Super-positivity of a family of L-functions in the level aspect

An automorphic self dual L-function has the super-positivity property if all derivatives of the completed L-function at the central point \(s=1/2\) a...

8 downloads 420 Views 620KB Size

Download PDF

Goldfeld and Huang Res Math Sci 61:5)802( https://doi.org/10.1007/s40687-018-0134-4

RESEARCH

Super-positivity of a family of L-functions in the level aspect Dorian Goldfeld1* and Bingrong Huang2,3 * Correspondence:

[email protected] 1 Department of Mathematics, Columbia University, New York, NY 10027, USA Full list of author information is available at the end of the article

Abstract An automorphic self dual L-function has the super-positivity property if all derivatives of the completed L-function at the central point s = 1/2 are nonnegative and all derivatives at a real point s > 1/2 are positive. In this paper, we prove that at least 12% of L-functions associated to Hecke basis cusp forms of weight 2 and large prime level q have the super-positivity property. It is also shown that at least 49% of such L-functions have no real zeros on Re(s) > 0 except possibly at s = 1/2. Keywords: Level, L-function, Molliﬁcation, Real zeros, Super-positivity, Zero-density

1 Introduction The notion of super-positivity of self dual L-functions was introduced in [14] with breakthrough applications to the function ﬁeld analog of the Gross–Zagier formula for higher derivatives of L-functions. We say a self dual L-function has the super-positivity property if all derivatives of its completed L-function (including Gamma factors and power of the conductor) at the central value s = 1/2 are nonnegative, all derivatives at a real point s > 1/2 are positive, and if the k0 th derivative is positive then all (k0 + 2j)th derivatives are positive, for all j ∈ N. See [4] for more details. In this paper, we continue our investigation of super-positivity of L-functions associated to classical modular forms as begun in [4]. Let q be a ﬁxed large prime. Let S2 (q) be the space of holomorphic weight 2 cusp forms of level q, and H2 (q) a basis of S2 (q) that are eigenfunctions of all the Hecke operators and have the ﬁrst Fourier coeﬃcient af (1) = 1. Our main theorem in this paper is as follows. Theorem 1.1 There are inﬁnitely many modular forms f of weight 2 and prime level such that L(s, f ) has the super-positivity property. In fact, the proportion of f ∈ H2 (q) which have the super-positivity property is ≥ 12%, when q is a suﬃciently large prime. In the course of proving Theorem 1.1, we also obtained the following result about real zeros of L-functions as a by-product. Theorem 1.2 There are inﬁnitely many modular forms f of weight 2 and prime level such that L(s, f ) has no nontrivial real zeros except possibly at s = 1/2. In fact, the proportion of f ∈ H2 (q) with this property is ≥ 49%, when q is a suﬃciently large prime.

© SpringerNature 2018.

123

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 2 of 26

A key ingredient of the proofs of the above theorems is given in a paper of Stark and Zagier [13] which essentially establishes that super-positivity follows if L(s, f ) has no zeros in the triangle s = σ + it 1/2 < σ < 1, t ∈ R, |t| ≤ σ − 1/2 . In this regard, see [4]. To prove such a zero-free region for a large number of those L-functions, we ﬁrst use Selberg’s lemma [12, Lemma 14] to convert the count of the number of zeros in this triangle to estimates of the molliﬁed second moments. We will need an asymptotic formula for the molliﬁed second moment of L-functions near the central point 1/2. In Sect. 4, we prove this (with the harmonic weights) by an asymptotic formula for the twisted second moment (see Theorem 3.2) and Perron’s formula. Then we deal with L-functions away from the critical line with the harmonic weights by the convexity principle (see Sect. 5). In order to get a better bound, we also need to improve an estimate of the ﬁrst moment, see Lemmas 5.3 and 6.7. The harmonic weights appear naturally, since we will use the Petersson trace formula. We will remove those harmonic weights in Sect. 6. The proofs of both Theorems 1.1 and 1.2 depend on numerics, which we didn’t try to optimize. Note that some of the techniques in this paper are motivated by Kowalski–Michel [9,10] and Conrey–Soundararajan [1,2]. Remark 1.3 It is possible to consider even and odd forms separately, and then get a more precise result even for ﬁxed even weight and square-free level. One can also prove a positive proportion result in the weight or spectral aspect by combining the ideas in this paper with [4].

2 Preliminaries 2.1 The approximate functional equation

For f ∈ H2 (q), let f (z) =

∞

n1/2 λf (n)e(nz),

(for z ∈ H)

n=1

be its Fourier expansion. We can associate it with an L-function L(s, f ) :=

∞ λf (n) n=1

ns

,

(for Re(s) > 1).

The functional equation is written in terms of the completed L-function √ s q 1 L(s, f ), s+ (s, f ) = 2π 2 namely (s, f ) = εf (1 − s, f ),

(2.1)

and the sign εf of the functional equation is εf = q 1/2 λf (q) ∈ {±1}.

(2.2)

Let G be a polynomial of degree 2N (large enough) satisfying G(−s) = G(s),

G(0) = 1,

and G(−N ) = · · · = G(−1) = 0.

(2.3)

Goldfeld and Huang Res Math Sci 61:5)802(

Page 3 of 26

Notice that we have G (0) = G (0) = 0. That is G(s) = a0

N

(s2 − k 2 ),

a0 = (−1)N (N !)−2 .

k=1

Deﬁne Ht (s) := G(s + it)G(s − it)(s + 1 + it)(s + 1 − it).

(2.4)

By Stirling’s formula, (in a vertical strip) we have

Ht (s) (1 + |t| + |Im(s)|)B · min 1, e−π (|Im(s)|−|t|) , Ht (δ)

(2.5)

for some constant B > 0 depending on N and Re(s). Note that for |δ|

log log q log q ,

we have

Ht (−δ) (−δ + 1 + it)(−δ + 1 − it) = = 1 + O |δ| . Ht (δ) (δ + 1 + it)(δ + 1 − it) By considering the following integral 1 Iδ = 2πi

3+i∞

(1/2 + δ + it + s, f )(1/2 + δ − it + s, f )G(s + it)G(s − it) 3−i∞

ds , s−δ

we can obtain the approximate functional equation of |L(1/2 + δ + it, f )|2 . Lemma 2.1 Let f ∈ H2 (q). Let − logB q ≤ δ ≤ ϑ, δ = 0, and t ∈ R. We have ∞ q −δ λf (n)ηit (n) L(1/2 + δ + it, f )2 = Vδ,t 2 4π n1/2

Here ην (n) :=

a ν

ad=n d

1 Vδ,t (y) := 2πi

3+i∞

3−i∞

n=1

4π 2 n . q

is the generalized divisor function, and for any y > 0,

Ht (s) 2s ζq (1 + 2s)y−s ds Ht (δ) (s − δ)(s + δ)

is real valued, and satisﬁes the following: Vδ,t (y) = ζq (1 + 2δ)y−δ +

Ht (−δ) ζq (1 − 2δ)yδ + ON yN (1 + |t|)B , Ht (δ)

for 0 < y ≤ 1; and Vδ,t (y) A,N y−A (1 + |t|)B for all A ≥ 1, for y ≥ 1, and B depending on A and N . In particular, for all y ≥ 1/q we have Vδ,t (y) q δ (log q)(1 + |t|)B . Here ζq is the Riemann zeta function with the Euler factor at q removed. Proof See Kowalski–Michel [9, pp. 526–527].

