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Relative K0, annihilators, Fitting ideals and the Stickelberger phenomena PDF

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Preview Relative K0, annihilators, Fitting ideals and the Stickelberger phenomena

Relative K , annihilators, Fitting ideals and 0 the Stickelberger phenomena Victor P. Snaith Abstract When G is abelian and l is a prime we show how elements of the relative K-group K (Z [G];Q ) give rise to annihilator/Fitting ideal 0 l l relations of certain associated Z[G]-modules. Examples of this phe- nomenon are ubiquitous. Particularly, we give examples in which G is the Galois group of an extension of global (cid:12)elds and the resulting an- nihilator/Fitting ideal relation is closely connected to Stickelberger’s Theorem and to the conjectures Coates-Sinnott and Brumer. 1 Introduction 1.1 Suppose thatl isaprimeandGisa(cid:12)nitegroup. Inthiscase therelative K-group K (Z [G];Q ) appearing in the localisation sequence (see 2.1) is 0 l l x isomorphic to the zero-th K-group of the category of (cid:12)nite Z [G]-modules l of (cid:12)nite projective dimension, usually denoted by K T(Z [G]). When G is 0 l abelian we have an isomorphism of the form K (Z [G];Q ) = Ql[G](cid:3). 0 l l (cid:24) Zl[G](cid:3) As explained in 2, elements of K (Z [G];Q ) may be constructed from a 0 l l x boundedperfectcomplexofZ [G]-modulestogetherwithaQ [G]-trivialisation l l of its cohomology. In arithmetic and algebraic geometry there are many sit- uations, some of which are studied in 3-5, which give rise to this data. In xx this paper we shall consider the simplest example of this type of element, namely the case of a perfect complex of Z [G]-modules whose cohomology l groups are (cid:12)nite. Our main result concerns the simplest case of all, when the complex has only two non-zero, (cid:12)nite cohomology groups. In this case (The- orem 2.4) when G is abelian, there are Stickelberger-type relations between the element of Q [G](cid:3) which represents the relative K class, the annihilators l 0 and the Fitting ideals of the cohomology groups. In order to apply Theorem 2.4 one must evaluate evaluate the element of Q [G](cid:3) representing the class l on K (Z [G];Q ). In general this is di(cid:14)cult to do but in the cases of abelian 0 l l Galois extensions of function (cid:12)elds and totally real number (cid:12)elds this element turns out to be a classical higher order Stickelberger element (see Theorems 1.6 and 3.4). 1 Let us begin by recalling the higher Stickelberger elements and the con- jectures pertaining to them. Suppose that L=Q is a (cid:12)nite Galois extension of number (cid:12)elds with abelian Galois group, G(L=Q), and L totally real. Then, for each integer n 2, there is a unique unit of the rational group-ring (cid:21) (cid:2) (n) Q[G(L=Q)](cid:3) L=Q 2 such that (cid:31)((cid:2) (n)) = L (1 n;(cid:31)(cid:0)1) L=Q Q (cid:0) for each one-dimensional complex representation (cid:31) where L (s;(cid:31)(cid:0)1) denotes Q the Dirichlet L-function of the character (cid:31)(cid:0)1 ([58] Ch.4). The rationality of (cid:2) (n) is seen by writing the L-function in terms of partial zeta functions L=Q L (1 n;(cid:31)(cid:0)1) = (cid:31)(g)(cid:0)1(cid:16) (g;1 n) Q (cid:0) X Q (cid:0) g2G(LKer((cid:31))=Q) and recalling that (cid:16) (g;1 n) is a rational number, by a result of Klingen Q (cid:0) and Siegel (cf. [48]). Inspired by Stickelberger’s Theorem ([58] p.94), Coates and Sinnott made afundamentalconjecture concerningGaloisactionsonthealgebraicK-groups of algebraic integers in number (cid:12)elds. Conjecture 1.2 ([11]; see also [12]).) In the situation of 1.1, let l be a prime and let denote the ring of L x O algebraic integers of L. For each n 1 (cid:21) w (Q)(cid:2) (n+1) ann (H0(Spec( );Q =Z (n+1))) n+1 L=Q (cid:1) Zl[G(L=Q)] (cid:19)et OL l l ann (K ( ) Z ): (cid:18) Zl[G(L=Q)] 2n OL (cid:10) l Here w (Q) denotes the largest integer m such that the Galois group, n+1 G(Q(e2(cid:25)i=m)=Q), has exponent dividing n+ 1. Alternatively it is the order of H0(Spec(Z);Q=Z(n+1)) (see ([50] 7.2.4). e(cid:19)t x Conjecture 1.3 In the situation of 1.1 and Conjecture 1.2 one could also x conjecture the stronger result that, for each n 1, (cid:21) (cid:2) (n+1) ann (H0(Spec( );Q =Z (n+1))) L=Q (cid:1) Zl[G(L=Q)] (cid:19)et OL l l F (K ( ) Z ): (cid:18) Zl[G(L=Q)] 2n OL (cid:10) l Here F (M) denotes the Fitting ideal of the module M (see 2). Zl[G(L=Q)] x This conjecture is stronger than Conjecture 1.2 since the integer w (Q) n+1 has been removed and the Fitting ideal is contained in the annihilator ideal (see 2.3). x 2 Remark 1.4 (i) The classical theorem of Stickelberger ([58] p.94) corre- sponds to the case when n = 0 in Conjecture 1.2 when K ( ) is replaced 0 L O by its torsion subgroup, the ideal class group. The Brumer Conjecture ([4], [60]), which is still open, corresponds to the case when n = 0 and L=K is an abelian extension with K totally real. (ii) Furthermore, inspired by the Brumer Conjecture, a conjecture similar to Conjecture 1.3 makes sense for any abelian Galois extension of number (cid:12)elds, L=K, with L totally real (see [50] Conjecture 7.2.6). (iii) There is an equivariant Chern class homomorphism of the form (cf. [2] Theorem B; [14]) c : K ( ) Z H1(Spec( [1=l]);Q =Z (n+1)): n+1;2 2n OL (cid:10) l (cid:0)! (cid:19)et OL l l The Lichtenbaum-Quillen Conjecture predicts (at least when l is odd) that c is an isomorphism. This was proved for n = 1 in [55]. As a corollary of n+1;2 the fundamental results of Voevodsky [56] [57], when l = 2 this Chern class is nearly an isomorphism in all dimensions [43]. Voevodsky’s method requires the existence of suitable \norm varieties" which is not yet established for all odd primes. However, recent work by Rost combined with that of Suslin- Voevodsky shows that c is an isomorphism for l = 3. n+1;2 The annihilator ann (H0(Spec( );Q =Z (n+1))) Zl[G(L=Q)] (cid:19)et OL l l is well-known ([10] Lemma 2.3; [54] p.82). Explicitly, for n 0, this annihi- (cid:21) lator is equal to the ideal generated by the elements, (P;L=Q) NPn+1 (cid:0) 2 Z [G(L=Q)], where P runs through primes which ramify in L=Q or divide l w (L) = H0(Spec( );Q =Z (n+1)) : n+1 j (cid:19)et OL l l j Here (P;L=Q) G(L=Q) is the element corresponding to P under Artin 2 reciprocity. In[14]itisshownthat(theresultcanalsobededucedfrom[15])K ( ) 2n L O (cid:10) Z mapssurjectivelyontoH1(Spec( [1=l]);Q =Z (n+1))sothattheCoates- l (cid:19)et OL l l SinnottConjectureof 1.2,asmodi(cid:12)edinConjecture1.3,predictsaninclusion x of the form (cid:2) (n+1) ann (H0(Spec( );Q =Z (n+1))) L=Q (cid:1) Zl[G(L=Q)] (cid:19)et OL l l F (H1(Spec( [1=l]);Q =Z (n+1))): (cid:18) Zl[G(L=Q)] (cid:19)et OL l l (iv) The annihilator/Fittingidealrelationof(iii)makes sense moregener- ally. Let L=K be a Galois