On the $p$-adic Beilinson conjecture and the equivariant Tamagawa number conjecture
Andreas Nickel

TL;DR
This paper explores the connections between the $p$-adic Beilinson conjecture, the equivariant Iwasawa main conjecture, and the equivariant Tamagawa number conjecture, establishing implications for Galois extensions of totally real fields.
Contribution
It demonstrates that these conjectures imply the $p$-part of the equivariant Tamagawa number conjecture for certain Galois extensions, extending results to CM-extensions for even $r$.
Findings
Implication of the $p$-adic Beilinson conjecture on Tamagawa number conjecture.
Reduction of conjectures to the $p$-part for Galois extensions.
Extension of results to CM-extensions with even $r$.
Abstract
Let be a finite Galois extension of totally real number fields with Galois group . Let be an odd prime and let be an odd integer. The -adic Beilinson conjecture relates the values at of -adic Artin -functions attached to the irreducible characters of to those of corresponding complex Artin -functions. We show that this conjecture, the equivariant Iwasawa main conjecture and a conjecture of Schneider imply the `-part' of the equivariant Tamagawa number conjecture for the pair . If is even we obtain a similar result for Galois CM-extensions after restriction to `minus parts'.
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On the -adic Beilinson conjecture
and the equivariant Tamagawa number conjecture
Andreas Nickel
Universität Duisburg-Essen
Fakultät für Mathematik
Thea-Leymann-Straße 9
D-45127 Essen
Germany
[email protected] https://www.uni-due.de/$\sim$hm0251/index.html
(Date: Version of 2nd October 2021)
Abstract.
Let be a finite Galois extension of totally real number fields with Galois group . Let be an odd prime and let be an odd integer. The -adic Beilinson conjecture relates the values at of -adic Artin -functions attached to the irreducible characters of to those of corresponding complex Artin -functions. We show that this conjecture, the equivariant Iwasawa main conjecture and a conjecture of Schneider imply the ‘-part’ of the equivariant Tamagawa number conjecture for the pair . If is even we obtain a similar result for Galois CM-extensions after restriction to ‘minus parts’.
Key words and phrases:
Beilinson conjecture; equivariant Tamagawa number conjecture; Iwasawa theory; regulator maps
2010 Mathematics Subject Classification:
19F27, 11R23, 11R42, 11R70
1. Introduction
Let be a finite Galois extension of number fields with Galois group and let be an integer. The equivariant Tamagawa number conjecture (ETNC) for the pair as formulated by Burns and Flach [BF01] asserts that a certain canonical element in the relative algebraic -group vanishes. This element relates the leading terms at of Artin -functions to natural arithmetic invariants.
If this might be seen as a vast generalization of the analytic class number formula for number fields, and refines Stark’s conjecture for as discussed by Tate in [Tat84] and the ‘Strong Stark conjecture’ of Chinburg [Chi83, Conjecture 2.2]. It is known to imply a whole bunch of conjectures such as Chinburg’s ‘-conjecture’ [Chi83, Chi85], the Rubin–Stark conjecture [Rub96], Brumer’s conjecture, the Brumer–Stark conjecture (see [Tat84, Chapitre IV, §6]) and generalizations thereof due to Burns [Bur11] and the author [Nic11b]. If is a negative integer, the ETNC refines a conjecture of Gross [Gro05] and implies (generalizations of) the Coates–Sinnott conjecture [CS74] and a conjecture of Snaith [Sna06] on annihilators of the higher -theory of rings of integers (see [Nic11a]). If the ETNC likewise predicts constraints on the Galois module structure of -adic wild kernels [Nic19].
The functional equation of Artin -functions suggests that the ETNC at and are equivalent. This is not known in general, but leads to a further conjecture which is sometimes referred to as the local ETNC. Except for the validity of the local ETNC it therefore suffices to consider the (global) ETNC for either odd or even integers . Note that the local ETNC is widely believed to be easier to settle. For instance, the ‘global epsilon constant conjecture’ of Bley and Burns [BB03] measures the compatibility of the closely related ‘leading term conjectures’ at [Bur01] and [BB07] and is known to hold for arbitrary tamely ramified extensions [BB03, Corollary 7.7] and also for certain weakly ramified extensions [BC16].
Now suppose that is a Galois extension of totally real number fields and let be an odd prime. If is odd Burns [Bur15] and the author [Nic13] independently have shown that the ‘-part’ of the ETNC for the pair holds provided that a certain Iwasawa -invariant vanishes (which conjecturally is always true). The latter condition is mainly present because the equivariant Iwasawa main conjecture (EIMC) for totally real fields then holds by independent work of Ritter and Weiss [RW11] and of Kakde [Kak13].
The case is more subtle. Burns and Venjakob [BV06, BV11] (see also [Bur15, Corollary 2.8]) proposed a strategy for proving the -part of the ETNC for the pair . More precisely, this special case of the ETNC is implied by the vanishing of the relevant -invariant, Leopoldt’s conjecture for at and the ‘-adic Stark conjecture at ’. The latter conjecture relates the leading terms at of the complex and -adic Artin -functions attached to characters of by certain comparison periods. Note that Burns and Venjakob actually assume these conjectures for all odd primes and then deduce the ETNC for the pair , but their approach has recently been refined by Johnston and the author [JN20a] so that one can indeed work prime-by-prime.
There are similar results on minus parts if is a Galois CM-extension with Galois group , i.e. is totally real and is a totally complex quadratic extension of a totally real field . Namely, if is even and vanishes, then the minus -part of the ETNC for the pair holds [Bur15, Nic13]. Burns [Bur20] recently proposed a strategy for proving the minus -part of the ETNC in the case . In comparison with the strategy in the case , Leopoldt’s conjecture is replaced with the conjectural non-vanishing of Gross’s regulator [Gro81], and the -adic Stark conjecture is replaced with the ‘weak -adic Gross–Stark conjecture’ [Gro81, Conjecture 2.12b] (now a theorem for linear characters by work of Dasgupta, Kakde and Ventullo [DKV18]). For an approach that only relies upon the validity of the EIMC we refer the reader to [Nic11c, Nic16].
The aim of this article is to propose a similar strategy in the remaining cases, i.e. we will consider the ETNC for Tate motives where and is a CM-field. Note that we can treat all integers simultaneously as the ‘plus -part’ of the ETNC for the pair naturally identifies with the corresponding conjecture for the extension of totally real fields. We show that the -adic Beilinson conjecture at , a conjecture of Schneider [Sch79] and the EIMC imply the plus (resp. minus) -part of the ETNC for the pair if is odd (resp. even).
We follow the formulation of the -adic Beilinson conjecture in [BBdJR09]. It relates the values at of the complex and -adic Artin -functions by certain comparison periods involving Besser’s syntomic regulator [Bes00]. For absolutely abelian extensions variants of the -adic Beilinson conjecture have been formulated and proved by Coleman [Col82], Gros [Gro90, Gro94] and Kolster and Nguyen Quang Do [KNQD98]. Thus the -adic Beilinson conjecture holds for absolutely abelian characters (see §3.13 for a precise statement).
