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Chapter 10 Algebraic Function Fields
CHAPTER 10 ALGEBRAIC FUNCTION FIELDS
Definitions
10.10
Let that
L
F(L)
and
Introduction
be a lattice in
@.
We have seen in Chapter 7
is a field extension of
as follows. p
which can be described
@
is transcendental over
finite algebraic extension of
@(?).
C
and
F(L)
is a
This will serve as a model
for the definition to follow. Let
K
be a subfield of a field
F.
KcF
will be called
an algebraic function field of one variable, or merely an algebraic function field, if there exists over
K,
such that
F
x
E
F,
transcendental
is an algebraic extension of
K(x)
of
finite degree. Example.
@ c
F(L)
is an algebraic function field.
The theory of algebraic function fields is a large one. We will give only a very brief sketch of it in this chapter, giving frequent references to the literature.
Hopefully we will
write enough to motivate what has been done when
K
is IR
or
C, and thus make Part I11 of this monograph more accessible to the reader not knowledgeable in these matters. The standard reference to this subject is Chevalley's concise and extensive Introduction to the theory of algebraic functions of one variable [16]. A more classical reference to the state of the art c. 1900 is Hensel and Landsberg's Theorie 189
Norman L. Alling
190
der - algebraischen Funktionen einer Veriabeln 1341. Let
10.11
(1)
Let
E
XI
KcF
F
be an algebraic function field (10.10).
be transcendental over
K;
Indeed, since the transcendence degree of definition, 1, x
is algebraic over
[F:K(x)], we see that
[F:K(x,x')]
then [F:K(x')] <
F
over
K(x');
thus
thus
K
m.
is, by
[F:K(x')l
< m l
establishing (1). Thus the definition of an algebraic function field does not depend on the choice of Let
K
be called a field of constants and
of functions (2)
Let
then
It
of f
{a
F :a
E
function field. 2 E x a m p l e 1.
algebraic over F,
and
KI;
EcF
is an algebraic
IRc@(x)
KcF.
is an algebraic function field.
The
@.
will be called a complex (resp. real) algebraic
function field if Let
the field --
is called the field of constants of
field of constants of it is
(3)
F
KcF.
is a subfield of
KcF
x.
FcF1
K = @ (resp. K=IR). be a finite algebraic extension; then
KcF1
is an algebraic function field. We have seen in 18.13 that a compact Riemann surface
x
may be associated with a complex algebraic function field, using the "cut and paste method". structing
X.
Many choices were made in s o con-
That these arbitrary choices do not influence
the final surface
X
is true, but was not manifest in 58.13.
To motivate the way we will presently construct
sider the following example.
x,
let us con-
Algebraic Function Fields Let a:
Example 2.
over
(4)
where
z ( 2 )
If
Oa
Let
=F(C);
thus the
corresponds to an object of analysis
with some algebraic subobject of
C
is transcendental
Our problem is initially to associate a point
and geometry, 1. of
(z)
We saw in Theorem 8.30 that a:
@.
algebraic object @ ( z )
u
c@
191
f
E C ( Z ) :
is regular at
~ ( 2 ) .
ul.
is a proper subring of ~ ( z ) that contains C I
Clearly
-
f E ~ : ( z ) U0
such that for all
I
l/f
E
0,.
Subrings of this
sort occur elsewhere in algebra; they are called valuation rings. (5)
A proper subring
f t - F-L) implies
l / f E
L) L)
Historical note:
of
F
that .contains K
such that
is called a valuation ring of
KcF.
in this form the idea of a valuation
ring goes back to Krull's classic Allgemeine Bewertungstheorie 1461 I written c. 1931. (6)
Let
RiemKF
{ L ) : L)
is a valuation ring of ,Kc F).
We will think of this set as the formal Riemann surface of K
c
F. It is not difficult to show that
Rie%C
( z ) = {Ou:u
E
11.
In order to work with valuation rings we must know more about them.
10.12 (7
E
Let
KcF
be an algebraic function field and let
RiemKF.
(1)
Let
ul
U(L))
(or U M(O)
and let
for short) be the group of units of (or M
for short) be
0 - U.
It may be useful to refer back to Example 2 in 510.11. Clearly
03;
U
thus
(OD) M((7,)
= {f
E
a: ( 2 ) : f has neither a zero or a pole at
is the maximal ideal of
0,.
Further
192 f
E
Norman L. Alling f(a) E C
Oa ->
M(O,).
as kernel
M
af
fc M
M;
for a moment
that
then it is in
that b a f = l ,
Now let g e M;
(3)
f-g
f E U,
Assume that
is a valuation ring
f
f
M;
by (2) is in
f/g
proving (3).
is an ideal in
is zero then clearly
g
are non-zero.
g
g/f
or
f/g
or
and
generality we may assume that
0,
which is absurd; proving
then
+ 1 U.~ If
Indeed, note that
of
such
M.
E
(3) holds.
0, is
af, which must be in
Thus there exists b e 0
U.
showing that
(2)
M
a E 0; then
and let
M.
E
Assume not in
0.
is the maximal ideal of
Let
Proof.
having
These facts suggest general results.
Theorem.
(2)
is a C-linear homomorphism onto d:
is in E
(1.
0
Without loss of
f - g = g (f/g
(1.
Since
- 1) ,
which
From ( 2 ) and (3) we see that
0. Since 0 - M = U,M
is the maximal ideal
proving the Theorem. Clearly
is a subgroup of
K*(:K-{Ol)
U,
thus
K n M = (01.
FO
Clearly K
maps injectively, under the canonical homomorphism
pO,
is called the residue -class field of
onto a subfield of
to a map
let
(4)
U
F*
h
f(O)
Let
E pO(f)
vO
(or v F*/U:
pO
(or p
F
by sending any
Po
EFO u
{a}.
for short) extend
fcF-0
So extended
to po
00,
a
is the
h
E
of course
onto
Let
0.
f6 F
-
is
Let
(5)
FO.
0. Given
place of
F.
of all of
p
point not in
of
O/M
GO
FO.
-
a subgroup of
F*.
for short) be the canonical homomorphism (or G
for short).
193
Algebraic Function Fields The Abelian group
0.
is called the -value group of
G
It will
be written additively, and can be ordered as follows:
(6)
let
v ( 0 nF*).
