On p-torsion of p-adic elliptic curves with additive 3 1 reduction 0 2 n a Ren´e Pannekoek J 0 January 31, 2013 3 ] G A 1 Introduction . h t a In this article, we fix a prime p. If E/Q is an elliptic curve with additive reduction, and p m one chooses for it a minimal Weierstrass equation over Z : p [ 2 y2 +a xy +a y = x3 +a x2 +a x+a , a ∈ Z for each i, 1 3 2 4 6 i p v 3 then we denote by E (Q ) ⊂ E(Q ) the subgroup of points that reduce to a non-singular 3 0 p p 8 point of the reduced curve. As is well-known, this subgroup does not depend on the choice 5 of minimal Weierstrass equation. . 1 The purpose of this note is to investigate the structure of E (Q ) as a topological 1 0 p 2 group. 1 v: Theorem 1. Let E/Qp be an elliptic curve with additive reduction, such that it can be i given by a minimal Weierstrass equation over Z : X p r a y2 +a xy +a y = x3 +a x2 +a x+a , 1 3 2 4 6 where the a are contained in pZ for each i. Then the group E (Q ) is topologically i p 0 p isomorphic to Z , except in the following four cases: p (i) p = 2 and a +a ≡ 2 (mod 4); 1 3 (ii) p = 3 and a ≡ 6 (mod 9); 2 (iii) p = 5 and a ≡ 10 (mod 25); 4 (iv) p = 7 and a ≡ 14 (mod 49). 6 In each of the cases (i)-(iv), E (Q ) is topologically isomorphic to pZ × F , where F 0 p p p p has the discrete topology. 1 The proof of Theorem 1 will be given in Section 4.5. The case p > 7 of Theorem 1 was also mentioned in [3]. We will say a few words about the idea of the proof. It is a standard fact from the theory of elliptic curves over local fields [2, VII.6.3] that E (Q ) admits a canonical 0 p filtration E (Q ) ⊃ E (Q ) ⊃ E (Q ) ⊃ E (Q ) ⊃ ..., 0 p 1 p 2 p 3 p where for each i ≥ 1 the quotient E (Q )/E (Q ) is isomorphic to F . The quotient i p i+1 p p E (Q )/E (Q ) is also isomorphic to F by the fact that E has additive reduction. One 0 p 1 p p has a natural isomorphism of topological groups j : E (Q ) →∼ p2Z given by the theory of 2 p p formal groups. If p > 2, the same theory even gives a natural isomorphism j′ : E (Q ) →∼ 1 p pZ . These isomorphisms identify E (Q ) with pnZ for all n ≥ 2. The idea of the p n p p proof of theorem 1 is to start from j or j′ and, by extending its domain, to build up an isomorphism between E (Q ) and either Z or pZ ×F . 0 p p p p Rather than elliptic curves over Q with additive reduction, we consider the more p general case of Weierstrass curves over Z whose generic fiber is smooth and whose special p fiber is a cuspidal cubic curve. This allows more general results. Theorem 1 is derived as a special case. At the end of the note, we give examples for each prime 2 ≤ p ≤ 7 of an elliptic curve E/Q with additive reduction at p such that E (Q ) contains a p-torsion point defined 0 p over Q. 2 Preliminaries 2.1 Preliminaries on Weierstrass curves All proofs of facts recalled in this section can be found in [2, Ch. IV, VII]. Let K be a finite field extension of Q for some prime p, and let v : K → Z∪{∞} p K be its normalized valuation. Let O be the ring of integers, m its maximal ideal and K K k its residue field. By a Weierstrass curve over O we mean a projective curve E ⊂ P2 K O K defined by a Weierstrass equation 2 3 2 y +a xy +a y = x +a x +a x+a , (1) 1 3 2 4 6 such that the generic fiber E is an elliptic curve with (0 : 1 : 0) as the origin. The K coefficients a are uniquely determined by E. The discriminant of E, denoted ∆ , is i E defined as in [2, III.1]. The curve E is said to be minimal if v (∆ ) is minimal among K E vK(∆E′), where E′ ranges over the Weierstrass curves such that EK′ ∼= EK. We will say that a Weierstrass curve E/O has good reduction when the special fiber K E is smooth, multiplicative reduction when E is nodal (i.e. there