n
is a
205
Let now with the BN-pair
X = F4
and let
(B(k,K) , N(k,K))
~ = A(k,K)
be the building associated
by 3.2.6. Up to canonical isomorphism, the
diagram of this building is the Coxeter diagram underlying the Dynkin diagram of G ; let
o = o(k,K)
be the ordering of its vertices starting at the extre~mity which
represents a long simple root. Then, it is easily seen, by means of an obvious generalization of 5.2 (iii) and using (2) (for
n = 2 ), that the relations (i) of
iO.3. I hold again.
Remark. The case
10.4. building
X = G2
provides a new class of generalized hexagons.
The following theorem describes the automorphism group of the
~(k,K). When the pair
(k,K)
satisfies one of the conditions (i) to (iv)
of 10.2, it is a consequence of theorem 5.8. In case (v) one can prove it, either by a method analogous to that of 5.11 (using also 8.6
(II) applied to
S(A,o)), or
via a straightforward generalization of 5.8 ; we omit the details.
THEOREM.
Let
k,K
be as in 10.2, set
be the group of all automorphisms of
k
& = &(k,K)
and let
which can be extended to ~
Aut K k
automorphism
o_f K . The other notations are as in 10.5, 5.1 an__~d5.7.2. Then
i__f 10.2 (i) (resp. (iii); (iv)) holds, then an extension of
i_ f
F~(k)
(resp.
10.2 (ii) holds , then
(Aut ~6)(k )
~7(k) ;
Aut A = Spe ~
(itself an extension of
alently, an extension of
E~(k)
~
finally, i___f1 0 . 2 (v) holds, then Aut K k ,
~8(k) )
an__~d Aut Z ~ / S p e A ~ Z / 2 Z
E~(k)
(K,k 2)
by
Aut K k
(cf. 5.9);
and this group!is an extension o__f_f b_yy ~ / / 2 ~
) __bY Aut K k , or, equiv-
[~ e Aut K I ~(k) = k );
Spe A
is ~u extension of
F4(k,K )
o___rI accordin~ as the two Fairs of fields
1
(~,,~) and
Aut ~ = Spe a , and this group is
are isomorphic or not.
206
10.5. tion
~ .
Set
a,b e K - [0} either
k
k = K and
(b,a)C.c = c.(a,b)
and
i - (c,b)
follows from 8.13
x
.
Suppose ,
k , n
c
: L ~k
: K ~k
Let
k
Bn
.
Thus,
is a field,
,
L
c
commutes with ((c,b+l)
is central in
K
- (c,b)).(b+l) and the lemma
is commutative).
quadratic -the -
i__ss
hence
be a field of characteristic
vanishes,
K
can be written
Since
k K
k
(10.2).
from the identity
b .
and that for
extension or a quaternion
(b,a) c = (a,b)
b ~-I
a non-degenerate
the quadratic
2,
K
form representin~
k -vector space
K • k2
a vector 1 , whose ,
a nd d
form
~--~n(x0) + XlX 2
L I = [0) • k • {0}
similitudes
one has
c ---/0 and
LEMMA.
. Then,
The hypothesis
(because it is obvious when
(x0, Xl, x2)
,Set
nK
rin~ with involu-
1 e k
quadratic
~s the norm
commutes with
associated b i l i n e a r form p
separable
it readily follows
10.6. s~aee over
*--~ x~x
division
Assume that
a~b~cba = bJa~cab
In particular,
.
(c,b) that
one has
( x , y ) = xyx -1 y -1
Set
(c,b+l)
be an associative
or a (commutative)
k , and
(a,b).c = e.(a,b)
Le__~t K
_i = [x+x~l x 6 K] .
c e k
itself,
algebra over
LEMMA.
and
(relative to
p
(x 0 E K ; Xl, x 2 c k)
L 2 = [0) • {0] • k . Suppose that the group : cf. 8.2.8)
leavin6 invariant
L1
and
L2
G
of all
is transi-
i tlve on
~-I(0) - L I - L 2 . Then,
x0
~ - ~ n ( X O )2
is a
k -linear bisection
of
K
1 onto a subfield of
k2
qontainin~
k . 1
For is
k -linear (since
x 0 e K , set Bn=
0 )
V(Xo) = n(XO )2 . Clearly, and injective
(since
n
the m a p p i n g
is anisotropic).
v: K Set
-@k
=
207
{e}= v'1(1)
. By hypothesis, if
x 0 ~ K - [0} , there exists
g(e,l,l) = (x0, I, n(XO) ) . This have and
g
multiplies the form
n(Xo).n(K ) = n(K) . It follows that v(K)
LEMMA.