G'Z
0 = v (1)E G+ ,
Clearly
and clearly
-
What is - at first glance given
(7)
gc
then
then
G,
g
or
f E F*
f
a valuation ring
or
-g
is, accordingly, in
in
G',
-g
0: i.e. ,
and so
g = 0, For
f
and
g
Let
G.
v(f)
0
l/f
is in
G
Assume that
+. l/f
and
h
(=
let
E G
0
g. Since
(10.11:5); hence
g
and
so that
a,b E U
are in
=
0.
Thus
-g fa f
is
g
or
are both and
b/€
is a unit
g,h
if
g-h
is in
linearly) ordered Abelian group.
be an element not in E
If both,
G'.
establishing (7).
is a totally
g
is in
such that
then there exist units
are in
all
a bit surprising is that
g = 0.
Indeed, there exists
G
is closed under addition.
G+
G, ordered to be greater than
G+;
then
Let
m
g
for
v(0) E m .
(8)
For all
a,b
(9)
Further, if
E
F, v(a
k
b) Lmin(v(a) , v ( b ) ) .
v(a) # v(b)
equality holds in (8).
Indeed, without l o s s of generality we may assume that v(a) Iv(b).
If
b#O;
v(b/a),O,
then
b=O
then (8) and (9) hold. andso
clearly (8) holds and, since
b/aEOnF*.
-1 E U , v(a)
=
Assume that If
a + b = 0 then
w (b). Assume that
aib#O.
v(a+b) =v(a(l+b/a)) =v(a) +v(li-b/a) 'v(a),
ing (8).
Assume now that
hence
b/a
E
M.
As a consequence
v (a 2 b) = v (a) + v
The map
v(a) < v(b).
v
(1 f b/a) of
F*
=v
(a),
onto
lkb/a
Then E
U,
v(b/a) > 0
provand
and so
showing that (9) holds. G
is known as the valuation
Norman L. Alling
194
with
associated
0.
Let us return to
E x a m p l e 2 (510.11
f E Q : ( z ) (=F(C)); let
with
{n E Z: n 2 0 )
0,,
and
Let
A
C
thus
vu
RE
f
Q:
u
at
onto
(z)*
2
vU(Uu n @ ( z ) * ) =
Further
is the valuation associated
is its value group.
be an integral domain and let
~
and let
C
E
be the order of
U ( O u ) nq: ( z ) * .
;
Z
quotient field. element
u
Let
is a homomorphism of
having as its kernel Z+(-
vu(f)
vu
Clearly
(86.41).
continued).
R
Let
denote its
A
be a field extension of
is called integral
A
A.
An
if there exists a
monic polynomial
... + mn-l
(10) m(x) E m 0 + m1 x +
as a root.
A
xn-l + xn E A[x]
is integrally closed in
is integral over
A
Lemma.
Each
Proof.
Let
is in 0
a
E
E
if each
is integrally closed in
be integral over
be a monic polynomial with coefficients in a root. hence
Assume, for a moment, that v(an)
<
v(an-l) <
that
. . . < v(a) < 0.
a{O;
F.
Let m(x)
I).
that has
I)
then
(10)
as
a
u(a) < 0
and
Since 1 nmn-l a r nv(a) ,min(v(mo)
... + w (a), . . . , v (mn-l)+ (n-l)v (a)) 2 (n-l)v (a);
a n = - m o - m1 c1-
v (m,)
a~ A
c1
A.
RiemKF
F
A
which has
which is
absurd, proving the Lemma.
10.13
Valuation theory can also be used to good effect
in number theory.
Let
a prime ideal in A. (1)
Let Pe
A
be an integral domain and let P
Let
A
A p - {a/bE A: a E A {a/b
E
A: a E P
and
be the field of quotients of and b
E
bEA-PI
A -PI;
be A.
and let
then
Ap, which is
Algebraic Function Fields called the ring
A
localized at P,
contains A, and Pe Pe n A = P . Further (2)
Pe
Indeed, give
- Pe.
Lemma.
Let
p
E
- Pel f = a/b with a,b E A - P; thus Hence Ap - Pe = u (Ap), establishing (2).
A
is a prime ideal in
in
A
be a unique factorization domain and let
Let
A.
Ap
A.
Let
P ZAP;
f e A-A,.
Then
f=a/b,
with
thus
plb.
Hence
a
is not in
P,
a
Since
and so
then
P
A.
is a valuation ring of
having no common irreducible factors.
b e P;
such that
Ap.
denote an irreducible element in
Proof.
Ap
that
f E Ap
Ap
f-l = b/a
A
is a subring of
is a prime ideal in
is the maximal ideal in
195
and
b
fpAp, b/aEAp,
proving the Lemma. We can apply this lemma to the following examples. E x a m p l e 1.
0 - z P (PI numbers.
is
Let
p
be a prime number; then by the Lemma,
is a valuation ring of the field Q1
of rational
It is easy to see that the residue class field of
Z
PI
the field having
p
elements.
easy to see that the value group of E x a m p l e 2.
Let
K
reducible polynomial in
Up
is
Further it is Z.
be a field and let K[x]
.
m(x)
be an ir-
By the lemma,
0 - 0
:K[x] is a valuation ring in the field K(x). m (x) (m(x)1 It is again easy to see the residue class field of 0 is
K-isomorphic to
K[x]/(m(x))
and that the value group is
Z.
That these two examples seem so similar, one drawn from number theory and the other from algebraic function theory, might be superficial; however it is not.
The development and
interrelations between these two fields lies outside the scope
Norman L. Alling
196
of this monograph; however before leaving this fascinating topic in comparative mathematics, let us point out an essential difference between these two topics. It is not difficult to show that given
Example 1 ( c o n t . ) .
any valuation ring number
p
see that
such that 2
Q, then there exists a unique prime
of
I)
o=I)
P'
Further it is not difficult to
is the intersection of all valuation subrings of
Q. Example 2
(cont.)
om 5 K [l/x] (l/x)
.
K[l/x]
is a subring of
is a valuation subring of
valuation ring at
(Note: if
co.