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 4 of 26

2.2 The Petersson trace formula

Let H denote the upper half plane. The Fourier coeﬃcients of f ∈ H2 (q) satisfy the relation λf (m)λf (n) =

εq (d)λf

mn

d|(m,n)

d2

(2.6)

,

where εq (·) is the principle Dirichlet character modulo q. In particular, we have λf (q)λf ( ) = λf (q ) for any ∈ Z>0 . The Petersson trace formula is given by the following basic orthogonality relation on H2 (q). Lemma 2.2 Let m, n ≥ 1. Then

ωf · λf (m)λf (n) = δm,n − 2π

f ∈H2 (q)

c≡0(modq)

S(m, n; c) J1 c

√ 4π mn . c

where

(log q)4 ζ (2) 1 1 ωf := = · · 1+O 4π f, f |H2 (q)| L(1, sym2 f ) q

is termed the harmonic weight of f , where ·, · denotes the Petersson inner product on S2 (q),

dx dy f (z) g(z) .

f, g = y2 0 (q)\H

Proof See e.g., Kowalski–Michel [9, pp. 507–509].

By Weil’s bound for Kloosterman sums and the bound J1 (x) x for J -Bessel function, we have (see e.g., [9, eq. (12)])

ωf = 1 + O q −3/2 .

(2.7)

f ∈H2 (q)

We can also consider the number of odd cusp forms. Note that

αf =

f ∈H2 (q) f is odd

1 − εf · αf , 2

(2.8)

f ∈H2 (q)

for any ﬁnite set of complex numbers (αf ). By Kowalski–Michel [11, Lemma 1], we have

ωf =

f ∈H2 (q) f is odd

1 1 +O . 2 q

(2.9)

Also, it’s well known that f ∈H2 (q) f is odd

1∼

1 1. 2 f ∈H2 (q)

(2.10)

Goldfeld and Huang Res Math Sci 61:5)802(

Page 5 of 26

3 The twisted second moment near the critical point Recall that H2 (q) denotes a basis for the space of holomorphic Hecke cusp forms of weight k = 2 for 0 (q) ⊂ SL(2, Z). Assume that for all f ∈ H2 (q) there is some uniquely deﬁned αf ∈ C. Consider the set {αf } := {αf }f ∈H2 (q) . The basic objects of study for the rest of this paper are given in the following deﬁnition. Definition 3.1 Let R1/2 := β + iγ β ∈ (1/2, 1) and |γ | ≤ β − 1/2 . For q > 1, a large prime number, we deﬁne the following sums A {αf }; q := αf ,

A(q) :=

f ∈H2 (q)

M(q) :=

f ∈H2 (q) L(s,f ) = 0 for s ∈ R1/2

1,

f ∈H2 (q)

1,

N (q) :=

1.

f ∈H2 (q) L(s,f ) has at least one zero in R1/2

It follows from Stark–Zagier [13] that it is enough to prove that at least 12% of Lfunctions associated to f ∈ H2 (q) have no zeros in the triangle R1/2 . Furthermore, it is clear that

M(q) + N (q) = A(q). The key strategy for proving Theorem 1.1 is to try to show that M(q) is large compared to A(q). To achieve this goal, we will use the molliﬁcation method which leads us to ﬁrst consider the following twisted second moment of L(s, f ) at the special value s = 1/2+δ+it. 1 both ﬁxed, and t ∈ R. Let Theorem 3.2 Let − logc q ≤ δ ≤ ϑ with c > 0, 0 < ϑ < 100 1−4ϑ

≤q be a positive integer. We have the following asymptotic formula A ωf λf ( )|L(1/2 + δ + it, f )|2 ; q ηit ( ) ηit ( ) Ht (−δ) q −2δ = ζq (1 + 2δ) 1/2+δ + ζq (1 − 2δ) 1/2−δ

Ht (δ) 4π 2 B −1/2+ε + Oε 1 + |t| q .

Remark 3.3 One may use a similar method to obtain the asymptotic formula for the average over even or odd forms, respectively. See Kowalski–Michel [11] for example. Proof We now begin the proof of Theorem 3.2. From the approximate functional equation (Lemma 2.1), we have

A

ωf · λf ( )|L(1/2 + δ + it, f )|2 ωf λf ( )|L(1/2 + δ + it, f )|2 ; q = f ∈H2 (q)

2 ∞ q −δ ηit (n) 4π n = V ωf · λf ( )λf (n). δ,t 2 1/2 4π n q n=1

f ∈H2 (q)

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 6 of 26

Applying the Petersson trace formula (Lemma 2.2), we obtain that

A

ωf λf ( )|L(1/2 + δ + it, f )|2 ; q = D + F ,

(3.1)

where we have the diagonal term (noting that < q)

D :=

2 q −δ η ( ) 4π it V , δ,t 2 1/2 4π

q

and the oﬀ-diagonal term 2 ∞ q −δ 4π n ηit (n) S( , n; c) F := −2π Vδ,t J1 2 1/2 4π n q c n=1

q|c

√ 4π n . c

3.1 The diagonal term

Recall that ϑ is a ﬁxed positive real number less than 1/100. We ﬁrst handle the case − logc q ≤ δ ≤ ϑ and δ = 0. Note that for the remaining case δ = 0, we can just view it as the limitation of δ → 0. Introducing the integral deﬁning Vδ,t (y) in Lemma 2.1, we have

D=

2 −s

q −δ η ( ) 1 3+i∞ Ht (s) 2s 4π it ζ ds. (1 + 2s) q 4π 2

1/2 2πi Ht (δ) q (s − δ)(s + δ) 3−i∞

For −1/2 ≤ Re(s) ≤ 3, we have

Re(s) + 1 2 |(s + 1 + it)(s + 1 − it)| 1. ≤ (δ + 1 + it)(δ + 1 − it) (δ + 1)2

Hence by shifting the contour to the line Re(s) = −1/2 + ε, we obtain ηit ( ) ηit ( ) Ht (−δ) q −2δ + ζ (1 − 2δ) q

1/2+δ

1/2−δ Ht (δ) 4π 2 −1/2+ε+i∞ 2 −s

Ht (s) 2s 4π τ ( )q −δ ζ ds +O (1 + 2s) q 1/2

Ht (δ) q (s − δ)(s + δ)

D = ζq (1 + 2δ)

−1/2+ε−i∞

ηit ( ) ηit ( ) Ht (−δ) q −2δ = ζq (1 + 2δ) 1/2+δ + ζq (1 − 2δ) 1/2−δ

Ht (δ) 4π 2 B −1/2+ε + Oε 1 + |t| q .

(3.2)

Here we use the bound (2.5) for Ht (s)/Ht (δ). 3.2 The oﬀ-diagonal term

One can show that

F (1 + |t|)B q −1/2+ε .