extension of totally real number (cid:12)elds with abelian Galois group, G(L=K). Let S be a (cid:12)nite set of primes of K including all 3 those which ramify in L=K. Then, as in 1.1, for each n 2 there exists a x (cid:21) unique unit of the rational group-ring (cid:2) (n) Q[G(L=K)](cid:3) L=K;S 2 such that (cid:31)((cid:2) (n)) = L (1 n;(cid:31)(cid:0)1) L=K;S K;S (cid:0) for each one-dimensional complex representation, (cid:31). Here (cid:31) is a character of G(L=K) and L (s;(cid:31)(cid:0)1) denotes the Artin L-function of (cid:31)(cid:0)1 with the Euler K;S factors associated to the primes in S removed. Let S0 be the set of places of L over S. Set Xl = Spec(OL;S0[1=l]), where OL;S0 is the ring of S0-integers of L. For each n 1, one would expect an (cid:21) annihilator relation of the form (cid:2) (n+1) ann (H0(Spec( );Q =Z (n+1))) L=K;S (cid:1) Zl[G(L=K)] (cid:19)et OL l l F (H1(X ;Q =Z (n+1)))(cid:1)Z [G(L=K)]: (cid:18) Zl[G(L=K)] e(cid:19)t l l l l In fact, it can be shown that these ideals have the same radical ([50] Theorem 7.3.2). (v) Using Iwasawa theory, it is shown in ([11] Theorem 2) that if L=Q is a totally real abelian extension of conductor f, l is a prime and b is an integer coprime to fl then w (Q)(b2 (b;L=Q))(cid:2) (2) Q [G(L=Q)] lies in 2 L=Q l (cid:0) 2 ann (H1(Spec( );Q =Z (2))) = ann (K ( ) Z ): Zl[G(L=K)] (cid:19)et OL l l Zl[G(L=K)] 2 OL (cid:10) l By combining ([11] Theorem 2.1) with results from [46], it is shown more generally in [39], under the same conditions (actually the condition that (b;fl) = 1 seems to have been omitted in ([39] Th(cid:19)eor(cid:18)eme 2.2)), that w (Q)(bj+1 (b;L=Q))(cid:2) (j +1) Q [G(L=Q)] lies in j+1 L=Q l (cid:0) 2 ann (H1(Spec( );Q =Z (j +1))) Zl[G(L=K)] (cid:19)et OL l l for j = 1;3;5:::. 1.5 Now let us describe the main results of this paper. Let l be an odd prime and let m be a positive integer prime to l. If (cid:24) denotes the root t of unity (cid:24) = e2(cid:25)i=t, consider the cyclotomic (cid:12)eld Q((cid:24) ) and its totally t mls+1 real sub(cid:12)eld Q((cid:24) )+. Let S denote the primes of Q((cid:24) )+ which mls+1 ml mls+1 divide ml and let X+ = Spec(Z[(cid:24) ]+ ) denote the spectrum of the S - l mls+1 Sml ml integers in Q((cid:24) )+. Note that H0(X+;Q =Z (1 r)) is isomorphic to mls+1 (cid:19)et l l l (cid:0) H0(Z[(cid:24) ][1=ml];Q =Z (1 r)) for all negative odd integers r. (cid:19)et mls+1 l l (cid:0) The following result will be proved in 4.3. x 4 Theorem 1.6 Let l be an odd prime. Let l;m and X+ be as in the notation of 1.5 and l x let (cid:2) (1 r) denote the higher Stickelberger element of 1.1. Then, Q((cid:24)mls+1)+=Q (cid:0) x for r = 1; 3; 5;::: and any positive integer s: (cid:0) (cid:0) (cid:0) (i) there exists a chain of annihilator ideal relations for (cid:19)etale cohomology of the form ftm0 j t 2 annZl[G(Q((cid:24)mls+1)+=Q)](H(cid:19)e1t(Xl+;Ql=Zl(1(cid:0)r)))g (cid:2) (1 r)ann (H0(X+;Q =Z (1 r))) (cid:18) Q((cid:24)mls+1)+=Q (cid:0) Zl[G(Q((cid:24)mls+1)+=Q)] (cid:19)et l l l (cid:0) ann (H1(X+;Q =Z (1 r))): (cid:18) Zl[G(Q((cid:24)mls+1)+=Q)] (cid:19)et l l l (cid:0) (ii) If l does not divide m 1 then in (i) the (cid:12)nal (cid:0) ann (H1(X+;Q =Z (1 r))) Zl[G(Q((cid:24)mls+1)+=Q)] (cid:19)et l l l (cid:0) may be replaced by F (H1(X+;Q =Z (1 r))): Zl[G(Q((cid:24)mls+1)+=Q)] (cid:19)et l l l (cid:0) Here m is the minimal number of generators of the Z [G(Q((cid:24) )+=Q)]- 