K(x),
I)
E
that is
0=0
(m(x))
*
the
here defined
It is not difficult
o = om
RiemKK(x), then either
there exists an irreducible polynomial m(x)
and
called
om
K = @ , then
and as defined in (10.11:4) are identical.) to show that given any
K(x)
in
K[x]
Clearly the intersection of all
0
E
or
such RiemKK(x)
K. Historical note.
The names of Hansel and Hasse are
associated with early applications of valuation theoretic methods to algebraic number theory.
See Endler's excellent
monograph on valuation theory [21] for additional details. Finally let us consider an example that will prove useful in Part I11 of this monograph. Example
3.
In studying R i e w ( x )
Example 2 above, that we must study maximal ideal of IR[x]
.
Given
m
E
we have seen, in
SpecmIR[xl, the set of
Specm lR[x] ,
it is, of course,
a principal ideal generated by an irreducible monic polynomial m(x) x-r,
in IR[x]. for some
m(x)
is of one of two types:
r E ~ R ; or it is
it is either
2
x + b x + c , with
Thus it is natural to associate SpecmIR[x]
with
b 2 - 4 c < 0.
Algebraic Function Fields
Q;+ E { z
(3)
c c : Im(z) > 03.
Hence it is natural to associate
with c + u
RieW(x)
{a}.
Extensions
10.20
Let
197
be an algebraic function field and let
KcF
be a finite algebraic extension of degree
n.
FcF
(As a general
reference on valuations and extensions see e.g., [ 7 0 , vol.11, Chapter VI].
This theory is not trivial.
Most of the results
in this section will be stated, but not proved.
Proofs may be
found e.g., in [ 7 0 , ~01.111. ) Let (1)
U
0E X
8 be in RiemK $:?
0 : ~ ( 8 )-
and let
8
nF;
then
E Riem F.
K
5
will be said to be under
6
and
extension theorem (see e.g. [16, p . 6 1 )
0. The place has many consequences.
One of them is the following: (2)
given Let
0 E X,
M
there exists
8 2
such that
E
0 and let
be the maximal ideal of
8;
maximal ideal of
then
k
n
0 = M.
~ ( 8 =) 0. be the
Then the following dia-
gram is commutative and row exact:
O ->
2
->
8
->
U / M ->
0
0 ->
M ->
0
->
U / M ->
0
A unique K-isomorphism
g
(3)
of
I
0, into ?J/G
t
*
of
-
U/M,
the residue class field
the residue class field of
fined so that ( 3 ) is commutative.
fication. (4)
Let
g
8,
serve as an identi-
Then
[a/i: O / M l
:f,
is finite.
It is called the relative degree of
-
can be de-
0 over
0.
198
Norman L. Alling
fi
Let
-
U.
(5)
-
0.
valuation associated with group of
0=
U n
0 ->
i j L > F*
0 ->
1 2
-’ GV
F* ->
U->
->
0
.
G - > O
of
Let
h
is of finite index
into
G
can be defined
serve as an identification.
Then
e
be the value
ih 13
making (5) commutative.
G
Let
U.
The following diagram is commutative and row exact:
A unique group isomorphism h
(6)
8 and let 5 be the
be the group of units of
e
in
is called ramification index of
-
G.
8
over
0.
As a corollary of (6) we have the following
(7)
is isomorphic to
2.
then
is finite. We have noted (Example 2 (10.13))
G
is isomorphic to
2.
and let
F - K(x);
x
[F:F]
be transcendental over
K
Indeed, let
that
Using (6) we see that (7) holds.
Let us consider some examples to illustrate these
10.21
phenomena. E x a m p l e 1.
U FlR[x] is IR
and let (XI and that of
of
is 2 .
-
f
Example 2 .
0 E@ [ z ]
(XI
10.22
8
8
F -lR(x)
a :Q: [XI
over
and
EC(x).
Let
-
The residue class field of 0 (XI is @ ; thus the relative degree (10.20:4)
-
K-Q:,
Let
and let
(10.20:6) of
K-IR,
Let
0 EQ: [ z
2
F
I
is
Assume now that
- @ ( Z ) ~
(,2)
-
and let
2 F - @ ( z ).
Let
then the ramification index
2.
-
FcF
is a separable extension.
Algebraic Function Fields
-
(This will - of course
be assured if
K
199
is of characteristic
zero, which it will be in all the central applications in this monograph.)
over
0. For
over
0
1 1 1k'
and let
e
0;
(1)
f
O1,...,Ok
E
-
X
aj
be the relative degree of
j
be the ramification index of
j
be the points
aj
over
... + ekfk =n.
e1f1 +
then
let
-
*
0 E X , let
Given any
Theorem.
(It takes a fair amount of space and care to prove this. A proof may be found as Theorem 20 [ 7 0 , vol.11, pp.60-611.
See
also the remark in the penultimate paragraph of 170, vol.11,
-
P.631 1 There are many applications of this beautiful theorem. Let
E x a m p l e 1.
K -@.
numbers and let L
elle2, and
-U E X-
Let
0.
be over
is
@.
Since
of
6
is also
or 2 points.
Finally
E
E
f =l.
n-l(o)
0 :
(10.11:4). 0
Over each
*-'((I) consists of 1
contains 1 point if and only if
Let
K=IR,
F EIR(x)
0
E
e=l=f.
X-
and let
F :@ (x) (as in
3 x 5 { 0 E X : the residue class field of
Let
nl. ax = m[xI (x-r):r c I R 1
each point
and let
Hence
u
ax there is only one point in
f=2.
C
00.
Example 1, 110.21).
0
u
(x,y), where
Clearly the residue class field of
thus
@;
Example 2.
is
Let
F SQ:
is algebraically closed the residue class field
Q:
u=el,e2,e3, or
0
be distinct complex
F -a: (x) and let
Let
y = 4(x-el) (x-e2)(x-e,).
e3
ax
'&[[l/xl over
1.
For each
0, since n = 2
and
there exist two points, since for
Norman L. Alling
200
The
10.30
d complex a l g e b r a i c f u n c t i o n
Riemann s u r f a c e
field
Let C c F and 10.11)
.
be a complex algebraic function field (10.10
X
Let
5
Riem F
C
ically closed,each 0 E X has C h
F O = Z,
(10.12); thus C
Since C
(10.11:6).
is algebra-
as its residue class field
the Riemann sphere ( ( 1 0 . 1 2 ) and ( 8 . 3 0 ) ) .
has, of course, a topology on it which makes it a compact
surface.