Let us compare our approach to the earlier work mentioned above. The formulation of both the -adic Beilinson conjecture and the -adic Stark conjecture involves the choice of a field isomorphism . We show in §3.12 that the -adic Beilinson conjecture does not depend upon this choice if and only if a conjecture of Gross [Gro05] holds. The latter is revisited in §3.8 and might be seen as a higher analogue of Stark’s conjecture; a similar result in the case has recently been established by Johnston and the author in [JN20a]. In both cases the independence of is therefore equivalent to the rationality part of the appropriate special case of the ETNC. This eventually allows us to establish a prime-by-prime descent result analogous to [JN20a, Theorem 8.1].
In a little more detail, we formulate conjectural ‘higher refined -adic class number formulae’ analogous to [Bur20, Conjecture 3.5] (where ), and show that these follow from the EIMC and Schneider’s conjecture in §4.6. Here, as will be shown in §4.5, the latter conjecture ensures that the relevant complexes are semisimple at all Artin characters as Leopoldt’s conjecture does in the case and the non-vanishing of Gross’s regulator does in the case . This is a necessary condition in order to apply the descent formalism of Burns and Venjakob [BV11]. A second condition is the vanishing of the aforementioned Iwasawa -invariant, but given recent progress of Johnston and the author [JN18, JN20b] on the EIMC without assuming , we wish to circumvent this hypothesis. For this purpose, we develop a different descent argument that makes no use of this assumption, but requires a more delicate analysis of the relevant complexes. The higher refined -adic class number formula at may then be combined with the -adic Beilinson conjecture at to deduce the plus, respectively minus, -part of the ETNC for the pair in §4.7. For this, it is crucial to relate Besser’s syntomic regulators to Soulé’s -adic Chern class maps [Sou79] and the Bloch–Kato exponential maps [BK90] that appear in the formulation of the ETNC. This is carried out in §3.9 (in particular see Proposition 3.16). The formulation of the ETNC that is most suitable for our purposes is a reformulation due to the author [Nic19]. This has primarily been introduced in order to construct (conjectural) annihilators of -adic wild kernels.
Our prime example are totally real Galois extensions with Galois group isomorphic to , where is a prime power and denotes the group of affine transformations on the finite field with elements. We show that Gross’s conjecture holds in this case (Theorem 3.14 (iv)). Moreover, the relevant cases of the EIMC hold unconditionally by recent work of Johnston and the author [JN18] (see also [JN20b]) and the -adic Beilinson conjecture reduces to the case of the trivial extension where denotes the subgroup of . See Example 4.24 for more details.
Finally, we note that the ETNC for the pair has been verified for any integer whenever is abelian over the rationals by work of Burns, Greither and Flach [BG03, Fla11, BF06]. However, if and is not absolutely abelian, then we are not aware of any previous (conditional) results that establish the (-part of the) ETNC for the pair .
Acknowledgements
The author acknowledges financial support provided by the Deutsche Forschungsgemeinschaft (DFG) within the Heisenberg programme (project number 334383116).
Notation and conventions
All rings are assumed to have an identity element and all modules are assumed to be left modules unless otherwise stated. Unadorned tensor products will always denote tensor products over . For a ring we write for its center and for the group of units in . For every field we fix a separable closure of and write for its absolute Galois group. If is an integer coprime to the characteristic of , we let denote a primitive -th root of unity in .
A finite Galois extension of totally real number fields will usually be denoted by , whereas denotes an arbitrary Galois extension of number fields. Galois CM-extensions will usually be denoted by as well.
2. Algebraic Preliminaries
2.1. Derived categories and Galois cohomology
Let be a noetherian ring and let be the category of all finitely generated projective -modules. We write for the derived category of -modules and for the category of bounded complexes of finitely generated projective -modules. Recall that a complex of -modules is called perfect if it is isomorphic in to an element of . We denote the full triangulated subcategory of comprising perfect complexes by .
If is a -module and is an integer, we write for the complex
[TABLE]
where is placed in degree . Note that this is compatible with the usual shift operator on cochain complexes.
Let be an algebraic extension of the number field . For a finite set of places of containing the set of all archimedean places we let be the Galois group over of the maximal extension of that is unramified outside ; here we write for the set of places of lying above those in . We let be the ring of -integers in . For any topological -module we write for the complex of continuous cochains of with coefficients in . If is a field and is a topological -module, we likewise define to be the complex of continuous cochains of with coefficients in .
If is a global or a local field of characteristic zero, and is a discrete or a compact -module, then for we denote the -th Tate twist of by . Now fix a prime and suppose that also contains all -adic places of . Then for each integer the cohomology group in degree of naturally identifies with , the -th étale cohomology group of the affine scheme with coefficients in the étale -adic sheaf . We set .
2.2. Representations and characters of finite groups
Let be a finite group and let be a field of characteristic zero. We write for the set of characters attached to finite-dimensional -valued representations of , and for the ring of virtual characters generated by . Moreover, we denote the subset of irreducible characters in and the ring of -valued virtual characters of by and , respectively.
For a subgroup of and we write for the induced character; for a normal subgroup of and we write for the inflated character. For and we set and note that this defines a group action from the left even though we write exponents on the right of . We denote the trivial character of by .
2.3. -twists
Let be a finite group and let be a field of characteristic zero. If is a -module we let be the maximal submodule of upon which acts trivially. Likewise we write for the maximal quotient module with trivial -action. For any we fix a (left) -module with character . For any -module and any we write for the -vector space
[TABLE]
and for the induced map . We note that is independent of the choice of . The following is [JN20a, Lemma 2.1] and very similar to [Tat84, Chapitre I, 6.4].
Lemma 2.1**.**
Let be an -module and let . Let be a subgroup of and let denote considered as an -module. Let be a normal subgroup of and view as an -module in the obvious way.
- (i)
If then . 2. (ii)
If then and . 3. (iii)
If then and .
Let be a prime. For each we fix a subfield of which is both Galois and of finite degree over and such that can be realized over . We write for the associated primitive central idempotent in and choose an indecomposable idempotent of . Let be the ring of integers in and choose a maximal -order in containing . Then is an -free right -module.
For any (left) -module we define a (left) -module , where acts upon by the rule for all and . We define -modules and . We thereby obtain left, respectively right exact functors and from the category of -modules to the category of -modules. Note that there is an isomorphism for every finitely generated -module .
Since multiplication by the trace gives rise to an isomorphism for each projective -module (in fact for each cohomologically trivial -module ), these functors extend to naturally isomorphic exact functors (and ).
Lemma 2.2**.**
Let and let be integers. If is acyclic outside , then is also acyclic outside and there are natural isomorphisms of -modules
[TABLE]
For we have isomorphisms for every .
Proof.
Since (finitely generated) -modules are cohomologically trivial, the functors and are naturally isomorphic exact functors on the category of finitely generated -modules. The final assertion of the lemma is therefore clear.