(3.3)

We won’t give the details of the proof of the above estimate, since a very similar result already appeared in Kowalski–Michel [10, Appendix A], and the techniques needed for the proof can be found in Kowalski–Michel [11, Sect. 2.4]. Combining (3.1)–(3.3), completes the proof of Theorem 3.2.

Goldfeld and Huang Res Math Sci 61:5)802(

Page 7 of 26

4 Mollification near the critical point 4.1 Choosing the molliﬁer

We will take the same molliﬁer as in Kowalski–Michel [10, Appendix A]. Let ϑ be a ﬁxed small positive constant, and M ≤ q 1/2−2ϑ . Fix 0 < ϒ < 1. Deﬁne ⎧ 1−ϒ , ⎪ ⎪ ⎨ 1, if 0 ≤ x ≤ M log(M/x) Fϒ,M (x) := P log M , if M 1−ϒ ≤ x ≤ M, ⎪ ⎪ ⎩ 0, if x ≥ M, with P(y) = y/ϒ. We deﬁne the molliﬁer for L(s, f ) by ∞ x (s)

λf ( ),

(4.1)

∞ μ( ) μ2 ( n)Fϒ,M ( n) .

s−1/2 n2s

(4.2)

M(s, f ) :=

=1

1/2

where

x (s) :=

n=1

We always write L(s, f )M(s, f ) as LM(s, f ). In this section, we will prove the following theorem. Theorem 4.1 With the notations as above and 0 < ϒ < 1, M ≤ q 1/2−2ϑ , assume that 100 log log q 100 log log q 100 |t| ≤ and that − log . Then we have log q q ≤δ ≤ log q

2

ωf |LM(1/2 + δ + it, f )| = 1 + q

f ∈H2 (q)

−2δ M

− M (1−ϒ)(−2δ+2it) 2 ϒ(−2δ + 2it) log M

−2δ+2it

M −2δ(1−ϒ) − M −2δ −2δ 1 − q (2δϒ log M)2 log log q −2(1−ϒ)δ M . +O log q

+

Proof By (2.6), we have |M(1/2 + δ + it, f )|2 = = =

∞ ∞ x 1 (1/2 + δ + it)x 2 (1/2 + δ − it)

1 =1 2 =1 ∞ ∞ ∞

1 =1 2 =1 d=1 ∞ ∞ ∞

1 =1 2 =1 d=1

1/2 1/2

1 2

λf ( 1 )λf ( 2 )

εq (d) xd 1 (1/2 + δ + it)xd 2 (1/2 + δ − it) λf ( 1 2 ) 1/2 1/2 d

1

2

1 xd 1 (1/2 + δ + it)xd 2 (1/2 + δ − it) λf ( 1 2 ). 1/2 1/2 d

1

(4.3)

2

Here for the last step, we use the fact that the sum over d is actually supported on [1, M] and that M < q and q being prime. Hence we get

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 8 of 26

A

ωf |LM(1/2 + δ + it, f )|2 ; q =

∞ ∞ ∞ 1 xd 1 (1/2 + δ + it)xd 2 (1/2 + δ − it) 1/2 1/2 d

1 2

1 =1 2 =1 d=1 × A ωf λf ( 1 2 )|L(1/2 + δ + it, f )|2 ; q .

There are two cases we need to consider: ⎧ 100 log log q 100 −100 ⎪ ⎪ and |δ| ≥ , ⎨ log q ≤ δ ≤ log q log q log log q (I) ⎪ 100 log log q ⎪ ⎩ |t| ≤ ; log q and ⎧ 100 ⎪ ⎪ ⎨ |δ| ≤ log q log log q , (II) 100 1 ⎪ ⎪ ⎩ ≤ |t| ≤ . 100 log q log q We will focus on the ﬁrst case (I), which we will assume in this section from now on. Note that the other case can be handled by combining the ideas of Conrey and Soundararajan [1, §6]. Deﬁne νδ (r) :=

1 μ(d) . r d 1+2δ

(4.4)

d|r

By Theorem 3.2, we obtain

A

ωf |LM(1/2 + δ + it, f )|2 ; q

∞ ∞ ∞ 1 xd 1 (1/2 + δ + it)xd 2 (1/2 + δ − it) ηit ( 1 2 ) · ζq (1 + 2δ) = 1/2 1/2 1/2+δ d ( 1 2 )

1 2

1 =1 2 =1 d=1 ηit ( 1 2 ) Ht (−δ) q −2δ + ζq (1 − 2δ) + Oε (1 + |t|)B Mq −1/2+ε 1/2−δ 2 ( 1 2 ) Ht (δ) 4π = S1 + S2 + Oε (1 + |t|)B q −2ϑ+ε , (4.5)

where 2 ηit ( ) , νδ (r) x (1/2 + δ + it) r 1+δ

r=1

2 ∞ ηit ( ) Ht (−δ) q −2δ S2 := ζq (1 − 2δ) ν−δ (r) xr (1/2 + δ + it) . 2 1−δ Ht (δ) 4π

S1 := ζq (1 + 2δ)

∞

r=1

Here we use the following Möbius inversion formula to separate the variables 1 and 2 , m n ηit (mn) = ηit . μ(d)ηit d d d|(m,n)

Goldfeld and Huang Res Math Sci 61:5)802(

Page 9 of 26

4.2 The treatment of S1

For S1 , we will follow Conrey and Soundararajan’s method in [2] to show M −2(1−ϒ)δ − M −2δ log log q −2(1−ϒ)δ M S1 = 1 + +O . (2δϒ log M)2 log q

(4.6)

One may also use the calculation in Kowalski–Michel [10, Apendix D] to prove it. Let ϒ,M (w) be the Mellin transform of Fϒ,M (x). We have ϒ,M (w) =

M w − M (1−ϒ)w . ϒw2 log M

(4.7)

It has a simple pole at w = 0 with residue 1. By Mellin inversion formula we have 1 Fϒ,M (x) = 2πi

α+i∞

ϒ,M (w)x−w dw,

α−i∞

for any constant α > 0. We have

S1 = ζq (1 + 2δ)

∞ r=1

∞ ηit ( ) μ(r ) μ2 (r n)Fϒ,M (r n) 2 νδ (r)

1+δ (r )δ+it n1+2δ+2it

n=1

∞ ∞ νδ (r) μ(r 1 )ηit ( 1 ) μ2 (r 1 n1 )Fϒ,M (r 1 n1 ) = ζq (1 + 2δ) r 2δ

1+2δ+it n1+2δ+2it 1 1

×

n1 =1

1

r=1

∞ μ(r 2 )ηit ( 2 ) μ2 (r 2 n2 )Fϒ,M (r 2 n2 )

2

1+2δ−it 2

= ζq (1 + 2δ)

1 (2πi)2

n1+2δ−2it 2

n2 =1 α+i∞

α+i∞

G1 (w1 , w2 , δ, t)ϒ,M (w1 )ϒ,M (w2 )dw1 dw2 , α−i∞ α−i∞

where G1 (w1 , w2 , δ, t) :=

∞ r=1

×

νδ (r) 2δ+w 1 +w2 r

μ2 (r 1 n1 )μ(r 1 )ηit ( 1 )μ2 (r 2 n2 )μ(r 2 )ηit ( 2 )

1

n1

2

n2

1 +2δ+it 1+w1 +2δ+2it 1+w2 +2δ−it 1+w2 +2δ−2it

1+w n1

2 n2 1

To deal with G1 (w1 , w2 , δ, t), we will use the following easy lemma. Lemma 4.2 Let f, g, h be three multiplicative functions. Denote F (k) = μ2 (rm)μ2 (rn)h(r)f (m)g(n). k=rmn

Then F is a multiplicative function. Proof We ﬁrst note that F is supported on cubic-free numbers. Let k = ab2 , where a, b are square-free numbers. We only need to consider the decompostion of k = rmn with b|m and b|n; otherwise the contribution will be zero because of μ2 . Hence h(r)f (m)g(n). F (k) = F (ab2 ) = f (b)g(b)H(a), where H(a) = a=rmn

Now it’s not hard to check that F is multiplicative.