0 E X ->
(1)
Let
fc F
gives rise to a map
?(0) E
C
(10.12:4).
have the weak topology making (1) continuous, for a1 L
X
f E F. (2)
Each
Chevalley [16, p.133 ff.] has proved the following. X
is a compact space.
As remarked before ( 1 0 . 2 0 : 7 ) , thus there exists
2;
fE F
the value group of
such that
0
is
vO(f) = 1.
Chevalley has also shown that (3)
f
is a local uniformizer at
0; thus X
is a compact
surface. Finally Chevalley has shown that the Atlas so defined is analytic ( 8 . 2 0 ) (4)
X
;
thus
becomes a compact Riemann surface X
is a meromorphic function on
X;
and
such that each
f E F ->
2
E
F(X)
is
a surjective @-isomorphism. Remark.
structing X
In the author's opinion,Chevalley's method of confrom C c F
is a great improvement over the "cut
and paste method" described in 58.13.
4 theorem
10.40
Let
C
of
coeguivalence
be the category whose objects are complex alge-
Algebraic Function Fields
201
braic function fieldsand whose morphisms are @-linear isomorphisms of one such object into another.
S
Let
be the category
whose objects are compact (connected) Riemann surfaces and whose morphisms are analytic surjections of one such object onto (See,e.g., 1501 for the revelent definitions in cate-
another.
gory theory.) let
f
Let
@
cF
and let
of generality, we may take @
@ cF
and
cF
of the morphism
f.
Let
into
[F : F].
Riem F
5
X
and
@
n
(Riem f) ( ? ) E
then
Riem f
@
F
Since
C F is a finite
is called the degree
-
,..
X :Riem F ;
c
S.
a
Given
2 n F;
Riem@
Lemma 1.
-
F.
then,
are compact Riemann surfaces:
is an analytic map of
a:
and
Then, without l o s s
and let
each is an object in the category
(1)
C
be objects in
F.
to be a subfield of
n: X
Let
as we noted in 510.30, X
,
F
-
cF
are algebraic function fields
algebraic extension.
i.e.
F
be a @-isomorphism of
@
2 onto
X.
let
E
Hence
is a contravariant function of
c
into
S. Y -> a
Now let S.
object in
Y.
tions on
Let
for details.) onto
g
is an
be a triple of object, morphism, and
F(Y)
be the field of a11 meromorphic func-
Using the fundamental existence theorem on Riemann
surfaces, F(Y),
Y
Y
is a proper extension of
Let
g
E
F(Y)
then
-@;
(2)
and
is an analytic map of
It may be shown that there exists
C.
n - to - 1 map of
Y
onto
Z
Then it is not difficult to show that F(Y)
f
(See e.g. , [ 5 8 1
@.
F(V)
are objects in
F(a) (h) ha,
to show that
for all
h
6
c. F(Y)
nc N
such that
(counting rami€ication). [F(Y):
@
(g)]
=n;
thus
Let
.
Then it is not difficult
202
Norman L. Alling
Theorem of c o e q u i v a l e n c e .
Riem
and
Q:
s
is a contravariant functor of
F
Lemma 2 .
into
c.
The contravariant functions
establish a coequivalence of the categories
F
c
S.
and
(See [5, pp.95-1041 for details.) f is a triple of object, morphism, and Thus if F1 > F2
C;
object in F1
(3)
L.
If
X 2 ->
in
S,
(4)
then
@ F(Rie% F1)
a
X1
F (Riem@f )
> F(Riemc F 2 ) = @ F 2 .
is a triple of object, morphism, and object
then X 2 = Riem F ( X 2 )
Rie%F (a)
Let
Theorem.
x :C/L
X':@/L'.
and
let F '
> Riem F(X1) =
c
c
L
and Let
L'
F
be lattices in
@.
Let
F(L) (or equivalently F ( X ) )
(or equivalently F ( X ' ) ) .
F(L')
xl. and
The following are
equivalent: L
and
L'
are equivalent lattices ( 6 . 2 3 ) .
(ii) X
and
X'
are analytically equivalent.
(iii) F
and
F'
are @-isomorphic.
(i)
(iv) J (L) = J (L') Proof.
.
By Theorem 8.45, (i) and (ii) are equivalent.
Theorem 10.40, (ii) and (iii) are equivalent.
By
By Theorem 9.29,
(ii) and (iv) are equivalent; proving the Theorem.
The Riemann-Roch Theorem
10.50
Let
X
be a compact Riemann surface, and let
the underlying topological space.
Since
X
X
denote
is a compact
orientable surface,it is homeomorphic to a sphere to which
g
Algebraic Function Fields handles have been adjoined. X
called its genus.
g
203
is a topological invariant of
(See e.g., [51] as a general reference on
the topology of surfaces.)
Let
a
be a divisor on
X.
(See
58.60 for a definition.)
(1)
Let
L(a)
then
L(a)
is a complex subspace of
(2)
L(a)
is of finite complex dimension
Riemann's
(3)
L(a)1'
(4)
Let
{f
E
F(X): (f) >a]; F(X)
. L(a).
Theorem
- g - deg(a) .
i(a),
the index - of specialty of
be the non-negative integer
a,
be defined to
-1 + L (a) + deg (a) + g;
then we have
the following. The Riemann-Roch
Theorem.
For all
a
E
divX,
the follow-
ing holds :
(5)
O=l-.l(a) -deg(a) -g+i(a). The Serre D u a l i t y Theorem.
For all
aEdivX
c U (X) (-a), where
(6)
i (a) = dim
(7)
U(X) (-a) :(6
(Note: D(X)
E
D(X):
(6) > -a}.
was defined in 1 8 . 2 3 . )
The literature on the Riemann-Roch and the Serre Duality Theorems is extensive.
Nevertheless, Gunning's excellent
Lectures 0" Riemann surface [29] would serve to give complete proofs of these beautiful and important results.
10.51
The Riemann-Roch theorem can be stated and proved
for any algebraic function field 113.)
KcF.
In so doing a non-negative integer
the genus of
KcF.
(See e . g . , g
[16, Chapter
emerges, called
One of the great accomplishments of contem-
204
Norman L. Alling
porary algebraic geometry is that it has been able to carry over much algebraic and analytic geometry, that was first discovered and investigated over
@,
to arbitrary ground fields.