Now suppose that is acyclic outside . If the claim is [Bur20, Lemma 5.1]. We repeat the short argument for convenience. Choose a complex of cohomologically trivial -modules that is isomorphic to in . Here and are placed in degrees and , respectively. Then we obtain a commutative diagram of -modules
[TABLE]
which implies the claim. If we choose a complex that is isomorphic to in and consider the exact sequence of perfect complexes
[TABLE]
where and denote naive truncation. Note that the complexes and are acyclic outside and , respectively. It follows by induction that is acyclic outside and, since , that we have an isomorphism . If then we likewise have that and we may again conclude by induction that we have an isomorphism . If we may alternatively consider the exact sequence of perfect complexes
[TABLE]
and deduce as above. ∎
3. The -adic Beilinson conjecture
3.1. Setup and notation
Let be a finite Galois extension of number fields with Galois group . For any place of we choose a place of above and write and for the decomposition group and inertia subgroup of at , respectively. We denote the completions of and at and by and , respectively, and identify the Galois group of the extension with . For each non-archimedean place we let be the ring of integers in . We identify with the Galois group of the corresponding residue field extension which we denote by . Finally, we let be the Frobenius automorphism, and we denote the cardinality of by . We let be a finite set of places of containing the set of archimedean places. If a prime is fixed, we will usually assume that the set of all -adic places is also contained in .
By a Galois CM-extension of number fields we shall mean a finite Galois extension such that is totally real and is a CM-field. Thus complex conjugation induces a unique automorphism in the center of and we denote the maximal totally real subfield of by . Then is also Galois with group .
3.2. Higher -theory
For an integer and a ring we write for the Quillen -theory of . In the cases and the groups and are equipped with a natural -action and for every integer the inclusion induces an isomorphism of -modules
[TABLE]
Moreover, if is a second finite set of places of containing , then for every there is a natural exact sequence of -modules
[TABLE]
Both results (3.1) and (3.2) are due to Soulé [Sou79]; see [Wei13, Chapter V, Theorem 6.8]. We also note that sequence (3.2) remains left-exact in the case . The structure of the finite -modules has been determined by Quillen [Qui72] (see also [Wei13, Chapter IV, Theorem 1.12 and Corollary 1.13]) to be
[TABLE]
3.3. The regulators of Borel and Beilinson
Let be the set of embeddings of into the complex numbers; we then have , where and are the number of real embeddings and the number of pairs of complex embeddings of , respectively. For an integer we define a finitely generated -module
[TABLE]
which is endowed with a natural -action, diagonally on and on . The invariants of under this action will be denoted by , and it is easily seen that we have
[TABLE]
The action of on endows with a natural -module structure.
Let be an integer. Borel [Bor74] has shown that the even -groups (and thus for any as above by (3.2) and (3.3)) are finite, and that the odd -groups are finitely generated abelian groups of rank . More precisely, for each Borel constructed an equivariant regulator map
[TABLE]
with finite kernel. Its image is a full lattice in . The covolume of this lattice is called the Borel regulator and will be denoted by . Moreover, Borel showed that
[TABLE]
where denotes the leading term at of the Dedekind zeta function attached to the number field .
In the context of the ETNC, however, it is more natural to work with Beilinson’s regulator map [Beĭ84]. By a result of Burgos Gil [BG02] Borel’s regulator map is twice the regulator map of Beilinson. Hence we will work with in the following.
Remark 3.1*.*
We will sometimes refer to [Nic19] where we have worked with Borel’s regulator map. However, if we are interested in rationality questions or in verifying the -part of the ETNC for an odd prime , the factor essentially plays no role. In contrast, the -adic Beilinson conjecture below predicts an equality of two numbers in so that this factor indeed matters.
3.4. The Quillen–Lichtenbaum Conjecture
Fix an odd prime and assume that contains and the set of all -adic places of . Then for any integer and Soulé [Sou79] has constructed canonical -equivariant -adic Chern class maps
[TABLE]
We need the following deep result.
Theorem 3.2** (Quillen–Lichtenbaum Conjecture).**
Let be an odd prime. Then for every integer and the -adic Chern class maps are isomorphisms.
Proof.
Soulé [Sou79] proved surjectivity. Building on work of Rost and Voevodsky, Weibel [Wei09] completed the proof of the Quillen–Lichtenbaum Conjecture. ∎
Let be a prime. For an integer and a ring we write for the -theory of with coefficients in . The following result is due to Hesselholt and Madsen [HM03].
Theorem 3.3**.**
Let be an odd prime and let be a finite place of . Then for every integer and there are canonical isomorphisms of -modules
[TABLE]
3.5. Local Galois cohomology
We keep the notation of §3.1. In particular, is a Galois extension of number fields with Galois group . Let be an odd prime. We denote the (finite) set of places of that ramify in by and let be a finite set of places of containing and all archimedean and -adic places (i.e. ).
Let be a topological -module. Then becomes a topological -module for every by restriction. For any we put
[TABLE]
For any integers and we define to be .
Lemma 3.4**.**
Let be an integer. Then we have isomorphisms of -modules
[TABLE]
Proof.
This is [Nic19, Lemma 3.3] (see also [Bar09, Lemma 5.2.4]). The case will be crucial in the following so that we briefly recall its proof. Let and put , where denotes Fontaine’s de Rham period ring. Then the Bloch–Kato exponential map
[TABLE]
is an isomorphism for every as follows from [BK90, Corollary 3.8.4 and Example 3.9]. Since the groups are finite for , we obtain isomorphisms of -modules
[TABLE]
∎
3.6. Schneider’s conjecture
Let be a topological -module. For any integer we denote the kernel of the natural localization map
[TABLE]
by . We call the Tate–Shafarevich group of in degree . We recall the following conjecture of Schneider [Sch79, p. 192].
Conjecture 3.5** ().**
Let be an integer. Then the Tate–Shafarevich group vanishes.
Remark 3.6*.*
It is not hard to show that Conjecture 3.5 does not depend on the choice of the set .
Remark 3.7*.*
Schneider originally conjectured that vanishes. Both conjectures are in fact equivalent (see [Nic19, Proposition 3.8 (ii)]).
Remark 3.8*.*
It can be shown that Schneider’s conjecture for is equivalent to Leopoldt’s conjecture (see [NSW08, Chapter X, §3]).
Remark 3.9*.*
For a given number field and a fixed prime , Schneider’s conjecture holds for almost all . This follows from [Sch79, §5, Corollar 4] and [Sch79, §6, Satz 3].
Remark 3.10*.*
Schneider’s conjecture holds whenever by work of Soulé [Sou79]; see also [NSW08, Theorem 10.3.27].
Lemma 3.11**.**
Let be an integer and let be an odd prime. Then the Tate–Shafarevich group is torsion-free. In particular, Schneider’s conjecture holds if and only if vanishes.
Proof.
The first claim is [Nic19, Proposition 3.8 (i)]. The second claim is immediate. ∎
3.7. Artin -series
Let be a finite Galois extension of number fields with Galois group and let be a finite set of places of containing all archimedean places. For any irreducible complex-valued character of we denote the -truncated Artin -series by , and the leading coefficient of at an integer by . We shall sometimes use this notion even if (which will happen frequently in the following).
Recall that there is a canonical isomorphism . We define the equivariant -truncated Artin -series to be the meromorphic -valued function
[TABLE]
For any we also put
[TABLE]
3.8. A conjecture of Gross
Let be an integer. Since Borel’s regulator map (3.5) induces an isomorphism of -modules, the Noether–Deuring Theorem (see [NSW08, Lemma 8.7.1] for instance) implies the existence of -isomorphisms
[TABLE]
Let be a complex character of and let be a -module with character . Composition with induces an automorphism of . Let be its determinant. If is a second character, then by Lemma 2.1 so that we obtain a map
[TABLE]
where denotes the ring of virtual complex characters of . We likewise define
[TABLE]
Gross [Gro05, Conjecture 3.11] conjectured the following higher analogue of Stark’s conjecture.