0 l mls+1 module H1(X+;Q =Z (1 r)) and F (M) denotes the Fitting (cid:19)et l l l (cid:0) Zl[G(Q((cid:24)mls+1)+=Q)] ideal of M. From the localisation sequence of ([52] p.268), when r = 1; 3; 5;:::, (cid:0) (cid:0) (cid:0) H1(Spec(Z[(cid:24) ]+[1=l]);Q =Z (1 r))isaGaloissubmoduleofH1(X+;Q =Z (1 (cid:19)et mls+1 l l (cid:0) (cid:19)et l l l (cid:0) r)), which implies the following result. Corollary 1.7 In the notation of 1.5 and Theorem 1.6, when l is an odd prime not x dividing m and r = 1; 3; 5;::: (cid:0) (cid:0) (cid:0) (cid:2) (1 r)ann (H0(Spec(Z[(cid:24) ]+[1=l]);Q =Z (1 r))) Q((cid:24)mls+1)+=Q (cid:0) Zl[G(Q((cid:24)mls+1)+=Q)] (cid:19)et mls+1 l l (cid:0) ann (H1(Spec(Z[(cid:24) ]+[1=l];Q =Z (1 r))) (cid:18) Zl[G(Q((cid:24)mls+1)+=Q)] (cid:19)et mls+1 l l (cid:0) for all positive integers s. The paper is organised in the following manner. In 2 we introduce the x relative K-group K (Z [G];Q ) for any (cid:12)nite group G and explain how ele- 0 l l ments of this group can yield annihilator/Fitting ideal relations (Theorem 2.4). Two important classes of elements to which the construction of 2 ap- x pliesariseinconnectionwiththe(cid:19)etalecohomologygroupsofcurves over(cid:12)nite (cid:12)elds and rings of integers in number (cid:12)elds. In 3 we apply Theorem 2.4 to x 5 an example from ([8] 7) to prove a Coates-Sinnott type of result (Theorem x 3.4) for the (cid:19)etale cohomology groups of curves over (cid:12)nite (cid:12)elds. In 4 we use x an example from [5] to prove a similar result (Theorem 1.6 proved in 4.3) for x the (cid:19)etale cohomology H1(X+;Q =Z (1 r)) of the S-integers in the totally (cid:19)et l l l (cid:0) real sub(cid:12)eld of a cyclotomic (cid:12)eld. When r = 2; 4; 6;::: { the case not (cid:0) (cid:0) (cid:0) covered by Theorem 1.6 { we apply Theorem 2.4 in Theorem 4.6 to study the annihilator ideal of H2(X+;Z (1 r)). In 4.8 and Theorem 4.9 we use (cid:19)et l l (cid:0) x Theorem 4.6 together with calculation of Beilinson [3] to construct elements of this annihilator from the leading terms of the Dirichlet L-function at s = r. In 5 we discuss invariants lying in K (Z [G];Q ) which are constructed from 0 l l x relatively abelian extensions of totally real number (cid:12)elds with vanishing Iwa- sawa (cid:22)-invariants, from the Galois action on vanishing cycles and from (cid:19)etale coverings of curves and surfaces. Finally, a remark about the classical Stickelberger Theorem and Brumer Conjecture which, as mentioned in Remark 1.4, correspond to the case when r = 0. In ([50] Remark 7.2.11(ii)) it is explained how one might use \Tate sequence" constructed in [41] to approach the Brumer Conjecture by the method used to prove Theorem 1.6. This approach is much more di(cid:14)cult thantheproofofTheorem1.6becauseofthepresenceofnon-trivialregulators (cf. [50] 7.1.12). On the other hand, this approach would aim to prove a x statement(analogoustothatofTheorem1.6)statingthatatoddprimesl,the Stickelberger ideal lies in the annihilator (and sometimes the Fitting ) ideal of the class-group of the S-integers (where S-contains all rami(cid:12)ed primes). Even in the case of the classical Stickelberger Theorem this seems to lead to questions which are at present unanswered. In the classical Stickelberger case such a Fitting ideal inclusion fails for l = 2 but holds at odd primes when, for example, both the roots of unity and the class-group are