Definitions
10.10
Let that
L
F(L)
and
Introduction
be a lattice in
@.
We have seen in Chapter 7
is a field extension of
as follows. p
which can be described
@
is transcendental over
finite algebraic extension of
@(?).
C
and
F(L)
is a
This will serve as a model
for the definition to follow. Let
K
be a subfield of a field
F.
KcF
will be called
an algebraic function field of one variable, or merely an algebraic function field, if there exists over
K,
such that
F
x
E
F,
transcendental
is an algebraic extension of
K(x)
of
finite degree. Example.
@ c
F(L)
is an algebraic function field.
The theory of algebraic function fields is a large one. We will give only a very brief sketch of it in this chapter, giving frequent references to the literature.
Hopefully we will
write enough to motivate what has been done when
K
is IR
or
C, and thus make Part I11 of this monograph more accessible to the reader not knowledgeable in these matters. The standard reference to this subject is Chevalley's concise and extensive Introduction to the theory of algebraic functions of one variable [16]. A more classical reference to the state of the art c. 1900 is Hensel and Landsberg's Theorie 189
Norman L. Alling
190
der - algebraischen Funktionen einer Veriabeln 1341. Let
10.11
(1)
Let
E
XI
KcF
F
be an algebraic function field (10.10).
be transcendental over
K;
Indeed, since the transcendence degree of definition, 1, x
is algebraic over
[F:K(x)], we see that
[F:K(x,x')]
then [F:K(x')] <
F
over
K(x');
thus
thus
K
m.
is, by
[F:K(x')l
< m l
establishing (1). Thus the definition of an algebraic function field does not depend on the choice of Let
K
be called a field of constants and
of functions (2)
Let
then
It
of f
{a
F :a
E
function field. 2 E x a m p l e 1.
algebraic over F,
and
KI;
EcF
is an algebraic
IRc@(x)
KcF.
is an algebraic function field.
The
@.
will be called a complex (resp. real) algebraic
function field if Let
the field --
is called the field of constants of
field of constants of it is
(3)
F
KcF.
is a subfield of
KcF
x.
FcF1
K = @ (resp. K=IR). be a finite algebraic extension; then
KcF1
is an algebraic function field. We have seen in 18.13 that a compact Riemann surface
x
may be associated with a complex algebraic function field, using the "cut and paste method". structing
X.
Many choices were made in s o con-
That these arbitrary choices do not influence
the final surface
X
is true, but was not manifest in 58.13.
To motivate the way we will presently construct
sider the following example.
x,
let us con-
Algebraic Function Fields Let a:
Example 2.
over
(4)
where
z ( 2 )
If
Oa
Let
=F(C);
thus the
corresponds to an object of analysis
with some algebraic subobject of
C
is transcendental
Our problem is initially to associate a point
and geometry, 1. of
(z)
We saw in Theorem 8.30 that a:
@.
algebraic object @ ( z )
u
c@
191
f
E C ( Z ) :
is regular at
~ ( 2 ) .
ul.
is a proper subring of ~ ( z ) that contains C I
Clearly
-
f E ~ : ( z ) U0
such that for all
I
l/f
E
0,.
Subrings of this
sort occur elsewhere in algebra; they are called valuation rings. (5)
A proper subring
f t - F-L) implies
l / f E
L) L)
Historical note:
of
F
that .contains K
such that
is called a valuation ring of
KcF.
in this form the idea of a valuation
ring goes back to Krull's classic Allgemeine Bewertungstheorie 1461 I written c. 1931. (6)
Let
RiemKF
{ L ) : L)
is a valuation ring of ,Kc F).
We will think of this set as the formal Riemann surface of K
c
F. It is not difficult to show that
Rie%C
( z ) = {Ou:u
E
11.
In order to work with valuation rings we must know more about them.
10.12 (7
E
Let
KcF
be an algebraic function field and let
RiemKF.
(1)
Let
ul
U(L))
(or U M(O)
and let
for short) be the group of units of (or M
for short) be
0 - U.
It may be useful to refer back to Example 2 in 510.11. Clearly
03;
U
thus
(OD) M((7,)
= {f
E
a: ( 2 ) : f has neither a zero or a pole at
is the maximal ideal of
0,.
Further
192 f
E
Norman L. Alling f(a) E C
Oa ->
M(O,).
as kernel
M
af
fc M
M;
for a moment
that
then it is in
that b a f = l ,
Now let g e M;
(3)
f-g
f E U,
Assume that
is a valuation ring
f
f
M;
by (2) is in
f/g
proving (3).
is an ideal in
is zero then clearly
g
are non-zero.
g
g/f
or
f/g
or
and
generality we may assume that
0,
which is absurd; proving
then
+ 1 U.~ If
Indeed, note that
of
such
M.
E
(3) holds.
0, is
af, which must be in
Thus there exists b e 0
U.
showing that
(2)
M
a E 0; then
and let
M.
E
Assume not in
0.
is the maximal ideal of
Let
Proof.
having
These facts suggest general results.
Theorem.
(2)
is a C-linear homomorphism onto d:
is in E
(1.
0
Without loss of
f - g = g (f/g
(1.
Since
- 1) ,
which
From ( 2 ) and (3) we see that
0. Since 0 - M = U,M
is the maximal ideal
proving the Theorem. Clearly
is a subgroup of
K*(:K-{Ol)
U,
thus
K n M = (01.
FO
Clearly K
maps injectively, under the canonical homomorphism
pO,
is called the residue -class field of
onto a subfield of
to a map
let
(4)
U
F*
h
f(O)
Let
E pO(f)
vO
(or v F*/U:
pO
(or p
F
by sending any
Po
EFO u
{a}.
for short) extend
fcF-0
So extended
to po
00,
a
is the
h
E
of course
onto
Let
0.
f6 F
-
is
Let
(5)
FO.
0. Given
place of
F.
of all of
p
point not in
of
O/M
GO
FO.
-
a subgroup of
F*.
for short) be the canonical homomorphism (or G
for short).
193
Algebraic Function Fields The Abelian group
0.
is called the -value group of
G
It will
be written additively, and can be ordered as follows:
(6)
let
v ( 0 nF*).