Conjecture 3.12** (Gross).**
We have for all .
Remark 3.13*.*
It is not hard to see that Gross’s conjecture does not depend on and the choice of (see also [Nic11a, Remark 6]). A straightforward substitution shows that if it is true for then it is true for for every choice of .
We record some cases where Gross’s conjecture is known and deduce a few new cases. If is a prime power, we let be the group of affine transformations on . Thus we may write , where acts on in the natural way. Note that is the commutator subgroup of .
Theorem 3.14**.**
Let be a finite Galois extension of number fields with Galois group and let be a virtual character. Let be an integer. Then Gross’s conjecture (Conjecture 3.12) holds in each of the following cases.
- (i)
* is absolutely abelian, i.e. there is a normal subgroup of such that factors through and is abelian;* 2. (ii)
* is the trivial character;* 3. (iii)
* is a virtual permutation character, i.e. a -linear combination of characters of the form where ranges over subgroups of ;* 4. (iv)
* and is abelian;* 5. (v)
* is totally real and is even;* 6. (vi)
* is a CM-extension, is an odd character and is odd.*
Proof.
We first note that (ii) is Borel’s result (3.6) above. Since Gross’s conjecture is invariant under induction and respects addition of characters, (ii) implies (iii). For (i), (v) and (vi) we refer the reader to [Nic19, Theorem 5.2] and the references given therein. We now prove (iv). It suffices to show that Gross’s conjecture holds for every . If is linear, it factors through so that is indeed absolutely linear. Thus Gross’s conjecture holds by (i). It has been shown in the proof of [JN20a, Theorem 10.5] that there is a unique non-linear irreducible character of and that this character can be expressed as a -linear combination of and linear characters in . As Gross’s conjecture holds for the linear characters and for by (iii), it also holds for . ∎
For any integer we write
[TABLE]
for the canonical -equivariant isomorphism which is induced by mapping to for and . Now fix an integer . We define a -isomorphism
[TABLE]
Here, the first isomorphism is induced by , whereas the second isomorphism is . As above, there exist -isomorphisms
[TABLE]
We now define maps
[TABLE]
and
[TABLE]
Proposition 3.15**.**
Fix an integer and a character . Then Gross’s conjecture 3.12 holds if and only if we have for all .
Proof.
This is [Nic19, Proposition 5.5]. ∎
3.9. The comparison period
We henceforth assume that is an odd prime and that is a Galois CM-extension. Recall that is the unique automorphism induced by complex conjugation. For each we define a central idempotent in . Now let be an integer. Since is CM, the idempotent acts trivially on , whereas vanishes. Thus (3.8) induces a -isomorphism
[TABLE]
We likewise define a -homomorphism
[TABLE]
as follows. For each we let be the -th syntomic cohomology group as considered by Besser [Bes00]. We let be the syntomic regulator [Bes00, Theorem 7.5]. By [BBdJR09, Lemma 2.15] (which heavily relies on [Bes00, Proposition 8.6]) we have canonical isomorphisms for each . The map is induced by the following chain of homomorphisms
[TABLE]
The map shows up in the formulation of the -adic Beilinson conjecture. However, the following map will be more suitable for the relation to the ETNC. We define a -homomorphism
[TABLE]
Here, the first map is induced by the -adic Chern class map which is an isomorphism by Theorem 3.2; the arrow is the natural localization map, and the last isomorphism is induced by the Bloch–Kato exponential maps (see Lemma 3.4).
The following result will be crucial for relating the -adic Beilinson conjecture to the ETNC.
Proposition 3.16**.**
For each we have .
Proof.
For any abelian group we write for its -completion, that is . The localization maps (3.9) induce a map
[TABLE]
For each the Universal Coefficient Theorem [Wei13, Chapter IV, Theorem 2.5] implies that there is a natural (injective) map
[TABLE]
Moreover, by [Bes00, Corollary 9.10] there is a natural map such that the diagram
[TABLE]
commutes. Here, the left-hand vertical arrow is induced by the syntomic regulator, and the map on the right by the isomorphism in Theorem 3.3. Moreover, the composite map
[TABLE]
is the Bloch–Kato exponential map (3.7) by [Bes00, Proposition 9.11]. Unravelling the definitions we now see that the maps and coincide. ∎
We will henceforth often not distinguish between the maps and . Since the Tate–Shafarevich group is torsion-free by Lemma 3.11, the following result is now immediate.
Lemma 3.17**.**
The map is a -isomorphism if and only if holds.
Definition 3.18**.**
Let be a field isomorphism and let . Let be an integer. We define the comparison period attached to , and to be
[TABLE]
We record some basic properties of .
Lemma 3.19**.**
Let be subgroups of with normal in .
- (i)
Let . Then . 2. (ii)
Let . Then . 3. (iii)
Let . Then .
Proof.
Each part follows from the corresponding part of Lemma 2.1. ∎
Remark 3.20*.*
Since is an isomorphism, for any two choices of field isomorphism we have that if and only if .
Remark 3.21*.*
For any fixed choice of field isomorphism we have
[TABLE]
where the first equivalence is Lemma 3.17. Thus the non-vanishing of can be thought of as the ‘-part’ of . Moreover, if then we may set and so if we assume then Lemma 3.19 (i) shows that the definition of naturally extends to any virtual character .
Remark 3.22*.*
Assume that is abelian. For each integer , Burns, Kurihara and Sano [BKS20, §2.2] define canonical period-regulator isomorphisms
[TABLE]
Here are certain idempotents such that the -parts of both -modules in the exterior products are free of the same rank . If and holds, then one may take and . In this case the diagram [BKS20, p. 125] gives an exact sequence of -modules
[TABLE]
where denotes -linear duals (note also that our is their ). The non-trivial map is (up to sign) the dual of . Hence the exterior product on the left of (3.13) canonically identifies with
[TABLE]
and the isomorphism together with induces a map to which can be identified with the exterior power on the right by a variant of Lemma 3.4. For more details we refer the interested reader to [BKS20, §2.2.4].
The authors then use the isomorphism (3.13) to define generalized Stark elements and to state [BKS20, Conjecture 3.6] which might be seen as an analogue and refinement of a conjecture of Rubin [Rub96] in the case . It is then shown in [BKS20, §4] that their conjecture is implied by the appropriate special case of the ETNC. As the formulation of the latter involves the Bloch–Kato exponential map rather than the syntomic regulator, a variant of Proposition 3.16 is already implicit in their work (for instance, see [BKS20, Remark 2.7])
3.10. -adic Artin -functions
Let be a finite Galois extension of totally real number fields and let . Let be an odd prime and let be a finite set of places of containing . For each the -truncated -adic Artin -function attached to is the unique -adic meromorphic function with the property that for each strictly negative integer and each field isomorphism we have
[TABLE]
where is the Teichmüller character and we view as a character of . By a result of Siegel [Sie70] the right-hand side does indeed not depend on the choice of . In the case that is linear, was constructed independently by Deligne and Ribet [DR80], Barsky [Bar78] and Cassou-Nogués [CN79]. Greenberg [Gre83] then extended the construction to the general case using Brauer induction.