cohomologically trivial. Very recently I became aware of the very important results of Masato Kurihara [27] which show that the Fitting ideal appearing in Theorem 1.6(ii) is given by a generalised Stickelberger ideal. Using Kurihara’s results one may verify the second inclusion in the statements of Theorems 1.6(ii) without any restrictions on the integer m while the other inclusion may in turn be combined with the results of [27] to yield upper bounds on the number of Z [G]-module generators of the (cid:19)etale cohomology groups. l Ackowledgments The results of [5] are crucial to this paper and I am particularly indebted to David Burns for bringing his work to my attention. ThisworkwasbegunduringavisittotheUniversity ofPennsylvaniainMarch 2000 and completed during a visit, funded by a Special Project Grant from the Royal Society, to the Euler Institute in St Petersburg during September 2000. I am particularly grateful to these institutions for their hospitality and to mathematicians there { Ted Chinburg, Ivan Panin and Igor Zhukov 6 { for help and encouragement. In addition, conversations with John Coates, Cornelius Greither, Bernhard Ko(cid:127)ck, Masato Kurihara, Christian Popescu, Nguyen Thong Quang Do, Ju(cid:127)rgen Ritter, Al Weiss and Andrew Wiles have been very helpful. In fact, [11] was one of the papers which (cid:12)rst got me interested in algebraic K-theory a long time ago. 2 K (Z [G];Q ) and annihilator/Fitting ideal 0 l l relations 2.1 Let l be a prime, G a (cid:12)nite group and let f : Z [G] Q [G] denote the l l (cid:0)! homomorphism of group-rings induced by the inclusion of the l-adic integers intothefraction(cid:12)eld, thel-adicrationals. WriteK (Z [G];Q )fortherelative 0 l l K-group of f, denoted by K (Z [G];f) in ([53] p.214; see also [50] De(cid:12)nition 0 l 2.1.5). By ([53] Lemma 15.6) elements of K (Z [G];Q ) are represented by 0 l l triples [A;g;B] where A;B are (cid:12)nitely generated, projective Z [G]-modules l and g is a Q [G]-module isomorphism of the form g : A Q (cid:24)= B Q . l (cid:10)Zl l ! (cid:10)Zl l De(cid:12)ning an exact sequence of triples in the obvious manner, the relations between these elements are generated by the following two types: (i) [A;g;B] = [A0;g0;B0]+[A00;g00;B00] if there exists an exact sequence 0 (A0;g0;B0) (A;g;B) (A00;g00;B00) 0 (cid:0)! (cid:0)! (cid:0)! (cid:0)! and (ii) [A;gh;C] = [A;h;B]+[B;g;C]. This group (cid:12)ts into a localisation sequence of the form ([44] 5 Theorem x 5; [20] p.233) f(cid:3) @ (cid:25) f(cid:3) K (Z [G]) K (Q [G]) K (Z [G];Q ) K (Z [G]) K (Q [G]): 1 l 1 l 0 l l 0 l 0 l (cid:0)! (cid:0)! (cid:0)! (cid:0)! Assume now that G is abelian. In this case K (Q [G]) = Q [G](cid:3) because 1 l (cid:24) l Q [G] is a product of (cid:12)elds and K (Z [G]) = Z [G](cid:3) ([13]I p.179 Theorem l 1 l (cid:24) l (46.24)). Under these isomorphisms f is identi(cid:12)ed with the canonical inclu- (cid:3) sion. The homomorphism, K (Z [G]) f(cid:3) K (Q [G]), is injective for all (cid:12)nite 0 l 0 l (cid:0)! groups G ([47] Theorem 34 p.131; [13]II p.47 Theorem 39.10). Alternatively, whenGisabelian, Z [G]issemi-localandtheinjectivity off followsfromthe l (cid:3) fact that a (cid:12)nitely generated projective module over a local ring is free ([16] p.124 Corollary 4.8 and p.205 Exercise 7.2). Thus the localisation sequence yields an isomorphism of the form Q [G](cid:3) l K (Z [G];Q ) = 0 l l (cid:24) Z [G](cid:3) l 7 when G is abelian. From the explicit description of @ ([53] p.216) this iso- morphism sends the coset of (cid:11) Q [G](cid:3) to [Z [G];((cid:11) );Z [G]]. The inverse l l l 2 (cid:1)(cid:0) isomorphism sends [A;g;B], where A and B may be assumed to be free Z [G]-modules, to the coset of det(g) Q [G](cid:3) with respect to any choice of l l 2 Z [G]-bases for A and B. l Example 2.2 We shall be particularly interested in the following source of elements of K (Z [G];Q ). 