G'Z
0 = v (1)E G+ ,
Clearly
and clearly
-
What is - at first glance given
(7)
gc
then
then
G,
g
or
f E F*
f
a valuation ring
or
-g
is, accordingly, in
in
G',
-g
0: i.e. ,
and so
g = 0, For
f
and
g
Let
G.
v(f)
0
l/f
is in
G
Assume that
+. l/f
and
h
(=
let
E G
0
g. Since
(10.11:5); hence
g
and
so that
a,b E U
are in
=
0.
Thus
-g fa f
is
g
or
are both and
b/€
is a unit
g,h
if
g-h
is in
linearly) ordered Abelian group.
be an element not in E
If both,
G'.
establishing (7).
is a totally
g
is in
such that
then there exist units
are in
all
a bit surprising is that
g = 0.
Indeed, there exists
G
is closed under addition.
G+
G, ordered to be greater than
G+;
then
Let
m
g
for
v(0) E m .
(8)
For all
a,b
(9)
Further, if
E
F, v(a
k
b) Lmin(v(a) , v ( b ) ) .
v(a) # v(b)
equality holds in (8).
Indeed, without l o s s of generality we may assume that v(a) Iv(b).
If
b#O;
v(b/a),O,
then
b=O
then (8) and (9) hold. andso
clearly (8) holds and, since
b/aEOnF*.
-1 E U , v(a)
=
Assume that If
a + b = 0 then
w (b). Assume that
aib#O.
v(a+b) =v(a(l+b/a)) =v(a) +v(li-b/a) 'v(a),
ing (8).
Assume now that
hence
b/a
E
M.
As a consequence
v (a 2 b) = v (a) + v
The map
v(a) < v(b).
v
(1 f b/a) of
F*
=v
(a),
onto
lkb/a
Then E
U,
v(b/a) > 0
provand
and so
showing that (9) holds. G
is known as the valuation
Norman L. Alling
194
with
associated
0.
Let us return to
E x a m p l e 2 (510.11
f E Q : ( z ) (=F(C)); let
with
{n E Z: n 2 0 )
0,,
and
Let
A
C
thus
vu
RE
f
Q:
u
at
onto
(z)*
2
vU(Uu n @ ( z ) * ) =
Further
is the valuation associated
is its value group.
be an integral domain and let
~
and let
C
E
be the order of
U ( O u ) nq: ( z ) * .
;
Z
quotient field. element
u
Let
is a homomorphism of
having as its kernel Z+(-
vu(f)
vu
Clearly
(86.41).
continued).
R
Let
denote its
A
be a field extension of
is called integral
A
A.
An
if there exists a
monic polynomial
... + mn-l
(10) m(x) E m 0 + m1 x +
as a root.
A
xn-l + xn E A[x]
is integrally closed in
is integral over
A
Lemma.
Each
Proof.
Let
is in 0
a
E
E
if each
is integrally closed in
be integral over
be a monic polynomial with coefficients in a root. hence
Assume, for a moment, that v(an)
<
v(an-l) <
that
. . . < v(a) < 0.
a{O;
F.
Let m(x)
I).
that has
I)
then
(10)
as
a
u(a) < 0
and
Since 1 nmn-l a r nv(a) ,min(v(mo)
... + w (a), . . . , v (mn-l)+ (n-l)v (a)) 2 (n-l)v (a);
a n = - m o - m1 c1-
v (m,)
a~ A
c1
A.
RiemKF
F
A
which has
which is
absurd, proving the Lemma.
10.13
Valuation theory can also be used to good effect
in number theory.
Let
a prime ideal in A. (1)
Let Pe
A
be an integral domain and let P
Let
A
A p - {a/bE A: a E A {a/b
E
A: a E P
and
be the field of quotients of and b
E
bEA-PI
A -PI;
be A.
and let
then
Ap, which is
Algebraic Function Fields called the ring
A
localized at P,
contains A, and Pe Pe n A = P . Further (2)
Pe
Indeed, give
- Pe.
Lemma.
Let
p
E
- Pel f = a/b with a,b E A - P; thus Hence Ap - Pe = u (Ap), establishing (2).
A
is a prime ideal in
in
A
be a unique factorization domain and let
Let
A.
Ap
A.
Let
P ZAP;
f e A-A,.
Then
f=a/b,
with
thus
plb.
Hence
a
is not in
P,
a
Since
and so
then
P
A.
is a valuation ring of
having no common irreducible factors.
b e P;
such that
Ap.
denote an irreducible element in
Proof.
Ap
that
f E Ap
Ap
f-l = b/a
A
is a subring of
is a prime ideal in
is the maximal ideal in
195
and
b
fpAp, b/aEAp,
proving the Lemma. We can apply this lemma to the following examples. E x a m p l e 1.
0 - z P (PI numbers.
is
Let
p
be a prime number; then by the Lemma,
is a valuation ring of the field Q1
of rational
It is easy to see that the residue class field of
Z
PI
the field having
p
elements.
easy to see that the value group of E x a m p l e 2.
Let
K
reducible polynomial in
Up
is
Further it is Z.
be a field and let K[x]
.
m(x)
be an ir-
By the lemma,
0 - 0
:K[x] is a valuation ring in the field K(x). m (x) (m(x)1 It is again easy to see the residue class field of 0 is
K-isomorphic to
K[x]/(m(x))
and that the value group is
Z.
That these two examples seem so similar, one drawn from number theory and the other from algebraic function theory, might be superficial; however it is not.
The development and
interrelations between these two fields lies outside the scope
Norman L. Alling
196
of this monograph; however before leaving this fascinating topic in comparative mathematics, let us point out an essential difference between these two topics. It is not difficult to show that given
Example 1 ( c o n t . ) .
any valuation ring number
p
see that
such that 2
Q, then there exists a unique prime
of
I)
o=I)
P'
Further it is not difficult to
is the intersection of all valuation subrings of
Q. Example 2
(cont.)
om 5 K [l/x] (l/x)
.
K[l/x]
is a subring of
is a valuation subring of
valuation ring at
(Note: if
co.
K(x),
I)
E
that is
0=0
(m(x))
*
the
here defined
It is not difficult
o = om
RiemKK(x), then either
there exists an irreducible polynomial m(x)
and
called
om
K = @ , then
and as defined in (10.11:4) are identical.) to show that given any
K(x)
in
K[x]
Clearly the intersection of all
0
E
or
such RiemKK(x)
K. Historical note.
The names of Hansel and Hasse are
associated with early applications of valuation theoretic methods to algebraic number theory.