3.11. Statement of the -adic Beilinson conjecture
We now formulate our variant of the -adic Beilinson conjecture.
Conjecture 3.23** (The -adic Beilinson conjecture).**
Let be a finite Galois extension of totally real number fields and let . Let be an odd prime and let be a finite set of places of containing . Let and let be an integer. Then for every choice of field isomorphism we have
[TABLE]
Remark 3.24*.*
It is straightforward to show that Conjecture 3.23 does not depend on the choice of .
Remark 3.25*.*
One can show (see Theorem 4.12 below) that if and only if . In this case (and thus in particular if holds) the statement of Conjecture 3.23 naturally extends to all virtual characters .
Remark 3.26*.*
It is clear from the definitions that Conjecture 3.23 is compatible with the -adic Beilinson conjecture as considered by Besser, Buckingham, de Jeu and Roblot [BBdJR09, Conjecture 3.18]. More concretely, the equality (3.14) is equivalent to the appropriate special case of [BBdJR09, Conjecture 3.18 (i)–(iii)], whereas [BBdJR09, Conjecture 3.18 (iv)] then is equivalent to the non-vanishing of as follows from Remark 3.25.
Remark 3.27*.*
Since both complex and -adic Artin -functions satisfy properties analogous to those of given in Lemma 3.19, the truth of Conjecture 3.23 is invariant under induction and inflation; moreover, if it holds for then it holds for .
3.12. The relation to Gross’s conjecture
The following results are the analogues of [JN20a, Theorem 4.16 and Corollary 4.18], respectively.
Theorem 3.28**.**
Let be a finite Galois extension of totally real number fields and let . Let be an odd prime and let be a finite set of places of containing . Let and let be an integer. We put . If for some (and hence every) choice of field isomorphism then the following statements are equivalent.
- (i)
* is independent of the choice of .* 2. (ii)
Gross’s conjecture at holds for and some (and hence every) choice of .
Proof.
The first and second occurrence of ‘and hence every’ in the statement of the theorem follow from Remark 3.13 and Remark 3.20, respectively.
Let be field isomorphisms and let . Then for some and so . For every -isomorphism as in (3.11) we have
[TABLE]
which does not depend on . Hence we have
[TABLE]
By Proposition 3.15 the last expression is equal to if and only if Gross’s conjecture at (Conjecture 3.12) holds for the character . ∎
Corollary 3.29**.**
Let be a finite Galois extension of totally real number fields and let . Fix a prime and let be an integer. Assume that holds. If the -adic Beilinson conjecture at holds for all then Gross’s conjecture at holds for for all .
3.13. Absolutely abelian characters
Since our conjecture is compatible with that of [BBdJR09] by Remark 3.26 and invariant under induction and inflation of characters by Remark 3.27, we deduce the following result from work of Coleman [Col82] (see [BBdJR09, Proposition 4.17]).
Theorem 3.30**.**
Let be a finite Galois extension of totally real number fields and let . Let be a prime and let be an integer. Suppose that is an absolutely abelian character, i.e., there exists a normal subgroup of such that factors through and is abelian. Then the -adic Beilinson conjecture (Conjecture 3.23) holds for .
4. Equivariant Iwasawa theory
4.1. Bockstein homomorphisms
We recall some background material regarding Bockstein homomorphisms. The reader may also consult [BV06, §3.1-§3.2].
Let be a compact -adic Lie group that contains a closed normal subgroup such that is isomorphic to . We fix a topological generator of . The Iwasawa algebra of is
[TABLE]
where the inverse limit is taken over all open normal subgroups of . If is a finite field extension of with ring of integers , we put . We consider continuous homomorphisms
[TABLE]
where is a finitely generated free -module. For we denote its image in under the canonical projection by . We view as a -bimodule, where acts by left multiplication and acts on the right via
[TABLE]
for , and . For each complex we define a complex by
[TABLE]
Given an open normal subgroup of we set and, if is contained in the kernel of , we furthermore obtain a complex
[TABLE]
which does actually not depend on . The natural exact triangles
[TABLE]
in induce short exact sequences of -modules
[TABLE]
for each . The Bockstein homomorphism in degree is defined to be the composite homomorphism
[TABLE]
where the middle arrow is the tautological map. We obtain a bounded complex of -modules
[TABLE]
where the term is placed in degree . Note that the Bockstein homomorphisms and the complex actually depend on the choice of , though our notation does not reflect this. The complex is called semisimple at if is acyclic (for any and hence every choice of ).
For any -module we put .
Lemma 4.1**.**
Assume that is a compact -adic Lie group of dimension and let be acyclic outside degree for some . Further assume that the -module has projective dimension at most . Then for every continuous homomorphism the complex is acyclic outside degree and there is a canonical isomorphism of -modules .
Proof.
This has been shown in the course of the proof of [Bur20, Lemma 5.6]. We repeat the short argument for convenience.
We may assume that . Then may be represented by a complex , where and are projective -modules placed in degrees and [math], respectively, and the homomorphism is injective. Then is represented by
[TABLE]
where is injective since is. The result follows. ∎
4.2. Algebraic -theory
Let be a noetherian integral domain with field of fractions . Let be a finite-dimensional semisimple -algebra and let be an -order in . For any field extension of we set . Let denote the relative algebraic -group associated to the ring homomorphism . We recall that is an abelian group with generators where and are finitely generated projective -modules and is an isomorphism of -modules; for a full description in terms of generators and relations, we refer the reader to [Swa68, p. 215]. Moreover, there is a long exact sequence of relative -theory (see [Swa68, Chapter 15])
[TABLE]
The reduced norm map is defined componentwise on the Wedderburn decomposition of and extends to matrix rings over (see [CR81, §7D]); thus it induces a map , which we also denote by .
In the case the relative -group identifies with the Grothendieck group whose generators are , where is an object of the category of bounded complexes of finitely generated projective -modules whose cohomology modules are -torsion, and the relations are as follows: if is acyclic, and for every short exact sequence
[TABLE]
in (see [Wei13, Chapter 2] or [Suj13, §2], for example).
We denote the full triangulated subcategory of comprising perfect complexes whose cohomology modules are -torsion by . Then every object of defines a class in .
Let be an odd prime and let be a one-dimensional compact -adic Lie group that surjects onto . Then may be written as with a finite normal subgroup of and a subgroup . Let be the ring of integers in some finite extension of . We consider as an order over , where is an open subgroup of that is central in . We denote the fraction field of by and let be the total ring of fractions of . Then [Wit13, Corollary 3.8] shows that the map in (4.3) is surjective; thus the sequence
[TABLE]
is exact. If is a pre-image of some , we say that is a characteristic element for . We also set .
We include the following consequence of (4.4) for later use.
Lemma 4.2**.**
Let be a finitely generated -module of projective dimension at most one. Assume that is torsion as an -module. Then admits a free resolution of the form
[TABLE]
for some positive integer .
Let be an open normal subgroup of and set . If in addition is finite, then vanishes and (4.5) induces a short exact sequence of -modules
[TABLE]
Proof.