.

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 10 of 26

We can rearrange the terms in G1 (w1 , w2 , δ, t) and view it as a summation over k = rmn where m = 1 n1 and n = 2 n2 . Hence by Lemma 4.2, we have ηit (p) ηit (p) 1 − p−1−2δ 1 + 1+2δ+w +w − 1+w +2δ+it − 1+2δ+w −it G1 (w1 , w2 , δ, t) = 1 2 1 2 p p p p + − =:

1 p1+w1 +2δ+2it

+

ηit (p) p2+w1 +w2 +4δ−it

1 p1+w2 +2δ−2it −

+

ηit (p)2 2+w p 1 +w2 +4δ

ηit (p)

+

1 p2+w1 +w2 +4δ

p2+w1 +w2 +4δ+it

ζ (1 + 2δ + w1 + w2 ) H1 (w1 , w2 , δ, t). ζ (1 + w1 + 2δ)ζ (1 + w2 + 2δ)

Here the Euler product deﬁning H1 (w1 , w2 , δ, t) converges absolutely for min Re(w1 ), Re(w2 ), Re(w1 + w2 ) > −1/2. To evaluate the integral in S1 , we shift both contours to the line Re(w1 ) = Re(w2 ) = (2A + 1)/ log q, and truncate the w2 integral at |Im(w2 )| ≤ q with error O(q −1+ε ). Then we shift the w1 integral to the contour C1 given by c C1 := w1 Re(w1 ) = −2δ − , log3/4 2 + |Im(w1 )| where c > 0 is a suitable constant such that ζ (s) has no zero in the region Re(s) ≥ 1 − c log−3/4 2 + |Im(s)| and c log−3/4 (2) < 1/3. If q is suﬃciently large, we encounter poles at w1 = 0 and w1 = −2δ − w2 . The ﬁrst pole at w1 = 0 yields a residue 1 1 ζ (1 + 2δ) 2πi

(2A+1)/

log q+iq

H1 (0, w2 , δ, t)ϒ,M (w2 )dw2 (2A+1)/ log q−iq

=

1 1 + Oε ζ (1 + 2δ)

−(1−ϒ)/2+ε M ,

(4.8)

by moving the w2 -contour to C21 where 2A + 1 1 1 1 1 2A + 1 C21 := − iq, − − iq ∪ − − iq, − + iq ∪ − + iq, + iq , log q 2 2 2 2 log q and estimating the integration trivially. The pole at w1 = −2δ − w2 leaves the residue 1 2πi

(2A+1)/

log q+iq

(2A+1)/ log q−iq

H1 (−2δ − w2 , w2 , δ, t) ϒ,M (−2δ − w2 )ϒ,M (w2 )dw2 . ζ (1 − w2 )ζ (1 + 2δ + w2 )

(4.9)

Note that by (4.7) we have ϒ,M (−2δ − w2 )ϒ,M (w2 ) =

M −2δ + M −2δ(1−ϒ) − M −ϒw2 −2δ − M ϒw2 −2δ(1−ϒ) . w22 (2δ + w2 )2 (ϒ log M)2 (4.10)

Goldfeld and Huang Res Math Sci 61:5)802(

Page 11 of 26

We can see that the contributions from the ﬁrst three terms on the right-hand side of −2δ −2δ(1−ϒ) −M −ϒw2 −2δ the above identity, that is, M w+M , are small. Indeed, by shifting the 2 (2δ+w )2 (ϒ log M)2 2

2

integration to the contour C22 where 2A + 1 2A + 1 1 1 1 2A + 1 − iq, −i ∪ − i, − i ∪ − i, + i C22 := log q log q log q 4 4 4 1 2A + 1 2A + 1 2A + 1 ∪ + i, +i ∪ + i, + iq , 4 log q log q log q

and using the standard bounds for the Riemann zeta function, one can show that the contributions from the ﬁrst three terms are bounded by

O

M −2δ(1−ϒ) (log M)2

.

Now we consider the contribution from

−M ϒw2 −2δ(1−ϒ) w22 (2δ+w2 )2 (ϒ log M)2

to (4.9). We move the contour

of integration to the left C23 where 2A + 1 c − iq, −2δ − C23 := − iq log q log3/4 q c c ∪ −2δ − − iq, −2δ − + iq log3/4 q log3/4 q c 2A + 1 ∪ −2δ − + iq , + iq, log q log3/4 q

for the same constant c in the deﬁnition of C1 , and pick up contributions from the poles at w2 = 0 and w2 = −2δ. Similarly, we ﬁnd the integration on C23 can be bounded by 1/4 O M −2δ(1−ϒ) e−c log q , for some c > 0. The pole at w2 = 0 contributes

M −2δ(1−ϒ) 1 H1 (−2δ, 0, δ, t). ζ (1 + 2δ) (2δϒ log M)2

(4.11)

Lastly the pole at w2 = −2δ leaves the residue

−

1 M −2δ H1 (0, −2δ, δ, t). ζ (1 + 2δ) (2δϒ log M)2

(4.12)

The remaining integral, for w1 on C1 , is bounded by 1/4 O M −2δ(1−ϒ) e−c log q , for some c > 0. The proof that M ≤ q 1/2−2ϑ now follows upon combining (4.8), (4.11), and (4.12), and noting that H1 (0, 0, δ, t) = 1.