0 l l As in 2.1, let l be a prime and let G be a (cid:12)nite abelian group. Suppose x that 0 F dk F dk(cid:0)1 ::: d2 F d1 F 0 k k(cid:0)1 1 0 (cid:0)! (cid:0)! (cid:0)! (cid:0)! (cid:0)! (cid:0)! is a bounded complex of (cid:12)nitely generated, projective Z [G]-modules (i.e. a l perfect complex of Z [G]-modules), having all its homology groups (cid:12)nite. l As usual, let Z = Ker(d : F F ) and B = d (F ) F denote t t t t(cid:0)1 t t+1 t+1 t (cid:0)! (cid:18) the Z [G]-modules of t-dimensional cycles and boundaries, respectively. We l have short exact sequences of the form 0 B (cid:30)i Z H (F ) 0 i i i (cid:3) (cid:0)! (cid:0)! (cid:0)! (cid:0)! and 0 Z i+1 F di+1 B 0: i+1 i+1 i (cid:0)! (cid:0)! (cid:0)! (cid:0)! Applying ( Q ) we obtain isomorphisms l (cid:0)(cid:10) (cid:30) : B Q (cid:24)= Z Q i i l i l (cid:10) (cid:0)! (cid:10) and we may choose Q [G]-module splittings of the form l (cid:17) : B Q F Q i i l i+1 l (cid:10) (cid:0)! (cid:10) such that (d 1)(cid:17) = 1 : B Q B Q . i+1 i i l i l (cid:10) (cid:10) (cid:0)! (cid:10) Then we form a Q [G]-module isomorphism of the form l X : F Q (cid:24)= F Q j 2j l j 2j+1 l (cid:8) (cid:10) (cid:0)! (cid:8) (cid:10) given by the composition F Q (cid:8)j ( 2j+(cid:17)2j(cid:0)1)(cid:0)1 (Z Q ) (B Q ) j 2j l j 2j l 2j(cid:0)1 l (cid:8) (cid:10) (cid:0)! (cid:8) (cid:10) (cid:8) (cid:10) (cid:8)j ((cid:30)(cid:0)2j1(cid:8)(cid:30)2j(cid:0)1) (B Q ) (Z Q ) j 2j l 2j(cid:0)1 l (cid:0)! (cid:8) (cid:10) (cid:8) (cid:10) ((cid:8)j (cid:17)2j+ 2j(cid:0)1) F Q : j 2j(cid:0)1 l (cid:0)! (cid:8) (cid:10) 8 This construction de(cid:12)nes a class, [ F ;X; F ], in K (Z [G];Q ) which j 2j j 2j+1 0 l l (cid:8) (cid:8) is well-known to be independent of the choices of the splittings used to de(cid:12)ne X ([53] Ch. 15; see also [50] Propositions 2.5.35 and 7.1.8). We shall denote by Q [G](cid:3) l det(X) 2 Z [G](cid:3) l the element which corresponds to [ F ;X; F ] K (Z [G];Q ) under j 2j j 2j+1 0 l l (cid:8) (cid:8) 2 the isomorphism of 2.1. x 2.3 Recall that, if R is aring and M a (left)R-module, the (left) annihilator ideal ann (M)(cid:1)R of M is de(cid:12)ned to be R ann (M) = r R r m = 0 for all m M : R f 2 j (cid:1) 2 g Let us recall from ([35] Appendix; see also [59]) the properties of the Fitting ideal (referred to as the initial Fitting invariant in [40]). Let R be a commutative ring with identity and let M be a (cid:12)nitely pre- sented R-module, in our applications M will actually be (cid:12)nite. Suppose that M has a presentation of the form Ra f Rb M 0 (cid:0)! (cid:0)! (cid:0)! with a b then the Fitting ideal of the R-module M, denoted by F (M), is R (cid:21) the ideal of R generated by all b b minors of any matrix representing f. (cid:2) The Fitting ideal F (M) is independent of the presentation chosen for M R and is contained in the annihilator ideal of M, F (M) ann (M). If M is R R (cid:18) generated by n elements then ann (M)n