Choose a surjective -homomorphism . Its kernel is a projective -module by assumption. Since is -torsion, we see that the classes of and in have the same image in . Hence they coincide by (4.4). In other words, and are stably isomorphic. By enlarging if necessary, we may assume that is free of rank and we have established the existence of (4.5). By [NSW08, Lemma 5.3.11] this sequence induces an exact sequence of -modules
[TABLE]
It follows that is a free -module of the same rank as . This proves the remaining claims. ∎
Now let be a continuous homomorphism as in (4.1) and set . There is a ring homomorphism induced by the continuous group homomorphism
[TABLE]
where denotes the image of in . By [CFK*+*05, Lemma 3.3] this homomorphism extends to a ring homomorphism and this in turn induces a homomorphism
[TABLE]
For we set . If is an Artin representation with character , we also write and for and , respectively, and let
[TABLE]
be the map defined by Ritter and Weiss in [RW04]. By [Nic13, Lemma 2.3] (choose ) we have a commutative triangle
[TABLE]
We shall also write for the leading term at of the power series .
We choose a maximal -order in such that is contained in .
Lemma 4.3**.**
Let be a complex and let be a characteristic element for . Let be an Artin representation with character . Then is a characteristic element for for every .
Proof.
In the case that this is [Bur20, Lemma 5.4 (vii)] (and follows from the naturality of connecting homomorphisms). By [RW04, Remark H] the image of under is contained in . This proves the claim. ∎
4.3. Cohomology with compact support
Let be an odd prime. We denote the cyclotomic -extension of a number field by and set . Let be a finite set of places of containing the set . Let be a topological -module. Following Burns and Flach [BF01] we define the compactly supported cohomology complex to be
[TABLE]
where the arrow is induced by the natural restriction maps. For any integers and we abbreviate to and set .
Let be a finite Galois extension of totally real fields and set . Then is a CM-field and we denote its maximal totally real subfield by as in §3.9. Set and let
[TABLE]
be the -adic cyclotomic character defined by for any and any -power root of unity . The composition of with the projections onto the first and second factors of the canonical decomposition are given by the Teichmüller character and a map that we denote by .
Assume in addition that contains all places that ramify in . For each integer we define a complex of -modules
[TABLE]
where denotes the -module upon which acts on the right via multiplication by the element ; here denotes the image of in . Note that the complexes are perfect by [FK06, Proposition 1.6.5] and we have natural isomorphisms
[TABLE]
for every integer .
Each -module naturally decomposes as a direct sum with . Similarly, each complex of gives rise to subcomplexes and . Moreover, we let be the Pontryagin dual of . By a Shapiro Lemma argument and Artin–Verdier duality we then have isomorphisms
[TABLE]
in . We let be the maximal abelian pro--extension of unramified outside . Then is a finitely generated -module, where we put . Iwasawa [Iwa73] has shown that is in fact torsion as a -module. We let denote the Iwasawa -invariant of and note that this does not depend on the choice of (see [NSW08, Corollary 11.3.6]). Hence vanishes if and only if is finitely generated as a -module. It is conjectured that we always have and as explained in [JN18, Remark 4.3], this is closely related to the classical Iwasawa ‘’ conjecture for at . Thus a result of Ferrero and Washington [FW79] on this latter conjecture implies that whenever and thus is abelian.
The only non-trivial cohomology groups of occur in degrees and [math] and canonically identify with and , respectively. Hence (4.7) with and (4.6) imply that for each integer the cohomology of is concentrated in degrees and and we have
[TABLE]
4.4. The main conjecture
The following is an obvious reformulation of the equivariant Iwasawa main conjecture for the extension (without its uniqueness statement).
Conjecture 4.4** (equivariant Iwasawa main conjecture).**
Let be a Galois CM-extension such that contains a primitive -th root of unity. Let be a finite set of places of containing and all places that ramify in . Then there exists an element such that and for every irreducible Artin representation of with character and for each integer divisible by we have
[TABLE]
for every field isomorphism .
Part (i) of the following theorem has been shown by Ritter and Weiss [RW11] and by Kakde [Kak13] independently. Part (ii) is due to Johnston and the present author [JN20b].
Theorem 4.5**.**
Conjecture 4.4 holds for in each of the following cases.
- (i)
The -invariant vanishes. 2. (ii)
The Galois group has an abelian Sylow -subgroup.
By starting out from the work of Deligne and Ribet [DR80], Greenberg [Gre83] has shown that for each topological generator of there is a unique element in the quotient field of (which we will identify with via the usual map that sends to ) such that
[TABLE]
where . For each integer we let be the automorphisms on induced by for . We use the same notation for the induced group homomorphisms on and , .
Proposition 4.6**.**
Suppose that Conjecture 4.4 holds for . Then for each there exists an element such that and for every irreducible Artin representation of with character we have
[TABLE]
Proof.
When we may take by [JN20a, Proposition 7.5]. Then is a characteristic element for by (4.6) and (4.9) follows from [Bur20, Lemma 5.4 (v)] (see also [Bur15, Lemma 9.5]). ∎
Corollary 4.7**.**
Let be an integer and let be an irreducible Artin representation of with character . Then is a characteristic element of .
Proof.
Since the main conjecture (Conjecture 4.4) holds ‘over the maximal order’ by [JN18, Theorem 4.9] (this result is essentially due to Ritter and Weiss [RW04]), the equality (4.9) holds unconditionally up to a factor for some . Thus the claim follows from Lemma 4.3. ∎
4.5. Schneider’s conjecture and semisimplicity
We recall the following result from [Nic19, Propositions 3.11 and 3.12]. Part (i) is a special case of [BF96, Proposition 1.20] and of [FK06, Proposition 1.6.5].
Proposition 4.8**.**
Let be a Galois extension of number fields with Galois group . Let be an integer and let be an odd prime. Then the following hold.
- (i)
The complex belongs to and is acyclic outside degrees and . 2. (ii)
We have an exact sequence of -modules
[TABLE] 3. (iii)
We have an isomorphism of -modules
[TABLE] 4. (iv)
The -module is finite. 5. (v)
The -rank of equals if and only if Schneider’s conjecture holds.
We now return to the situation considered in §4.3. Before proving the next result we recall that for a finitely generated -torsion module the following are equivalent: (i) is finite; (ii) is finite; (iii) , where denotes a characteristic element for . Moreover, by [NSW08, Proposition 5.3.19] we have that if and only if .
Proposition 4.9**.**
Let be an integer and let be an irreducible Artin character of such that contains . Set . Then we have that for and natural isomorphisms of -modules
[TABLE]
and
[TABLE]
and a short exact sequence of -modules
[TABLE]
In particular, the -modules and are finite.
Proof.