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 12 of 26

4.3 The treatment of S2

We now consider S2 . Following a similar argument as for S1 , we have ∞ ∞ ∞ Ht (−δ) q −2δ μ2 (r) ηit ( 1 )μ( 1 )μ2 (r 1 n1 ) S2 = ζ (1 − 2δ) ν (r) q −δ Ht (δ) 4π 2 r 2δ

1+it n1+2δ+2it 1 1 r=1

1 =1 n1 =1 ×

∞ ∞ ηit ( 2 )μ( 2 )μ2 (r 2 n2 )

Fϒ,M (r 1 n1 )Fϒ,M (r 2 n2 )

1−it n1+2δ−2it 2 2 Ht (−δ) q −2δ = ζq (1 − 2δ) Ht (δ) 4π 2 α+i∞

α+i∞

1 × G2 (w1 , w2 , δ, t)ϒ,M (w1 )ϒ,M (w2 )dw1 dw2 , (2πi)2

2 =1 n2 =1

α−i∞ α−i∞

where G2 (w1 , w2 , δ, t) μ2 (r)ν−δ (r) μ2 (r 1 n1 )μ( 1 )ηit ( 1 )μ2 (r 2 n2 )μ( 2 )ηit ( 2 ) := 1+w1 +it 1+w1 +2δ+2it 1+w2 −it 1+w2 +2δ−2it r 1+2δ+w1 +w2 n1

2 n1 r

1 n1 2 n2 1 ηit (p) ηit (p) 1 1 1 − p−1+2δ = 1 + 1+2δ+w +w − 1+w +it − 1+w −it + 1+w +2δ+2it + 1+w +2δ−2it 1 2 1 2 1 2 p p p p p p ηit (p)2 1 ηit (p) ηit (p) + 2+w +w + 2+w +w +4δ − 2+w +w +2δ−it − 2+w +w +2δ+it p 1 2 p 1 2 p 1 2 p 1 2 =:

ζ (1 + 2δ + w1 + w2 )ζ (1 + w1 + 2δ + 2it)ζ (1 + w2 + 2δ − 2it) H2 (w1 , w2 , δ, t). ζ (1 + w1 )ζ (1 + w1 + 2it)ζ (1 + w2 )ζ (1 + w2 − 2it)

Here the Euler product deﬁning H2 (w1 , w2 , δ, t) converges absolutely for min Re(w1 ), Re(w2 ), Re(w1 + w2 ) > −1/2. To estimate the integral in S2 , we again shift the w1 and w2 contours to the lines Re(w1 ) = Re(w2 ) = 2A+1 log q . We now truncate the w2 contour at Im(w2 ) ≤ q, and shift the w1 contour to C1 given by c C1 := w1 Re(w1 ) = − 3/4 , log 2 + |Im(w1 + 2it)| for the same constant c in the deﬁnition of C1 . If q is suﬃciently large, we encounter poles at w1 = −2δ − 2it and w1 = −2δ − w2 . The ﬁrst pole at w1 = −2δ − 2it yields a residue 1 1 · ζ (1 − 2δ)ζ (1 − 2δ − 2it) 2πi

(2A+1)/

log q+iq

(2A+1)/ log q−iq

ζ (1 + w2 + 2δ − 2it) ζ (1 + w2 )

(4.13)

× H2 (0, w2 , δ, t)ϒ,M (−2δ − 2it)ϒ,M (w2 )dw2 . where We now move the w2 -contour to C21 2A + 1 2A + 1 C21 := − iq, α0 − iq ∪ [α0 − iq, α0 + iq] ∪ α0 + iq, + iq log q log q

c c with α0 = max − 3/4 , −2δ − 3/4 , pick up the pole at w2 = −2δ + 2it when q is log q log q large enough, and estimate the remaining integration trivially. By doing so, we ﬁnd that (4.13) is equal to

Goldfeld and Huang Res Math Sci 61:5)802(

Page 13 of 26

H2 (0, −2δ + 2it, δ, t) ϒ,M (−2δ − 2it)ϒ,M (−2δ + 2it) ζ (1 − 2δ)ζ (1 − 2δ − 2it)ζ (1 − 2δ + 2it) (4.14) −2δ(1−ϒ) −c log1/4 q +O M e , for some constant c > 0 depending on c and ϒ. The pole at w1 = −2δ − w2 leaves the residue 1 2πi

(2A+1)/

log q+iq

(2A+1)/ log q−iq

ζ (1 − w2 + 2it)ζ (1 + w2 + 2δ − 2it)H2 (−2δ − w2 , w2 , δ, t) ζ (1 − 2δ − w2 )ζ (1 − w2 − 2δ + 2it)ζ (1 + w2 )ζ (1 + w2 − 2it)

× ϒ,M (−2δ − w2 )ϒ,M (w2 )dw2 . (4.15) Note that we have (4.10). We can see that the contributions from the ﬁrst three terms there are small again. Indeed, by the same method as in the treatment of S1 we see that the contributions from the ﬁrst three terms are M −2δ(1−ϒ) O . (log M)2 ϒw2 −2δ(1−ϒ)

−M Now we consider the contribution from w2 (2δ+w C23

2

2)

2 (ϒ

log M)2

to (4.15). We move the contour

of integration to the left where 2A + 1 c c c C23 := − iq, − 3/4 − iq ∪ − 3/4 − iq, − 3/4 + iq log q log q log q log q c 2A + 1 + iq , ∪ − 3/4 + iq, log q log q for the same constant c in the deﬁnition of C1 , and pick up contributions from the poles can be bounded by at w2 = 0 and w2 = −2δ. Similarly, we ﬁnd the integration on C23 1/4 O M −2δ(1−ϒ) e−c log q , for some c > 0. The pole at w2 = 0 contributes −

M −2δ(1−ϒ) 1 H2 (−2δ, 0, δ, t). ζ (1 − 2δ) (2δϒ log M)2

(4.16)

Lastly the pole at w2 = −2δ leaves the residue 1 M −2δ H2 (0, −2δ, δ, t). ζ (1 + 2δ) (2δϒ log M)2

(4.17)

The remaining integral, for w1 on C1 , is bounded by 1/4 O M −2δ(1−ϒ) e−c log q , for some c > 0. Combining (4.14), (4.16), and (4.17), and noting that H2 (0, 0, 0, 0) = 1, we obtain − M (1−ϒ)(−2δ+2it) 2 S2 = q ϒ(−2δ + 2it) log M −2δ(1−ϒ) −2δ log log q −2(1−ϒ)δ M −M − q −2δ + O M . (2δϒ log M)2 log q

−2δ M

−2δ+2it

Finally, by (4.5), (4.6), and (4.18), this completes the proof of Theorem 4.1.

(4.18)

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 14 of 26

5 Mollification away from the critical line In this section, we will prove Theorem 5.1 which is not needed for the proof of our main theorems. However, the results of this section will serve as a prototype for a similar result (without the harmonic weights) which is actually needed in Sect. 6.2. Theorem 5.1 With notations as in Sect. 4, assume s =

1 2

+ δ + it where

1 1 10 log log q ≤ δ ≤ + . log q 2 (1 − ϒ) log q Then there exists an absolute constant B > 0 such that for any 0 < a < 2(1 − ϒ) we have ωf |LM(s, f )|2 − 1 ϒ,ϑ,a,B (1 + |t|)B M −aδ . f ∈H2 (q)

Proof of Theorem 5.1 The proof follows easily from Lemmas 5.2 and 5.3 which are stated and proved below.

Lemma 5.2 With notations as above, assume s = 1/2 + δ + it with δ ≥ 1/(2 log q). Then for any 0 < a < 2(1 − ϒ), we have ωf |LM(s, f ) − 1|2 ϒ,ϑ,a,B (1 + |t|)B M −aδ . f ∈H2 (q)

Proof See Kowalski–Michel [10, Corollary 1]. Lemma 5.3 With notations as above, assume that log1 q ≤ δ ≤ 1/2 + any 0 < a ≤ 2(1 − ϒ), we have ωf LM(s, f ) − 1 ϒ,ϑ,B (1 + |t|)B M −aδ .