are two distinct tangent k k directions to the singular point), and additive reduction when E is cuspidal (i.e. one k tangent direction to the singular point). A non-minimal Weierstrass curve has additive reduction. The reduction type of an elliptic curve E is defined to be the reduction type 2 of a minimal Weierstrass model of E over O , which is a minimal Weierstrass curve E/O K K ∼ such that E = E. By the fact that the minimal Weierstrass model of E is unique up to K O -isomorphism, this is well-defined. K We have E(K) = E(K) = E(O ) since E is projective. Therefore, we have a reduction K map E(K) → E(k) given by restricting an element of E(O ) to the special fiber. By K E (K) we denote the subgroup E (K) ⊂ E(K) of points reducing to a non-singular point 0 0 of the special fiber E . By E (K) ⊂ E (K) we denote the kernel of reduction, i.e. the points k 1 0 that map to the identity 0 of E(k). A more explicit definition of E (K) is k 1 E (K) = {(x,y) ∈ E(K) : v (x) ≤ −2,v (y) ≤ −3}∪{0 }. (2) 1 K K E More generally, one defines subgroups E (K) ⊂ E (K) as follows: n 0 E (K) = {(x,y) ∈ E(K) : v (x) ≤ −2n,v (y) ≤ −3n}∪{0 }. n K K E We thus have an infinite filtration on the subgroup E (K): 1 E (K) ⊃ E (K) ⊃ E (K) ⊃ ··· (3) 1 2 3 For an elliptic curve E/K and an integer n ≥ 0, we define E (K) to be E (K), where E n n is a minimal Weierstrass model of E over O . The E (K) are well-defined, again by the K n fact that the minimal Weierstrass model of E is unique up to O -isomorphism. K Proposition 2. For E a Weierstrass curve over Z , there is an exact sequence p 0 → E (K) → E (K) → E (k) → 0, 1 0 sm e where E is the complement of the singular points in the special fiber E. sm e e Proof. This comes down to Hensel’s lemma. See [2, VII.2.1]. For any Weierstrass curve E, we can consider its formal group E [2, IV.1–2]. This is a b one-dimensional formal group over O . Giving the data of this formal group is the same K as giving a power series F = FEb in OK[[X,Y]], called the formal group law. It satisfies F(X,Y) = X +Y +(terms of degree ≥ 2) and F(F(X,Y),Z)) = F(X,F(Y,Z)). For E as in (1), the first few terms of F are given by: F(X,Y) = 2 2 3 3 2 2 X +Y − a XY − a (X Y +XY ) − 2a (X Y +XY )+(a a −3a )X Y − 1 2 3 1 2 3 4 4 2 3 2 2 3 (2a a +2a )(X Y +XY )−(a a −a +4a )(X Y +X Y ) +... 1 3 4 1 3 2 4 3 Treating the Weierstrass coefficients a as unknowns, we may consider F as an element of i Z[a ,a ,a ,a ,a ][[X,Y]]calledthegenericformalgrouplaw. IfwemakeZ[a ,a ,a ,a ,a ] 1 2 3 4 6 1 2 3 4 6 into a weighted ring with weight function wt, such that wt(a ) = i for each i, then the i coefficients ofF indegree narehomogeneous ofweight n−1 [2, IV.1.1]. Foreach n ∈ Z , ≥2 we define power series [n] in O [[T]] by [2](T) = F(T,T) and [n](T) = F([n−1](T),T) K for n ≥ 3. Here also, we may consider each [n] either as a power series in O [[T]] or as a K power series in Z[a ,a ,a ,a ,a ][[T]] called the generic multiplication by n law. We have: 1 2 3 4 6 Lemma 3. Let [p] = b Tn ∈ Z[a ,a ,a ,a ,a ][[T]] be the generic formal multiplica- Pn n 1 2 3 4 6 tion by p law. Then: 1. p | b for all n not divisible by p; n 2. wt(b ) = n−1, considering Z[a ,a ,a ,a ,a ] as a weighted ring as above. n 1 2 3 4 6 Proof. (1) is proved in [2, IV.4.4]. (2) follows from [2, IV.1.1] or what was said above. The series F(u,v)converges toanelement of m forall u,v ∈ m . To E oneassociates K K the group E(m ), the m -valued points of E, which as a set is just m , and whose group K K K operation +b is given by u + v = F(u,v) fobr all u,v ∈ E(m ). The identity element of K E(m ) is 0 ∈ m . If n ≥ 1 is an integer, then by E(mn )bwe denote the subset of E(m ) K K K K cborresponding to the subset