We put for brevity. Since the complex is acyclic outside degrees and and the functor is right exact, it is clear that vanishes for . We let . Then is contained in the kernel of , and by [FK06, Proposition 1.6.5] we have an isomorphism
[TABLE]
in . We now consider the exact sequence (4.2) for the case at hand and various integers . We will repeatedly apply Lemma 2.2. In particular, the complex is acyclic outside degrees , and by Proposition 4.8 (i). For we find that and vanish. Thus vanishes for and even for once we show that the -module is trivial. We already know that it is finite. Sequence (4.2) in the case and Lemma 2.2 now give rise to a short exact sequence
[TABLE]
Since the central idempotent annihilates and we have an isomorphism
[TABLE]
by Proposition 4.8 (ii). Since the Tate–Shafarevich group is torsion-free by Lemma 3.11, the -module is free. Thus vanishes as desired and we have established (4.10). Proposition 4.8 (iii), Lemma 2.2 and the case of sequence (4.2) imply (4.11). Finally, sequence (4.12) is the case of sequence (4.2). ∎
Lemma 4.10**.**
Let be an arbitrary integer. Then there are finitely generated -modules and with all of the following properties:
- (i)
The projective dimension of both and is at most ; 2. (ii)
both and are torsion as -modules; 3. (iii)
there is an exact triangle
[TABLE]
in ; 4. (iv)
we have that and ; 5. (v)
the coinvariants are finite if .
Proof.
We first consider the case . It is shown in [JN19, Proposition 8.5] that the complex is isomorphic in to a complex
[TABLE]
where is placed in degree . More precisely, in the notation of [JN19] we have , and . Here is a finite set of places of disjoint from with certain properties, and denotes the decomposition group at a chosen place of above for each ; moreover, we write for any open subgroup of and any -module . By [JN19, Lemmas 8.4 and 8.5] the modules and are -torsion and of projective dimension at most . Thus (i) and (ii) also hold for and . It is now clear that (iv) holds and that is isomorphic to the complex
[TABLE]
in . Hence (iii) also holds. Moreover, the coinvariants are clearly finite for . ∎
Remark 4.11*.*
We point out that similar constructions repeatedly appear in the literature. In fact, by [Nic13, Theorem 2.4] the complex naturally identifies with the complex constructed by Ritter and Weiss [RW02]. Choosing their maps and in [RW04, p.562 f.] suitably one can take and . Moreover, Burns [Bur20, §5.3.1] constructed an exact triangle in of the form
[TABLE]
where the set is as in the proof of Lemma 4.10. The complexes are acyclic outside degree and we have -isomorphisms
[TABLE]
for each . For each -module and we set . We then have an isomorphism of -modules
[TABLE]
If is a complex in , we write for the complex . If is an -torsion -module of projective dimension at most , then we have isomorphisms in for every . This yields
[TABLE]
The complex is acyclic outside degree and its second cohomology group is of projective dimension at most by [Bur20, Proposition 5.5]. Since we have an isomorphism
[TABLE]
by Artin–Verdier duality, it follows that we have an isomorphism
[TABLE]
in and an isomorphism of -modules
[TABLE]
Finally, the minus Tate module of the Iwasawa-theoretic -motive constructed by Greither and Popescu [GP15] may play the role of ; the -module is our . See in particular [GP15, Remark 3.10].
Theorem 4.12**.**
Let be an integer and let be an irreducible Artin character of such that contains . Set . Then the following conditions are equivalent.
- (i)
We have that vanishes. 2. (ii)
We have that vanishes. 3. (iii)
We have that vanishes. 4. (iv)
The period is non-zero for any (and hence every) choice of . 5. (v)
We have that .
If these equivalent conditions hold (in particular if holds), then the complex is semisimple at .
Proof.
We have already observed in the proof of Proposition 4.9 that is a free -module, where we again set . The equivalence of (i) and (ii) is therefore clear. We have an exact sequence of -modules
[TABLE]
Since the -modules and are (non-canonically) isomorphic and is finite by Proposition 4.8 (iv), there is a (non-canonical) isomorphism of -modules
[TABLE]
Thus also and are (non-canonically) isomorphic and so (ii) and (iii) are indeed equivalent. The equivalence of (ii) and (iv) is easy (see Remark 3.21).
We next establish the equivalence of (i) and (v). By Lemma 4.1 the triangle of Lemma 4.10 (iii) induces an exact triangle
[TABLE]
in . Let and be characteristic elements of and , respectively. Corollary 4.7 implies that we may assume that
[TABLE]
Since is finite by Lemma 4.10 (v) we have that . Thus is non-zero if and only if if and only if vanishes, where the latter equivalence uses Lemma 4.2 (with and ) and Lemma 4.10 (i) and (ii). By (4.13) we have an exact sequence of -modules
[TABLE]
Since taking -invariants is left exact and vanishes by another application of Lemma 4.2, it follows that there is an isomorphism . The latter identifies with by Proposition 4.9 which proves the claim.
Finally, if these equivalent conditions all hold, then Proposition 4.9 implies that the -modules and are finite for all . It follows from the short exact sequences (4.2) that is finite for all , where we set as before. Thus the whole complex vanishes. In particular, the complex is semisimple at . ∎
Remark 4.13*.*
By specializing in the above argument, we see that implies that vanishes and that is finite.
4.6. Higher refined -adic class number formulae
We keep the notation of §4.3. We let be the composition of the inverse of the reduced norm and the connecting homomorphism to relative -theory. By abuse of notation we shall use the same symbol for the induced maps on ‘-parts’. We recall that denotes and that . We define
[TABLE]
Let us assume that Schneider’s conjecture holds. Then we actually have that and the cohomology groups of the complex are finite by Proposition 4.8 and Theorem 4.12. This complex therefore is an object in . We now state our conjectural higher refined -adic class number formula.
Conjecture 4.14**.**
Let be an integer and assume that holds. Then in one has
[TABLE]
Remark 4.15*.*
In the case Burns [Bur20, Conjecture 3.5] has formulated a conjectural refined -adic class number formula. Conjecture 4.14 might be seen as a higher analogue of his conjecture. Accordingly, Theorem 4.17 below is the higher analogue of [Bur20, Theorem 3.6].
Lemma 4.16**.**
Let be an integer and assume that holds. Then
[TABLE]
does not depend on the set .
Proof.
Let be a second sufficiently large finite set of places of . By embedding and into the union we may and do assume that . By induction we may additionally assume that , where is not in . In particular, is unramified in and . By [BF01, (30)] we have an exact triangle
[TABLE]
where is a perfect complex of -modules which is naturally quasi-isomorphic to
[TABLE]
with terms in degree [math] and . We set
[TABLE]
We compute
[TABLE]
where the first and second equality follow from (4.14) and (4.15), respectively. This implies the claim. ∎
Our main evidence for Conjecture 4.14 is provided by the following result which, crucially, does not depend upon the vanishing of .
Theorem 4.17**.**
Let be an integer and assume that holds. If the equivariant Iwasawa main conjecture (Conjecture 4.4) holds for (and so in particular if or if has an abelian Sylow -subgroup), then Conjecture 4.14 holds.
Proof.
We first observe that the complex is semisimple at for all by Theorem 4.12. Moreover, if we put as above, then we have an isomorphism
[TABLE]
in . If Conjecture 4.4 holds, then by Proposition 4.6 there is a characteristic element of such that . Since we have that . If vanishes or does not divide the cardinality of , then [BV11, Theorem 2.2] implies the claim (as noted above the complexes all vanish).