10 log log q (1−ϒ) log q .

Then for

f ∈H2 (q)

Remark 5.4 This is an improvement in lemma 7 in Kowalski–Michel [10], where they proved a similar bound for any 0 < a < 1 − ϒ. We will prove the lemma by using the method of Conrey and Soundararajan [2] (see also [4, Lemma 6.6]). The main idea here is to use the approximate functional equation and the Petersson trace formula instead of obtaining the bound by the second moment and the Cauchy–Schwarz inequality. Proof of Lemma 5.3 In the region Re(s) > 1, by (4.1) we may write ⎞ ⎛ ∞ 1 ⎝ λf (a)λf (b)μ(b)μ(bc)2 Fϒ,M (bc)⎠ . LM(s, f ) = ns 2 abc =n

n=1

Using the Hecke relations and the fact that we may assume b < q, we see that ab λf (a)λf (b)μ(b)μ(bc)2 Fϒ,M (bc) = λf μ(b)μ(bc)2 Fϒ,M (bc), 2 d 2 2 abc =n

abc =n d|(a,b)

and setting a = αd, b = βd, and g = cd, this becomes n 2 λf μ(βg) F (βg) μ(βd) = λ (n) μ(β)Fϒ,M (β), ϒ,M f g2 2 2 g |n

αβ=n/g

αβ=n

cd=g

since the terms with g > 1 are easily seen to disappear. Thus LM(s, f ) =

∞ λf (n) n=1

ns

c(n),

where c(n) =

d|n

μ(d)Fϒ,M (d).

Goldfeld and Huang Res Math Sci 61:5)802(

Page 15 of 26

We have c(1) = 1; for 1 < n ≤ M 1−ϒ , we have c(n) = d|n μ(d) = 0; and for n > M 1−ϒ , we have |c(n)| ≤ τ (n). 10 log log q We will ﬁrst handle the case Re(s) = 1/2 + δ0 where δ0 = 1/2 + (1−ϒ) log q . Put B(s, f ) := LM(s, f ) − 1. We consider 1 2πi

3+i∞

(w)B(w + s, f )X w dw, 3−i∞

where X = q 1−ϑ . We shift the line of integration to Re(w) = −δ0 + δ1 , where δ1 = The pole at w = 0 gives B(s, f ), and so we conclude that −δ0 +δ

1 +i∞

3+i∞

1 (w)B(w + s, f )X dw − 2πi

1 B(s, f ) = 2πi

w

3−i∞

1 log q .

(w)B(w + s, f )X w dw −δ0 +δ1 −i∞

=: T1 (s, f ) − T2 (s, f ). We ﬁrst estimate the contribution of the T2 (s, f ) terms. By Cauchy’s inequality and Lemma 6.6, for some constant B > 0 we have ! " −δ0 +δ1 A ωf |T2 (s, f )| ; q X A ωf |(w)| · |B(w + s, f )| |dw| ; q (−δ0 +δ1 )

B

(1 + |t|) X

−δ0 +δ1

(1 + |t|)B q −(1−2ϑ)δ0 (1 + |t|)B M −2(1−ϒ)δ0 . # It remains now to estimate the T1 contribution. Since 2π1 i (α) (w)(X/n)w dw = e−n/X , we see that ∞ λf (n)c(n) −n/X λf (n)c(n) −n/X T1 (s, f ) = e = e + O q −B . s s n n 1−ϒ 2 n=2

M

In order to bound A ωf T1 (s, f ) ; q , for M 1−ϒ < n ≤ X(log q)2 , we consider A ωf λf (n) ; q = ωf · λf (n). f ∈H2 (q)

By Lemma 2.2, we arrive at

− 2π

c ≡ 0 (mod q)

S(1, n; c) J1 c

√ √ √ 4π n n n 3/2−ε r −3/2 3/2−ε . c q q r≥1

Thus we see that if n ≤ X(log q)2 then √ n A ωf λf (n) ; q 3/2−ε q −1−ε . q Hence A ωf T1 (s, f ) ; q q −1 , and A ωf (LM(1/2 + δ0 + it, f ) − 1) ; q B,a (1 + |t|)B M −2(1−ϒ)δ0 . This completes the proof for Re(s) = 1 log q

≤δ≤

1 2

+

10 log log q (1−ϒ) log q

1 2

+ δ0 = 1 +

10 log log q (1−ϒ) log q . Furthermore, the result for

now follows from Lemma 5.2 and the convexity argument.

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 16 of 26

6 Removing the harmonic weights 6.1 Near the critical point

To get the natural average from the harmonic average, we will use the method of [9]. For x ≥ 1, let ωf (x) :=

λf (d 2 ) . dl 2 2

(6.1)

dl ≤x

We will use the following lemma to remove the harmonic weights. Lemma 6.1 Let {αf } be complex numbers satisfying the conditions A {ωf αf }; q (log q)C ,

(for some absolute constant C > 0),

(6.2)

and max |ωf αf | q − ,

f ∈H2 (q)

(for some > 0),

(6.3)

as the level q (prime) tends to inﬁnity. Let x = q κ for some 0 < κ < 1. There exists an absolute constant ς = ς (κ, ) > 0 such that A {αf }; q 1 = A {ωf · ωf (x)αf }; q + O(q −ς ). A(q) ζ (2)

Proof See [9, Proposition 2].

Using the above lemma and similar calculations as in Sect. 4, we can obtain the following theorem. Theorem 6.2 Let q, M, ϒ be the same as in Theorem 4.1. Let x = q κ where 0 < κ < 1 is a 100 log log q 100 log log q 100 small constant. Assume that |t| ≤ and − log . Then we have log q q ≤δ ≤ log q 1 ωf · ωf (x) · |LM(1/2 + δ + it, f )|2 ζ (2) f ∈H2 (q)

−2δ+2it M − M (1−ϒ)(−2δ+2it) 2 = 1 + q −2δ ϒ(−2δ + 2it) log M M −2δ(1−ϒ) − M −2δ log log q −2(1−ϒ)δ −2δ M + O 1 − q + . (2δϒ log M)2 log q Furthermore, we have −2δ+2it M A {|LM(1/2 + δ + it, f )|2 }; q − M (1−ϒ)(−2δ+2it) 2 = 1 + q −2δ A(q) ϒ(−2δ + 2it) log M log log q −2(1−ϒ)δ M −2δ(1−ϒ) − M −2δ −2δ M + 1 − q +O . (2δϒ log M)2 log q

(6.4)

(6.5)

Proof We will follow [5, §6] closely. By (4.3), (6.1), and the Hecke relations, we have ωf (x)|M(1/2 + δ + it, f )|2 =

∞ ∞ ∞ 1 1 2 dl g 2

dl ≤x

×

1 =1 2 =1 g=1

xg 1 (1/2 + δ + it)xg 2 (1/2 + δ − it)

1/2 1/2

1 2

h|(d 2 , 1 2 )

λf

d 2 1 2 h2

.