Let
k
be a field and
with a non-de6enerate quadratic form S
by
such that
n(XO) , and we
is a multiplicative group,
is a field, q.e.d.
10.7.
set of
n(K - {0})
p
g ~ G
q : V ~k
S
the polar space assQciated
of Witt index 2. Let
M
be a sub-
containin6 at least two non-collinear ~oints and havin6 the following
property:
(I)
if
s c S
and
collinear with line, then
Then,
x,y E M
are such that both
s , whereaw
x, y, s
(the bilinear form associated with
denotes the projective space of
Let
y
ar_~e
s c M .
M = S , o__r Gq
the codimension of
and
do not belon~ to a same
In the following proof~ the symbol P
x
pl
in
c,d r M
q ) has rank 4 .
or
I stands for
l(q)
P , is at least 5 9
be non-collinear.
and not contained in the linear span
Let
Set A
[a,c,d,Pl]
L = clA
din
be a line of of
S . Let S
a,b ~ L
containing
[a,c,d) U p l
in
LC
M . Let cln
xln of
V
to
{a]
represented by
a I . Since
I
xlN
cln
dI
S
which contains
b
to the
implies that
, it then follows that
and, using again (1), we conclude that
the line of
A
. From 8.2.7 applied to the restriction of
represented b y
q
c,d ~ M , it follows from (I) that
x ~ A - {a] . The assumption made on
dl~a
a
P ~ the
existence of such a line follows from 8.2.7 applied to the restriction of V
and
~q , equal to
V . We assume that the rank of
be distinct (and therefore non-collinear).
hyperplane of
,
q x~O
x c M . Hence
to the subspace L
Is not reduced
A C M . Let
and has a non-empty intersection with
B
be
A . For
2~
every
y c (blA
S) - B , there
line is different (bin
S) - B C M
is a line containing
from the line . Let
all but one meet
z e S - (biN
(bin
Since every point of
[y,b] , hence
y 6 M
and meeting
z e M
A , and this
(always by (I))
S) ; among the lines of
S) - B , consequently B
y
S
and we have
lies on at least two other lines,
and
going through
z ,
S - B C M .
B C M , and the proof
is complete.
10.8.
PROPOSITION.
of a field and an alsebra (v) of 10.2.
Suppose
Then, there exists
an isomo_rphism
defined by
n K = nK,
nK,
implies
the mapping
10.9. satisfies : K ~K
~
which
k
and
nK,
o @
is
one of the conditions an___w S(k',K')
extends
k'
k -linear bijection
and satisfies
K
and
K'
(i) to
are isomorphic. K -~K'
~
: K -~K'
PROPOSITION.
the relations
M(1) = 1
of the norms
nK ,
, as is well known. in the cases
0~ = 0 S(k,K)
(i), and
(ii),
of 10.2 and assume that
(iii) o_~r (v). Let the involution
x~.x = nK(x )
is isomorphic
the polar space associated
from
n K , n K,
We use the notations
one of the conditions
b e defined by
of
,
~ : K -~K'
itself turns out to be an algebra isomorphism
and the definition
fo___r x e K - {0} . Then,
to
with an alternatin~
.
and can be
The bijection
(i) to (iv), the equivalence
of the algebras
consistin5
to an isomorphism
are isomorphic
are proportional.
k -linear
be two pairs
and this is also true in the case (v), as readily follows
dual of the polar space
(i)
and
the isomorphism
the above relations
K
nK
S(k,K)
for a suitable
o ~ . In the cases
(i), (ii) and (iii),
k ~k'
(II), the fields
M(x) = ~(1)-l.@(x)
and
Actually,
forms
an___d (k',K')
ov~ r this field satisfyin~
in such a way that,
the quadratic
(k,K)
that the polar spaces
By 8.6 identified
Let
form in
k4
,
the
2O9
(ii)
the polar space associated with equivalently, with a
(iii)
c -hermitian form (or,
~ -antihermitian form) in
the polar space associated with a
K4
(~,-i) -quadratic form in
K# ,
or
1 (v)
the polar space
S(K, k 2)
respectively.
In the projective space of the right
K4
K -vector space
in the cases (i), (ii), (iii),
1 k~ x K 4
in the case (v) ,
we consider the polar space
S*
associated, in the caSes (i) and (ii), with the
-antihermitian form
in the case (iii), with the
(xl)
~-~
x~ x 3
+
(~,-I) -quadratic form
x~ x 4
+ k
(cf.