In order to avoid these assumptions, we proceed as follows. Observe that both and are finite by Lemma 4.10 (v) and Theorem 4.12 (or rather Remark 4.13), respectively, since Schneider’s conjecture holds by assumption. Recall from Lemma 4.10 (iii) that we have an exact triangle
[TABLE]
in . It now follows from (4.16) and Lemma 4.2 for both and that we likewise have an exact triangle
[TABLE]
in . Let and in be the reduced norms of characteristic elements of and , respectively. Note that both and are actually reduced norms of matrices with coefficients in . Since Conjecture 4.4 holds by assumption, we may assume that , where is the characteristic element of that occurs in Proposition 4.6. Now by (the proof of) [Nic10, Theorem 6.4] one has
[TABLE]
where
[TABLE]
and is defined similarly. Hence we obtain
[TABLE]
It remains to justify the last equality . For this we compute
[TABLE]
Here the first and second equality follow from [Nic11d, Lemma 2.3] and (4.9), respectively. This finishes the proof of . ∎
Let us write for the torsion subgroup of .
Corollary 4.18**.**
Let be an integer and assume that holds. Then we have that .
Proof.
Let be a totally real field containing . Denote the Galois group by . Then maps to under the natural restriction map . If is a Galois CM-extension of , then likewise maps to under the natural quotient map . Since vanishes for each intermediate Galois CM-extension of degree prime to by Theorem 4.17, we deduce the result by a slight modification of the argument given in [RW97, Proof of Proposition 11] (also see [Nic11c, Proof of Corollary 2]). ∎
4.7. An application to the equivariant Tamagawa number conjecture
Let be an integer and let be a finite Galois extension of number fields with Galois group . We set which we regard as a motive defined over and with coefficients in the semisimple algebra . The ETNC [BF01, Conjecture 4 (iv)] for the pair asserts that a certain canonical element in vanishes. Note that in this case the element is indeed well-defined as observed in [BF03, §1]. If is rational, i.e. belongs to , then by means of the canonical isomorphism
[TABLE]
we obtain elements in .
If is an integer and is a Galois CM-extension, the following result provides a strategy for proving the ETNC for the pair . We let be the image of under the canonical maps
[TABLE]
induced by extension of scalars. We define similarly.
Theorem 4.19**.**
Let be an integer and let be an odd prime. Let be a Galois CM-extension with Galois group and set . Assume that both Schneider’s conjecture and the -adic Beilinson conjecture (Conjecture 3.23) for hold. Then is rational and we have that
[TABLE]
If we assume in addition that the equivariant Iwasawa main conjecture (Conjecture 4.4) holds for , then the -part of the ETNC for the pair holds, i.e. the element vanishes.
Proof.
Since maps to under the canonical quotient map by [BF01, Theorem 4.1], we may and do assume that . Since both Schneider’s conjecture and the -adic Beilinson conjecture hold, Corollary 3.29 implies that Gross’s conjecture at holds for all even (odd) irreducible characters of if is even (odd). By [Nic19, Proposition 5.5 and Theorem 6.5] (or rather the ‘-parts’ of these results) this is indeed equivalent to the rationality of .
Let us define
[TABLE]
By the validity of the -adic Beilinson conjecture we have that
[TABLE]
We clearly have that . Moreover, by Proposition 3.16 the automorphism
[TABLE]
coincides with the ‘-part’ of the trivialization of the same name in [Nic19, §6.2] (up to an insignificant factor ; cf. Remark 3.1). Since we have that , the object
[TABLE]
is equal to the -part of the object denoted by in [Nic19, §6.2]. We now compute
[TABLE]
Here, the first equality holds by definition of , the second and third equality follow from (4.17) (essentially the -adic Beilinson conjecture) and (4.18), respectively, and the last equality follows from [Nic19, Proposition 6.4 and Theorem 6.5]. Now Corollary 4.18 and Theorem 4.17 give the result. ∎
Remark 4.20*.*
Fix an integer . We have assumed throughout that contains a -th root of unity. What was actually needed in the above considerations, however, is that restricted to is trivial. Let be the smallest intermediate field such that restricted to is trivial. Then we can replace by throughout. Note that is totally real and thus whenever is odd, whereas we have otherwise. In particular, we can replace by whenever .
Corollary 4.21**.**
Let be an odd prime and let be an integer such that . Let be a Galois extension of totally real fields with Galois group . Assume that Schneider’s conjecture , the -adic Beilinson conjecture (Conjecture 3.23) for and the equivariant Iwasawa main conjecture (Conjecture 4.4) for all hold. Then is rational and the -part of the ETNC for the pair holds.
Proof.
This follows from Theorem 4.19 and Remark 4.20. ∎
Corollary 4.22**.**
Let be a Galois extension of number fields with Galois group and let be an odd prime. Assume that is abelian. Then is rational and the -part of the ETNC for the pair holds for all but finitely many .
Proof.
We may assume that by functoriality. As is abelian over the rationals, the relevant Iwasawa invariant vanishes by the aforementioned result of Ferrero and Washington [FW79] (see the discussion following (4.7)). Hence Conjecture 4.4 holds for by either part of Theorem 4.5 (but note that in this case a variant of the equivariant Iwasawa main conjecture can be deduced from work of Mazur and Wiles [MW84] as in [RW02, Theorem 8] for example). The -adic Beilinson conjecture holds for by Theorem 3.30. Finally, Schneider’s conjecture holds for all but finitely many by Remark 3.9. Thus the result follows from Theorem 4.19. ∎
Remark 4.23*.*
Of course, the result of Corollary 4.22 is not new. In fact, the ETNC for the pair holds for every integer whenever is abelian. If this is the main result of Burns and Greither in [BG03] (important difficulties with the prime have subsequently been resolved by Flach [Fla11]). The case is due to Burns and Flach [BF06]. A slightly weaker variant of the ETNC, where the integral group ring is essentially replaced by a maximal order containing it, has been studied earlier by Huber and Kings [HK03].
Example 4.24*.*
Let be a Galois extension of totally real fields with Galois group , where is a prime power. Let be an integer. Since Gross’s conjecture holds for all by Theorem 3.14 (iv), we have that is rational by [Nic19, Theorem 6.5 (i)]. Let us write , where denotes the commutator subgroup of . Then the -adic group ring is ‘-hybrid’ in the sense of [JN16, Definition 2.5] by [JN16, Example 2.16] for every prime . Since every -adic group ring is -hybrid, we deduce from [JN19, Theorem 10.2] (or just as well from Theorem 4.5 (ii)) that the equivariant Iwasawa main conjecture holds unconditionally for for every odd prime . Thus Conjecture 4.14 holds by Theorem 4.17 whenever holds. In particular, this conjecture holds for almost all for a fixed prime .
We now assume for simplicity that . The -adic Beilinson conjecture holds for all linear characters of by Theorem 3.30. As we have already observed in the proof of Theorem 3.14 (iv) there is only one non-linear character of which is a -linear combination of linear characters and of . Hence it suffices to show Conjecture 3.23 for the trivial character , i.e. for the trivial extension . Assuming this we can apply Corollary 4.21 to deduce that the -part of the ETNC for the pair holds. So what is missing here (apart from Schneider’s conjecture) is a higher analogue of Colmez’s -adic analytic class number formula [Col88] and its complex analytic counterpart. (A closer analysis of the proof of Theorem 4.19 shows that similar observations indeed hold for arbitrary .)
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