mn ⊂ m , where mn isbthe nth power of the ideal m obf O . K K K K K The groups E(mn ) are subgroups of E(m ), and we have an infinite filtration of E(m ): K K K b b b E(m ) ⊃ E(m2 ) ⊃ E(m3 ) ⊃ ··· (4) K K K b b b Proposition 4. The map ψ : E (K) →∼ E(m ) K 1 K b (x,y) 7→ −x/y 0 7→ 0 is a isomorphism of topological groups. Moreover, ψ respects the filtrations (3) and (4), K i.e. it identifies the subgroups E (K) defined above with E(mn ). n K b Proof. See [2, VII.2.2]. It follows from the proof given in [2, VII.2.2] that there exists a power series w ∈ O [[T]], with the first few terms given by K 3 4 2 5 3 6 w(T) = T +a T +(a +a )T +(a +2a a +a )T +..., 1 1 2 1 1 2 3 such that the inverse to ψ is given by z 7→ (z/w(z),−1/w(z)). Given a finite field K extension K ⊂ L, we have an obvious commutative diagram E (K) ψK // E(m ) 1 K b incl incl (cid:15)(cid:15) (cid:15)(cid:15) E (L) ψL // E (m ) 1 OL L d 4 Here E (m ) is the set of m -valued points of the formal group of E , the base-change OL L L OL d of E to Spec(O ). L 2.2 Extensions of topological abelian groups Proposition 5. Suppose X is a topological abelian group and we have a short exact sequence 0 → Zd → X → F → 0. p p of topological groups where the second arrow is a topological embedding. Then X is iso- morphic as a topological group to either Zd or Zd ×F . p p p It is indeed necessary to require Zd → X to be a topological embedding, i.e. a homeo- p morphism onto its image, since otherwise we could take X to be the product (Zd)ind×F , p p where the first factor is the abelian group Zd endowed with the indiscrete topology. p Proof. First, weclaimthat Ext1(F ,A) = A/pAforanyabeliangroupA. Taking thelong Z p p exact sequence associated to Hom (−,A) for the exact sequence 0 → Z → Z → F → 0 Z p results in the exact sequence Hom(Z,A) →p Hom(Z,A) → Ext1(F ,A) → Ext1(Z,A) = 0 Z p Z where the last equality follows from the fact that Hom(Z,−) is an exact functor. Using that Hom(Z,A) = A, we get Ext1(F ,A) = A/pA, Z p which proves the claim. Putting A = Zd, we find Ext1(F ,Zd) = Fd. We conclude that p Z p p p theequivalence classes ofextensions ofZ-modules 0 → Zd → X → F → 0 areinbijective p p correspondence with the elements of Fd. The element 0 ∈ Fd corresponds to the split p p extension. The non-split ones are obtained as follows. For v ∈ Zd−pZd, we construct an p p extension 0 → Zd → X →fv F → 0. p v p by defining the subgroup X ⊂ Qd as X = Zd +hv/pi and letting f : X → F be the v p v p v v p unique group homomorphism that is trivial on Zd ⊂ X and that sends v/p to 1. The p v equivalence class of the above extension only depends on the class of v modulo pZd. Note p that if we take any element x ∈ X mapping to 1 ∈ F , we have px = v +pv ∈ Zd for v p 1 p some v ∈ Zd. Note further that X is topologically isomorphic to Zd, if we give it the 1 p v p subspace topology. A diagram chase shows that this construction gives us pd − 1 different equivalence classes of extensions. Suppose that v,w ∈ Zd −pZd and φ : X →∼ X are such that p p v w 0 //Zd // X fv //F //0 p v p id φ id (cid:15)(cid:15) (cid:15)(cid:15) (cid:15)(cid:15) 0 //Zd // X fw //F //0 p w p 5 is a commutative diagram. Consider an element x ∈ X such that f (x) = 1. Then v v f (φ(x)) = 1. Furthermore, px = v+pv for some v ∈ pZd, andφ(px) = pφ(x) = w+pw w 1 1 p 1 for some w ∈ pZd. Hence v +pv = φ(v +pv ) = w+pw , so v ≡ w (mod pZd). 