See Endler's excellent
monograph on valuation theory [21] for additional details. Finally let us consider an example that will prove useful in Part I11 of this monograph. Example
3.
In studying R i e w ( x )
Example 2 above, that we must study maximal ideal of IR[x]
.
Given
m
E
we have seen, in
SpecmIR[xl, the set of
Specm lR[x] ,
it is, of course,
a principal ideal generated by an irreducible monic polynomial m(x) x-r,
in IR[x]. for some
m(x)
is of one of two types:
r E ~ R ; or it is
it is either
2
x + b x + c , with
Thus it is natural to associate SpecmIR[x]
with
b 2 - 4 c < 0.
Algebraic Function Fields
Q;+ E { z
(3)
c c : Im(z) > 03.
Hence it is natural to associate
with c + u
RieW(x)
{a}.
Extensions
10.20
Let
197
be an algebraic function field and let
KcF
be a finite algebraic extension of degree
n.
FcF
(As a general
reference on valuations and extensions see e.g., [ 7 0 , vol.11, Chapter VI].
This theory is not trivial.
Most of the results
in this section will be stated, but not proved.
Proofs may be
found e.g., in [ 7 0 , ~01.111. ) Let (1)
U
0E X
8 be in RiemK $:?
0 : ~ ( 8 )-
and let
8
nF;
then
E Riem F.
K
5
will be said to be under
6
and
extension theorem (see e.g. [16, p . 6 1 )
0. The place has many consequences.
One of them is the following: (2)
given Let
0 E X,
M
there exists
8 2
such that
E
0 and let
be the maximal ideal of
8;
maximal ideal of
then
k
n
0 = M.
~ ( 8 =) 0. be the
Then the following dia-
gram is commutative and row exact:
O ->
2
->
8
->
U / M ->
0
0 ->
M ->
0
->
U / M ->
0
A unique K-isomorphism
g
(3)
of
I
0, into ?J/G
t
*
of
-
U/M,
the residue class field
the residue class field of
fined so that ( 3 ) is commutative.
fication. (4)
Let
g
8,
serve as an identi-
Then
[a/i: O / M l
:f,
is finite.
It is called the relative degree of
-
can be de-
0 over
0.
198
Norman L. Alling
fi
Let
-
U.
(5)
-
0.
valuation associated with group of
0=
U n
0 ->
i j L > F*
0 ->
1 2
-’ GV
F* ->
U->
->
0
.
G - > O
of
Let
h
is of finite index
into
G
can be defined
serve as an identification.
Then
e
be the value
ih 13
making (5) commutative.
G
Let
U.
The following diagram is commutative and row exact:
A unique group isomorphism h
(6)
8 and let 5 be the
be the group of units of
e
in
is called ramification index of
-
G.
8
over
0.
As a corollary of (6) we have the following
(7)
is isomorphic to
2.
then
is finite. We have noted (Example 2 (10.13))
G
is isomorphic to
2.
and let
F - K(x);
x
[F:F]
be transcendental over
K
Indeed, let
that
Using (6) we see that (7) holds.
Let us consider some examples to illustrate these
10.21
phenomena. E x a m p l e 1.
U FlR[x] is IR
and let (XI and that of
of
is 2 .
-
f
Example 2 .
0 E@ [ z ]
(XI
10.22
8
8
F -lR(x)
a :Q: [XI
over
and
EC(x).
Let
-
The residue class field of 0 (XI is @ ; thus the relative degree (10.20:4)
-
K-Q:,
Let
and let
(10.20:6) of
K-IR,
Let
0 EQ: [ z
2
F
I
is
Assume now that
- @ ( Z ) ~
(,2)
-
and let
2 F - @ ( z ).
Let
then the ramification index
2.
-
FcF
is a separable extension.
Algebraic Function Fields
-
(This will - of course
be assured if
K
199
is of characteristic
zero, which it will be in all the central applications in this monograph.)
over
0. For
over
0
1 1 1k'
and let
e
0;
(1)
f
O1,...,Ok
E
-
X
aj
be the relative degree of
j
be the ramification index of
j
be the points
aj
over
... + ekfk =n.
e1f1 +
then
let
-
*
0 E X , let
Given any
Theorem.
(It takes a fair amount of space and care to prove this. A proof may be found as Theorem 20 [ 7 0 , vol.11, pp.60-611.
See
also the remark in the penultimate paragraph of 170, vol.11,
-
P.631 1 There are many applications of this beautiful theorem. Let
E x a m p l e 1.
K -@.
numbers and let L
elle2, and
-U E X-
Let
0.
be over
is
@.
Since
of
6
is also
or 2 points.
Finally
E
E
f =l.
n-l(o)
0 :
(10.11:4). 0
Over each
*-'((I) consists of 1
contains 1 point if and only if
Let
K=IR,
F EIR(x)
0
E
e=l=f.
X-
and let
F :@ (x) (as in
3 x 5 { 0 E X : the residue class field of
Let
nl. ax = m[xI (x-r):r c I R 1
each point
and let
Hence
u
ax there is only one point in
f=2.
C
00.
Example 1, 110.21).
0
u
(x,y), where
Clearly the residue class field of
thus
@;
Example 2.
is
Let
F SQ:
is algebraically closed the residue class field
Q:
u=el,e2,e3, or
0
be distinct complex
F -a: (x) and let
Let
y = 4(x-el) (x-e2)(x-e,).
e3
ax
'&[[l/xl over
1.
For each
0, since n = 2
and
there exist two points, since for
Norman L. Alling
200
The
10.30
d complex a l g e b r a i c f u n c t i o n
Riemann s u r f a c e
field
Let C c F and 10.11)
.
be a complex algebraic function field (10.10
X
Let
5
Riem F
C
ically closed,each 0 E X has C h
F O = Z,
(10.12); thus C
Since C
(10.11:6).
is algebra-
as its residue class field
the Riemann sphere ( ( 1 0 . 1 2 ) and ( 8 . 3 0 ) ) .
has, of course, a topology on it which makes it a compact
surface.