Goldfeld and Huang Res Math Sci 61:5)802(

Page 17 of 26

Write h = h1 h22 where h1 and h2 are square-free. Clearly h2 |( 1 , 2 ) and h2 |d. Also h1 |(d, 1 2 ). Shifting the orders of summations, and then making changes of variables (d → dh1 h2 , 1 → 1 h2 , and 2 → 2 h2 ), we obtain ∞ ∞ ∞ 1 1 1 1 ωf · ωf (x)|LM(1/2 + δ + it, f )|2 = ζ (2) ζ (2) 2 dl 2 g

1 =1 2 =1 g=1 h|(d 2 , 1 2 ) f ∈H2 (q) dl ≤x 2 xg 1 (1/2 + δ + it)xg 2 (1/2 + δ − it) d 2 1 2 × ωf · λf L(1/2 + δ + it) 1/2 1/2 2 h

1 2 f ∈H2 (q) ∞ ∞ ∞ 1 1 1 1 xg 1 h2 (1/2 + δ + it)xg 2 h2 (1/2 + δ − it) 1/2 1/2 ζ (2) l2 g h22

=

l

1 × h1 h1 | 1 2

1 =1 2 =1 g=1

d
1

h2

2

2 1 ωf · λf d 2 1 2 L(1/2 + δ + it) . d f ∈H2 (q)

Now introducing our expression for the twisted second moment, i.e., Theorem 3.2, we obtain 1 ωf · ωf (x)|LM(1/2 + δ + it, f )|2 ζ (2) f ∈H2 (q)

=

∞ ∞ ∞ 1 1 1 1 xg 1 h2 (1/2 + δ + it)xg 2 h2 (1/2 + δ − it) 1/2 1/2 ζ (2) l2 g h22

1 2

1 =1 2 =1 g=1 h2 l 1 1 ηit (d 2 1 2 ) ζq (1 + 2δ) 2 × h1 d (d 1 2 )1/2+δ h1 | 1 2 d
The error term above contributes Oε Mq −1/2+ε = Oε q −2ϑ+ε . Note that we may remove the restriction on the sum over d with error x−1/2+ε . Thus 2 1 ωf · ωf (x)LM(1/2 + δ + it, f ) ζ (2) f ∈H2 (q) = T1 + T2 + Oε q −κ/2+ε + q −2ϑ+ε ,

(6.6)

where ∞ ∞ ∞ 1 1 T1 := ζq (1 + 2δ) g h22

=1 =1 g=1 1

2

h2

xg 1 h2 (1/2 + δ + it)xg 2 h2 (1/2 + δ − it) 1 ηit (d 2 1 2 ) × , ( 1 2 )1+δ h1 d 2+2δ h1 | 1 2

d

∞ ∞ ∞ Ht (−δ) q −2δ 1 1 T2 := ζq (1 − 2δ) Ht (δ) 4π 2 g h22

1 =1 2 =1 g=1

h2

xg 1 h2 (1/2 + δ + it)xg 2 h2 (1/2 + δ − it) 1 ηit (d 2 1 2 ) × . ( 1 2 )1−δ h1 d 2−2δ h1 | 1 2

d

To estimate the main term contributions, we will need the following lemma.

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 18 of 26

Lemma 6.3 Let 1 and 2 be square-free. For Re(s ± 2ν) > 1 we have ην (d 2 1 2 )

=

ds

d

ην (p) ζ (s)ζ (s + 2ν)ζ (s − 2ν) ζ (2s) 1 + p−s p 1 2 ( 1 , 2 )2

p|( 1 , 2 )

ην (p2 ) − p−s . 1 + p−s

Proof of Lemma 6.3 See Hough [5, lemma 6.3]. By (4.2), we have T1 = ζq (1 + 2δ)

∞ ∞ ∞ 1 1 μ(g 1 h2 )μ(g 2 h2 ) 1 2 g h1 h2 (gh2 )2δ 11+2δ+it 21+2δ−it

1 =1 2 =1 g=1 h h | 2

1

1 2

μ2 (g 1 h2 n1 )Fϒ,M (g 1 h2 n1 ) μ2 (g 2 h2 n2 )Fϒ,M (g 2 h2 n2 ) ηit (d 2 1 2 )

×

n11+2δ+2it

n1

T2 = ζq (1 − 2δ)

n21+2δ−2it

n2

d 2+2δ

d

∞ ∞ ∞ Ht (−δ) q −2δ 1 1 μ(g 1 h2 )μ(g 2 h2 ) 1 Ht (δ) 4π 2 g h1 h22 (gh2 )2δ 1+it

1−it 1 2

1 =1 2 =1 g=1 h h | 2

1

1 2

μ2 (g 1 h2 n1 )Fϒ,M (g 1 h2 n1 ) μ2 (g 2 h2 n2 )Fϒ,M (g 2 h2 n2 ) ηit (d 2 1 2 )

×

,

n11+2δ+2it

n1

n21+2δ−2it

n2

d

d 2−2δ

.

We ﬁrst consider T1 . By Lemma 6.3, we have

T1 = ζq (1 + 2δ)

1 ζ (2 + 2δ) |ζ (2 + 2δ + 2it)|2 1+2δ ζ (4 + 4δ) g h2+2δ r=gh

×

μ( 1 )μ( 2 )

1 , 2 ,n1 ,n2 ( 1 ,n1 )=1,( 2 ,n2 )=1 ( 1 2 n1 n2 ,r)=1

×

p

1 2 ( 1 , 2 )2

1 1+ p

1+2δ+it

1+2δ−it n1+2δ+2it n1+2δ−2it 1 2 1 2

ην (p) 1 + p−2−2δ

p|( 1 , 2 )

1 1+ p

Fϒ,M ( 1 n1 r)Fϒ,M ( 2 n2 r)

ην (p2 ) − p−2−2δ 1 + p−2−2δ

.

Here the factor (1 + 1/p) in the products is coming from the h1 -sum. It follows from Mellin inversion that ζ (2 + 2δ) |ζ (2 + 2δ + 2it)|2 T1 = ζq (1 + 2δ) ζ (4 + 4δ) α+i∞

α+i∞

1 × G1 (w1 , w2 , δ, t)ϒ,M (w1 )ϒ,M (w2 )dw1 dw2 , (2πi)2 α−i∞ α−i∞

where G1 (w1 , w2 , δ, t) :=

r=gh

1 r 1+2δ+w1 +w2 h ⎛

1 , 2 ,n1 ,n2 ( 1 ,n1 )=1,( 2 ,n2 )=1 ( 1 2 n1 n2 ,r)=1

μ( 1 )μ( 2 ) 1+w1 +2δ+it 1+w2 +2δ−it

1

2

⎞ −1 2 ) − p−2−2δ )(1 + p−2−2δ ) (p 1 (η ν ⎠ × 1+w +2δ+2it 1+w +2δ−2it ⎝ 1+ p ην (p)2 n1 1 n2 2 p|( 1 , 2 ) ⎞⎛ ⎞ ⎛ (p) (p) 1 1 η η ν ν ⎠⎝ ⎠. 1+ 1+ ×⎝ p 1 + p−2−2δ p 1 + p−2−2δ 1

p| 1

p| 2

To write G1 (w1 , w2 , δ, t) as an Euler product, we can use the following lemma.