1 p 1 1 1 p Let X be a topological group sitting inside an extension of topological groups 0 → Zd →i X →f F → 0, with i a topological embedding and f continuous. This means that p p there exists an extension of topological groups 0 → Zd → Y → F → 0 that is either p p split or equal to one of the form 0 → Zd → X →fv F → 0, an isomorphism of groups p v p ∼ φ : X → Y, and a commutative diagram: 0 //Zd //X f //F //0 p p id φ id (cid:15)(cid:15) (cid:15)(cid:15) (cid:15)(cid:15) 0 //Zd //Y // F //0. p p We claim that φ must also be a homeomorphism. Since both X and Y are topological disjoint unions of the translates of their subgroups Zd, and φ respects the disjoint union p decomposition, this is clear. So X is topologically isomorphic to Y, and hence to either Zd or Zd ×F . p p p Remark 6. By repeatedly applying Proposition5, we see that if we have a finite filtration Zd = M ⊂ M ⊂ ... ⊂ M p n n−1 1 of topological groups, in which all quotients are isomorphic to F , then M is torsion-free p 1 if and only if it is topologically isomorphic to Zd. p The following is a strengthening of Proposition 5 in the case d = 1, which will be important for us. Corollary 7. Let p be a prime and suppose we have a short exact sequence i 0 → pZ → X → F → 0 p p of topological abelian groups where the second arrow is a topological embedding. If X is topologically isomorphic to Z , then v (i−1(px)) = 1 for all x ∈ X−i(pZ ), where v is the p p p p p-adic valuation. If X is not topologically isomorphic to Z , it is topologically isomorphic p to pZ ×F , and we have v (i−1(px)) > 1 for all x ∈ X −i(pZ ). p p p p Proof. If X is topologically isomorphic to Z , the map i is given by multiplication by p some unit α ∈ Z∗ followed by the inclusion pZ ⊂ Z . The conclusion follows. p p p If X is not topologically isomorphic to Z , then by Proposition 5 we must have X ∼= p pZ ×F . But then if x = (y,c), we have v (i−1(px)) = v (py) > 1. p p p p 6 Lemma 8. Let K be a finite extension of Q with ring of integers O . Then O is p K K topologically isomorphic to Zd, where d = [K : Q ]. p p Proof. O is a free Z -module of rank d, so there is a group isomorphism Zd →∼ O . K p p K Since both groups are topologically finitely generated, any isomorphism between them is bicontinuous [1, 1.1]. 3 Weierstrass curves with additive reduction over O K As in section 2, let K be a finite extension of Q . Let O again be the ring of integers of p K K, with maximal ideal m and residue field k. K In this section, we gather some general properties of Weierstrass curves over O with K additive reduction. Lemma 9. Let E/O be a Weierstrass curve with additive reduction. Then E is O - K K isomorphic to a Weierstrass curve of the form 2 3 2 y +a xy +a y = x +a x +a x+a , 1 3 2 4 6 where all a lie in m . i K Proof. We construct an automorphism α ∈ PGL (O ) that maps E to a Weierstrass 3 K curve of the desired form. Consider a translation α ∈ PGL (O ) moving the singular 1 3 K point of the special fiber E to (0 : 0 : 1). The image E = α (E) is a Weierstrass k 1 1 curve with coefficients satisfying a ,a ,a in m . There exists a second automorphism 3 4 6 K α ∈ PGL (O ), of the form x′ = x,y′ = y +cx, such that in the special fiber of α (E ) 2 3 K 2 1 the unique tangent at (0 : 0 : 1) is given by y′ = 0. The Weierstrass curve E = α (E ) 2 2 1 now has all its coefficients a ,a ,a ,a ,a in m . One may thus take α = α ◦α . 1 2 3 4 6 K 2 1 Suppose that E/O is a Weierstrass curve given by (1), and suppose that the a K i are contained in m . In particular, E has additive reduction. If we let F denote the K formal group law of E, then the assumption on the a implies that F(u,v) converges to i an element of O for all u,v ∈ O . Hence F can be seen to induce a group structure on K K O , extending the group structure on E(m ). The same statement holds true when we K K b replace K by a finite field extension L. Definition 10. Let E/O be a Weierstrass curve given by (1), and assume that the a K i are contained in m . For any finite field extension K ⊂ L, we denote by E(O ) the K L b topological group obtained by endowing the space O with the group structure induced L by F. ThefollowingpropositionwillbefundamentalindeterminingofthestructureofE (Q ) 0 p as a topological group for Weierstrass curves with additive reduction. 