8.2.1;
here
K
_l : k
)
and in the case (v), with the quadratic form 1
(Xo, x i) ~-* x~+ xlx 3 + x2x 4
where the index
i
always runs from i to 4 and
(xo ~ k 2)
x i e K . To prove our proposition
210
it clearly suffices to produce a correspondence (a "duality") that, if
x e S(k,K)
y e S* , then
then
[y c S*I (x,y) e D} is a line of
Ix e S(k,K) I (x,y) e D]
lations show that the relation index
i
varies from
0
D
is a line of
D C S(k,K) • S* S*
such
and, conversely, if
S(k,K) . Straightforward calcu-
defined as follows has these properties (here, the
to 4 , the index
j
varies from
0
to 4 in the case (v)
and from 1 to 4 in all other cases, and we use the obvious "homogeneous coordinates" to represent the points of
S(k,K)
and
S* ):
xlx[+xox ~
x~x~=0
O
x2x ~ + ~0x~
((xi),(x~)) ~ D ~:~
- xlx ~ : 0
x3x~-x0x ~
x2x~ = 0
x 4 x ~ - XoX ~ .I _ x3x ~ = 0
The proposition is proved.
I0. i0. that both
S
PROPOSITION.
and its dual
S(k~K) , where
k
S*
Let
S
be a polar space of rank 2, and assume
are embeddable. Then
is a field and
K
~
S
o_~r S*
is isomorphic to some
k -algebra satisfyin~ one of the conditions
(i), (ii), (iii) or (v) of 10.2.
The lines of the points of S*
S
and
S*
S
consist of at least three points, therefore
S* belong to at least three lines;
in other words,
S
and
are thick.
Let
(p, ~, ~)
snd
respectively (cf. 8.7), where vector space with x~
and
~(S)
V (resp. and
y, ... of
S* S*
V' )
with
(P', ~', $')
P (resp. P' )
be dominant embeddings of
S*
and
is the projective space of a right
over a division ring
~'(S*) . The lines of
will be denoted by
S
k (resp. S
x*, y~, . . . .
k' ). We identify
corresponding to points
S
211
From the thickness
(i)
if
~ (resp.
then
~' )
dim P
of
S
and
S* , it follows that
is represented by a symmetric bilinear form,
(resp.
dim P' )
is
> 3 9
To begin with, let us suppose that bilinear form. Let
x, y e S*
~' , there exists of
S*
z e S*
be non-eollinear
such that
which is co]linear
(in
x* , y*
span pairwlse, through
and
z*
and the mapping
x*
the polarity
meeting
S* . From the assumption made on
are collinear in
x*
x
and
and
y*
~x*,y*: y~ -~x*
~x.,y.(S) =
(~) si
with the plane spanned by ~
in
is not represented by a symmetric
y
also meets
s
In other
P
which they
is the inter-
s e y*
z* . This projection being linear,
is represented by a bilinear form. Furthermore,
an easy computation
shows that the above situation cannot occur if this form is antisymmetric, char k = 2 . This discussion and that ~'
~
f r o m n o w on, that
is represented by a symmetric bilinear form; indeedj
k
unless
is commutative
if it were not so,
would be represented by such a form and it would suffice to exchange
Since the embedding q : V -~ k
(P, ~, ~)
is dominant,
S
e i e S* (i = l, 2, 3, 4)
P' . The set
of
[el, e2, e 3, e4]
S*
either
contained in M--S
on
[el, e3}
, that
M
of all points of
is P' : [el, e2, e3, e4] , or
m u s t then be degenerate
and
char k = 2
[e2, e4)
S
~
~
denote
which correspond to lines of 10.7; hence,
has rank 4.
has rank 4. Because of (i),
(cf. 8.2.4).
(frame)
are not
[el, e2, es, e4]
clearly fulfils the hypothesis
We first consider the case where
S* .
~'
and
S* , and the six other pairs are), and let
their linear span in
and
be the four vertices of a quadrangle
S* , ordered in a natural cyclic way (i.e.
collinear in
S
is associated to a quadratic form
(cf. 8.7). We now drop the above restriction
Let in
allows us to assume,
z .
is just the "projection
of a point
and
z~ .
subspace of
(cf. 7.2.3)
A x*
P . Then, every point
is also collinear with
are contained in a 5-dimensional
z* " : the image
section of
x~ y, z
S* ) with both
This means that every line of. S words,
~'
Since the embedding
212
(P', ~', ~')
is dominant,
ratic form in
S~
P' (cf. 8.7).
of all automorphisms