F (M) and if (cid:25) : M M0 is a R R (cid:18) ! surjection of (cid:12)nitely presented R-modules then F (M) F (M0). R R (cid:18) The following result yields relations between the annihilator ideals and Fitting ideals of the homology modules in Example 2.2 in the special case when each H (F ) is (cid:12)nite and zero except for i = 0;1. i (cid:3) Theorem 2.4 Let G be a (cid:12)nite abelian group and l a prime. Suppose that 0 F dk F dk(cid:0)1 ::: d2 F d1 F 0 k k(cid:0)1 1 0 (cid:0)! (cid:0)! (cid:0)! (cid:0)! (cid:0)! (cid:0)! is a bounded, perfect complex of Z [G]-modules, as in Example 2.2, having l H (F ) (cid:12)nite for i = 0;1 and zero otherwise. Let i (cid:3) Q [G](cid:3) l [ F ;X; F ] K (Z [G];Q ) = (cid:8)j 2j (cid:8)j 2j+1 2 0 l l (cid:24) Z [G](cid:3) l be as in Example 2.2. Then: 9 (i) if t ann (H (F )), i 2 Zl[G] i (cid:3) det(X)((cid:0)1)itmi ann (H (F ))(cid:1)Z [G] i 2 Zl[G] 1(cid:0)i (cid:3) l for i = 0;1. Here m ;m is the minimal number of generators required for 0 1 the Z [G]-module H (F );Hom(H (F );Q =Z ), respectively, l 0 (cid:3) 1 (cid:3) l l (ii) if the Sylow l-subgroup of G is cyclic then in (i) ann (H (F )) Zl[G] 1(cid:0)i (cid:3) may be replaced by F (H (F )). Zl[G] 1(cid:0)i (cid:3) 2.5 The proof of Theorem 2.4 will occupy the remainder of this section, culminating in 2.11. We begin with some preliminary observations and con- x structions. In the situation of Theorem 2.4, without changing the class [ F ;X; F ], we may replace F ;:::;F by (cid:12)nitely generated, free j 2j j 2j+1 0 k(cid:0)1 (cid:8) (cid:8) Z [G]-modules. Then, since ( 1)i[F ] = f ((cid:25)([ F ;X; F ])) = 0 l Pi (cid:0) i (cid:3) (cid:8)j 2j (cid:8)j 2j+1 and f is injective, F must be stably free and hence free. Therefore hence- (cid:3) k forth we shall assume that each F is a (cid:12)nitely generated, free Z [G]-module. i l In this case we are going to modify the isomorphism X to make it Z -integral. l Firstly we observe that, for i 1, the short exact sequence of Z [G]- l (cid:21) module homomorphisms 0 B i+1 F di+1 B 0 i+1 i+1 i (cid:0)! (cid:0)! (cid:0)! (cid:0)! splits. To see this, write G = H G where G is the Sylow l-subgroup of G 1 1 (cid:2) and observe, by induction starting with B = F , that B is a torsion-free, k(cid:0)1 (cid:24) k i cohomologically trivial Z [G ]-module if i 1. Hence, by ([1] Theorem 7) l 1 (cid:21) there exist elements v ;:::;v B such that the natural map induces an 1 t i 2 isomorphism of the form Z=lm[G ] < v ;:::;v > (cid:24)= B =lmB 1 1 t i i (cid:0)! for each m 1. Since B is l-adically complete, the inverse limit of these i (cid:21) isomorphisms shows that B is a free Z [G ]-module. Hence we may split d i l 1 i+1 as a Z [G ]-module homomorphism and, by averaging over H, as a Z [G]- l 1 l module homomorphism also. Therefore we have (cid:17) : B F i i i+1 (cid:0)! for i 1 and (cid:21) = (cid:30) : B Z i i i (cid:0)! for i 2 without tensoring with the l-adic rationals. (cid:21) Since H (F ) is (cid:12)nite, in the notation of Example 2.2, we have a homo- 0 (cid:3) morphism (cid:17) = (cid:17) ((cid:30) 1)(cid:0)1 : F Q F Q 0 0 0 l 1 l (cid:1) (cid:10) (cid:10) (cid:0)! (cid:10) 10

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nihilator/Fitting ideal relation is closely connected to Stickelberger's. Theorem and often the answer to this question is affirmative for trivial reasons.
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