7 Proposition 11. Let E/O be a Weierstrass curve given by (1), and assume that the a K i are contained in m . K 1. The map Ψ : E (K) → E(O ) that sends (x,y) to −x/y is an isomorphism of 0 K b topological groups. 2. If 6e(K/Q ) < p − 1, where e denotes the ramification degree, then E (K) is also p 0 topologically isomorphic to O equipped with the usual group structure. K Proof. Let π be a uniformizer for O . Consider the field extension L = K(ρ) with ρ6 = π. K Then define the Weierstrass curve D over O by L 2 3 2 4 y +α xy +α y = x +α x +α x x+α , 1 3 2 4 6 where α = a /ρi. There is a birational map φ : E × O 99K D, given by φ(x,y) = i i OK L (x/ρ2,y/ρ3). The birational map φ induces an isomorphism on generic fibers, and hence a homeomorphism between E(L) and D(L). Using (2) and the fact that we have (x,y) ∈ E (L) if and only if v (x),v (y) are both not greater than zero, one sees that φ induces 0 L L ∼ a bijection E (L) → D (L), that all maps (a priori just of sets) in the following diagram 0 1 are well-defined, and that the diagram commutes: E (K) incl //E (K) incl // E (L) φ //D (L) 1 0 0 1 (cid:15)(cid:15)ψK (cid:15)(cid:15)Ψ (cid:15)(cid:15)ΨL (cid:15)(cid:15)ψL E(m ) incl //E(O ) incl //E(O ) ·ρ // D(m ) K K L L b b b b Here the map Ψ : E (L) → O is defined by (x,y) 7→ −x/y, the rightmost lower hori- L 0 L zontal arrow is multiplication by ρ, and the maps labeled incl are the obvious inclusions. Note that the horizontal and vertical outer maps are all continuous. Since ψ , φ and L multiplication by ρ are homeomorphisms (for ψ one uses Proposition 4), so is Ψ . Hence L L Ψ must be a homeomorphism onto its image. By Galois theory, Ψ is surjective, so it is itself a homeomorphism. Let Fb be the formal group law of D. One calculates that D ρF(X,Y) = Fb(ρX,ρY). D Hence all maps in the diagram are group homomorphisms. This proves the first part of the proposition. Now assume 6e(K/Q ) < p−1, so that v (p) = 6v (p) = 6e(K/Q ) < p−1. Now [2, p L K p IV.6.4(b)] implies that E (K) is topologically isomorphic to m , and D (L) to m . Since 1 K 1 L E has additive reduction, we have E (k) ∼= k+ ∼= Ff, where f = f(K/Q ) is the inertia sm p p e degree of K/Q and E is the smooth locus of the special fiber of E. Proposition 2 shows p sm e we have a short exact sequence 0 → m → E (K) → Ff → 0. K 0 p 8 In the diagram above, the topological group E (K) is mapped homomorphically into the 0 torsion-free group D (L), hence it is itself torsion-free. It follows from Remark 6 that 1 E (K) is topologically isomorphic to O . This proves the second part. 0 K The following corollary is worth noting, but will not be used in what follows. Corollary 12. Let E/O be a Weierstrass curve with additive reduction. If 6e(K/Q ) < K p p−1, then E (K) is topologically isomorphic to O . 0 K Proof. The statement that E (K) is topologically isomorphic to O only depends on the 0 K O -isomorphismclassofE. ByLemma 9, thereexists aWeierstrass curve E′ witha ∈ m K i K that is O -isomorphic to E. Now apply Proposition 11 to E′. K 4 Weierstrass curves with additive reduction over Z p In this section, we gather some general properties of Weierstrass curves over Z with p additive reduction and finish the proof of theorem 1. Lemma 13. Let E/Z be a Weierstrass curve with additive reduction. Then there exists p a topological isomorphism χ : E(pZ ) →∼ pZ such that for n ∈ Z , χ identifies E(pnZ ) p p ≥1 p with pnZ . b b p Proof. For p > 2, this is standard; the proof may be found in [2, IV.6.4(b)]. We now treat the case p = 2. By Lemma 9, we may assume that the Weierstrass coefficients a of E all i lie in 2Z . The multiplication by 2 on E(2Z ) is given by the power series 2 2 b 2 3 4 [2](T) = FEb(T,T) = 2T −a1T −2a2T +(a1a2 −7a3)T −..., (5) where FEb is the formal group law of E. By [2, IV.3.2(a)], E(2Z2)/E(4Z2) is cyclic of order b b ∼ 2. By [2, IV.6.4(b)], there exists a topological isomorphism E(4Z ) → 4Z . Hence there 2 2 b exists an extension i 0 → 4Z → E(2Z ) → F → 0. 2 2 2 b From Theorem 5 we see that E(2Z ) is topologically isomorphic either to 2Z or to 4Z × 2 2 2 b F . Assume that the latter is the case, then there is an element z of order 2 in E(2Z ) that 2 2 b isnotcontainedinE(4Z ). Forsuchaz wehavev (z) = 1,wherev : E(2Z ) → Z ∪{∞} 2 2 2 2 ≥1 b b is the 2-adic valuation on the underlying set 2Z of E(2Z ). Using that in the duplication 2 2 b power series (5) we have a ∈ 2Z for each i, it follows that v ([2](z)) = 2, so [2](z) 6= 0. i 2 2 ∼ This is a contradiction, so there exists an isomorphism χ : E(2Z ) → 2Z as topological 2 2 groups. From this, and from the fact that E(2nZ )/E(2n+1Zb ) ∼= F for all n ∈ Z [2, 2 2 2 ≥1 b b IV.3.2(a)], we see that χ necessarily respects the filtrations on either side. Corollary 14. Let E/Z be a Weierstrass curve with additive reduction. Then there exists p an isomorphism E (Q ) →∼ pZ which for n ∈ Z identifies E (Q ) with pnZ . 1 p p ≥1 n p p Proof. Such an isomorphism can be obtained by composing the isomorphism χ from Lemma 13 with the isomorphism ψ from Proposition 4. Qp 9 4.1 p = 2 Proposition 15. Let E/Z be a Weierstrass curve with its coefficients a in 2Z . Then 2 i 2 E (Q ) is topologically isomorphic to Z if a +a ≡ 0 (mod 4), and to 2Z ×F otherwise. 0 2 2 1 3 2 2 Proof. Proposition 2 shows that there is a short exact sequence 0 → E (Q ) → E (Q ) → F → 0. 1 2 0 2 2 ByLemma13, wehaveE (Q ) ∼= 2Z , soProposition5impliesthatE (Q )istopologically 1 2 2 0 2 isomorphic either to Z or to 2Z ×F . 2 2 2 Let [2](T) ∈ O [[T]] be the formal duplication formula (5) on E. Let Ψ be the map K from Proposition 11. Since Ψ is an isomorphism of topological groups, we have for all P ∈ E (Q ): 0 2 Ψ(2P) = [2](Ψ(P)). (6) By Corollary 7, we have E (Q ) ∼= Z if and only if for all P ∈ E (Q )−E (Q ) we have 0 2 2 0 2 1 2 2P = E (Q ) − E (Q ), which by (6) is true if and only if for all z ∈ E(Z ) − E(2Z ) 1 2 2 2 2 2 b b we have v ([2](z)) = 1, where v : E(Z ) → Z ∪ {∞} is the 2-adic valuation on the 2 2 2 ≥0 b underlying set Z of E(Z ). This condition may be checked using the duplication power 2 2 b series ∞ [2](T) = 2T −a1T2 −2a2T3 +(a1a2 −7a3)T4 −... = XbiTi. i=1 In deciding whether v ([2](z)) = 1 for z ∈ E(Z ) − E(2Z ), we do not need to consider 2 2 2 b b those parts of terms whose coefficients have valuation ≥ 2. The non-linear parts of each coefficient b will contribute only terms with valuation ≥ 2, so may ignore these and keep i only the linear parts. The terms b zi with i odd we may discard altogether; by Lemma i 3, all their coefficients have valuation ≥ 2. Finally, we may discard all terms b zi with i i even and ≥ 6: a polynomial in Z[a ,...,a ] whose weight is odd and at least 5 does not 1 6 contain a linear term (there being no a ), so the terms involving z6,z8,z10,... will have 5 valuation ≥ 2. We thus get that, if z ∈ E(Z )−E(2Z ), 2 2 b b 2 4 v ([2](z)) = 1 ⇔ v (2z −a z −7a z ) = 1. 2 2 1 3 This is true for all z ∈ E(Z )−E(2Z ) if and only if: 2 2 b b a 7a 1 2 3 4 v (z − z − z ) = 0 ⇔ a +7a ≡ 0 (mod 4) ⇔ a +a ≡ 0 (mod 4) 2 1 3 1 3 2 2 since z ≡ z2 ≡ z4 (mod 2). This proves the proposition. 10