0 E X ->
(1)
Let
fc F
gives rise to a map
?(0) E
C
(10.12:4).
have the weak topology making (1) continuous, for a1 L
X
f E F. (2)
Each
Chevalley [16, p.133 ff.] has proved the following. X
is a compact space.
As remarked before ( 1 0 . 2 0 : 7 ) , thus there exists
2;
fE F
the value group of
such that
0
is
vO(f) = 1.
Chevalley has also shown that (3)
f
is a local uniformizer at
0; thus X
is a compact
surface. Finally Chevalley has shown that the Atlas so defined is analytic ( 8 . 2 0 ) (4)
X
;
thus
becomes a compact Riemann surface X
is a meromorphic function on
X;
and
such that each
f E F ->
2
E
F(X)
is
a surjective @-isomorphism. Remark.
structing X
In the author's opinion,Chevalley's method of confrom C c F
is a great improvement over the "cut
and paste method" described in 58.13.
4 theorem
10.40
Let
C
of
coeguivalence
be the category whose objects are complex alge-
Algebraic Function Fields
201
braic function fieldsand whose morphisms are @-linear isomorphisms of one such object into another.
S
Let
be the category
whose objects are compact (connected) Riemann surfaces and whose morphisms are analytic surjections of one such object onto (See,e.g., 1501 for the revelent definitions in cate-
another.
gory theory.) let
f
Let
@
cF
and let
of generality, we may take @
@ cF
and
cF
of the morphism
f.
Let
into
[F : F].
Riem F
5
X
and
@
n
(Riem f) ( ? ) E
then
Riem f
@
F
Since
C F is a finite
is called the degree
-
,..
X :Riem F ;
c
S.
a
Given
2 n F;
Riem@
Lemma 1.
-
F.
then,
are compact Riemann surfaces:
is an analytic map of
a:
and
Then, without l o s s
and let
each is an object in the category
(1)
C
be objects in
F.
to be a subfield of
n: X
Let
as we noted in 510.30, X
,
F
-
cF
are algebraic function fields
algebraic extension.
i.e.
F
be a @-isomorphism of
@
2 onto
X.
let
E
Hence
is a contravariant function of
c
into
S. Y -> a
Now let S.
object in
Y.
tions on
Let
for details.) onto
g
is an
be a triple of object, morphism, and
F(Y)
be the field of a11 meromorphic func-
Using the fundamental existence theorem on Riemann
surfaces, F(Y),
Y
Y
is a proper extension of
Let
g
E
F(Y)
then
-@;
(2)
and
is an analytic map of
It may be shown that there exists
C.
n - to - 1 map of
Y
onto
Z
Then it is not difficult to show that F(Y)
f
(See e.g. , [ 5 8 1
@.
F(V)
are objects in
F(a) (h) ha,
to show that
for all
h
6
c. F(Y)
nc N
such that
(counting rami€ication). [F(Y):
@
(g)]
=n;
thus
Let
.
Then it is not difficult
202
Norman L. Alling
Theorem of c o e q u i v a l e n c e .
Riem
and
Q:
s
is a contravariant functor of
F
Lemma 2 .
into
c.
The contravariant functions
establish a coequivalence of the categories
F
c
S.
and
(See [5, pp.95-1041 for details.) f is a triple of object, morphism, and Thus if F1 > F2
C;
object in F1
(3)
L.
If
X 2 ->
in
S,
(4)
then
@ F(Rie% F1)
a
X1
F (Riem@f )
> F(Riemc F 2 ) = @ F 2 .
is a triple of object, morphism, and object
then X 2 = Riem F ( X 2 )
Rie%F (a)
Let
Theorem.
x :C/L
X':@/L'.
and
let F '
> Riem F(X1) =
c
c
L
and Let
L'
F
be lattices in
@.
Let
F(L) (or equivalently F ( X ) )
(or equivalently F ( X ' ) ) .
F(L')
xl. and
The following are
equivalent: L
and
L'
are equivalent lattices ( 6 . 2 3 ) .
(ii) X
and
X'
are analytically equivalent.
(iii) F
and
F'
are @-isomorphic.
(i)
(iv) J (L) = J (L') Proof.
.
By Theorem 8.45, (i) and (ii) are equivalent.
Theorem 10.40, (ii) and (iii) are equivalent.
By
By Theorem 9.29,
(ii) and (iv) are equivalent; proving the Theorem.
The Riemann-Roch Theorem
10.50
Let
X
be a compact Riemann surface, and let
the underlying topological space.
Since
X
X
denote
is a compact
orientable surface,it is homeomorphic to a sphere to which
g
Algebraic Function Fields handles have been adjoined. X
called its genus.
g
203
is a topological invariant of
(See e.g., [51] as a general reference on
the topology of surfaces.)
Let
a
be a divisor on
X.
(See
58.60 for a definition.)
(1)
Let
L(a)
then
L(a)
is a complex subspace of
(2)
L(a)
is of finite complex dimension
Riemann's
(3)
L(a)1'
(4)
Let
{f
E
F(X): (f) >a]; F(X)
. L(a).
Theorem
- g - deg(a) .
i(a),
the index - of specialty of
be the non-negative integer
a,
be defined to
-1 + L (a) + deg (a) + g;
then we have
the following. The Riemann-Roch
Theorem.
For all
a
E
divX,
the follow-
ing holds :
(5)
O=l-.l(a) -deg(a) -g+i(a). The Serre D u a l i t y Theorem.
For all
aEdivX
c U (X) (-a), where
(6)
i (a) = dim
(7)
U(X) (-a) :(6
(Note: D(X)
E
D(X):
(6) > -a}.
was defined in 1 8 . 2 3 . )
The literature on the Riemann-Roch and the Serre Duality Theorems is extensive.
Nevertheless, Gunning's excellent
Lectures 0" Riemann surface [29] would serve to give complete proofs of these beautiful and important results.
10.51
The Riemann-Roch theorem can be stated and proved
for any algebraic function field 113.)
KcF.
In so doing a non-negative integer
the genus of
KcF.
(See e . g . , g
[16, Chapter
emerges, called
One of the great accomplishments of contem-
204
Norman L. Alling
porary algebraic geometry is that it has been able to carry over much algebraic and analytic geometry, that was first discovered and investigated over
@,
to arbitrary ground fields.