Goldfeld and Huang Res Math Sci 61:5)802(

Page 19 of 26

Lemma 6.4 Let f1 , f2 , g1 , g2 , h, t be some multiplicative functions. Denote F (k) = μ2 (r 1 n1 )μ2 (r 2 n2 )h(r)f1 ( 1 )f2 ( 2 )g1 (n1 )g2 (n2 ) t(p). k=r 1 n1 2 n2

p|( 1 , 2 )

Then F is a multiplicative function. Proof of Lemma 6.4 Note that F is supported on cubic-free numbers. Let k = ab2 , where a, b are square-free numbers. We only need to consider the decompostion of k = r 1 n1 2 n2 with b| 1 n1 and b| 2 n2 ; otherwise the contribution will be zero because of μ2 . Write a = r 1 n1 2 n2 and b = b1 b1 = b2 b2 , where 1 = b1 1 , 2 = b2 2 , n1 = b1 n1 , and n2 = b2 n2 . Hence we have F (k) = F (ab2 ) = h(r)f1 ( 1 )f2 ( 2 )g1 (n1 )g2 (n2 ) a=r 1 n1 2 n2

×

f1 (b1 )g1 (b1 )f2 (b2 )g2 (b2 )

b=b1 b1 =b2 b2

t(p).

p|(b1 ,b2 )

Since b is square-free, it’s not hard to check that F is multiplicative. Now by Lemma 6.4, we have

G1 (w1 , w2 , δ, t) 1 + 1/p 1 + 1/p ηit (p) ηit (p) 1 + 1/p = − 1+2δ−it+w 1 + 1+2δ+w +w − 1+2δ+it+w −2−2δ 1 2 1 2 p 1+p 1 + p−2−2δ p p p + −

1 p1+2δ+2it+w1

+

ηit (p) 2+4δ−it+w 1 +w2 p

1 p1+2δ−2it+w2

+

1 p2+4δ+w1 +w2

ηit (p2 ) − p−2−2δ 1 + 1/p p2+4δ+w1 +w2 1 + p−2−2δ 1 + 1/p . 1 + p−2−2δ

+

1 + 1/p ηit (p) − 2+4δ+it+w +w −2−2δ 1 2 1+p p

Hence we get

G1 (w1 , w2 , δ, t)

ζ (4 + 4δ) 1 1 1 1 = 1 + 2+2δ + 1+2δ+w +w + 3+4δ+w +w + 2+2δ+w +w 1 2 1 2 1 2 ζ (2 + 2δ) p p p p p +

1 p4+4δ+w1 +w2

−

ηit (p) 1+2δ+it+w 1 p

−

ηit (p) 2+2δ+it+w 1 p

−

ηit (p) 1+2δ−it+w 2 p

−

ηit (p) 2+2δ−it+w 2 p

1 1 1 1 1 + 3+4δ+2it+w + 1+2δ−2it+w + 3+4δ−2it+w + 2+4δ+w +w 1 2 1 2 2 p p1+2δ+2it+w1 p p p 2 −2−2δ 2 −2−2δ 1 ηit (p ) − p ηit (p ) − p ηit (p) + 4+6δ+w +w + + − 2+4δ−it+w +w 1 2 1 2 p2+4δ+w1 +w2 p3+4δ+w1 +w2 p p ηit (p) ηit (p) ηit (p) − 3+4δ−it+w +w − 2+4δ+it+w +w − 3+4δ+it+w +w 1 2 1 2 1 2 p p p +

ζ (1 + 2δ + w1 + w2 ) H1 (w1 , w2 , δ, t). ζ (1 + 2δ + w1 )ζ (1 + 2δ + w2 ) Here the Euler product deﬁning H1 (w1 , w2 , δ, t) converges absolutely for min Re(w1 ), Re(w2 ), Re(w1 + w2 ) > −1/2. =:

We ﬁnd that

H1 (0, 0, δ, t) =

ζ (4 + 4δ) . ζ (2 + 2δ)|ζ (2 + 2δ + 2it)|2

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 20 of 26

Hence, by exactly the same argument as in Sect. 4.2, we can prove that

T1 = 1 +

M −2(1−ϒ)δ − M −2δ log log q −2(1−ϒ)δ M + O . (2δϒ log M)2 log q

(6.7)

And similarly, we can handle T2 , getting −2δ+2it M − M (1−ϒ)(−2δ+2it) 2 T2 = q −2δ ϒ(−2δ + 2it) log M M −2δ(1−ϒ) − M −2δ log log q −2(1−ϒ)δ M − q −2δ + O . (2δϒ log M)2 log q

(6.8)

By (6.6)–(6.8), we prove (6.4) in the theorem. To prove (6.5), we will apply Lemma 6.1. Note that condition (6.2) is a consequence of the trivial bound |M(1/2 + δ + it, f )| < M 1/2+ε , the convexity bound L(1/2 + δ + it, f ) q 1/4+ε (1 + |t|)1/2+ε , and the fact ωf (log q)q −1 . The result in Theorem 4.1 guarantees condition (6.3) under our choice of the parameters. The proof is completed upon applying Lemma 6.1.

6.2 Away from the critical line

Now, we want to remove the harmonic weights that appear in Sect. 5. Our main result in this subsection is the following theorem. Theorem 6.5 With notations as in Sect. 4, assume s =

1 2

+ δ + it where

1 1 10 log log q ≤ δ ≤ + . log q 2 (1 − ϒ) log q Then there exists an absolute constant B > 0, such that for any 0 < a < 2(1 − ϒ), we have 1 |LM(s, f )|2 − 1 ϒ,ϑ,a,B (1 + |t|)B M −aδ . A(q) f ∈H2 (q)

Proof of Theorem 6.5 As in Sect. 5, the proof follows easily from Lemmas 6.6, 6.7, stated and proved below.

Lemma 6.6 With notations as above, assume s = 12 + δ + it where δ ≥ any 0 < a < 2(1 − ϒ) we have 1 |LM(s, f ) − 1|2 ϒ,ϑ,a,B (1 + |t|)B M −aδ . A(q)

1 (2 log q) .

Then for

f ∈H2 (q)

Proof Together with Theorem 6.2 and the fact that ωf log q, the proof of the above lemma is similar to Kowalski–Michel [10, Corollary 1].

Lemma 6.7 With notations as above, assume that log1 q ≤ δ ≤ any 0 < a < 2(1 − ϒ) we have 1 LM(s, f ) − 1 ϒ,ϑ,B (1 + |t|)B M −aδ . A(q) f ∈H2 (q)

1 2

+

10 log log q (1−ϒ) log q .

Then for

Goldfeld and Huang Res Math Sci 61:5)802(

Page 21 of 26

Proof of Lemma 6.7 We will ﬁrst handle the case Re(s) = 12 + δ0 where we set 10 log log q δ0 = 12 + (1−ϒ) log q . Put B(s, f ) = LM(s, f )−1. As in the proof of Lemma 5.3, for Re(s) > 1, we have ∞ λf (n) c(n), where c(n) = μ(d)Fϒ,M (d), LM(s, f ) = ns n=1

d|n

and B(s, f ) = T1 (s, f ) − T2 (s, f ). We ﬁrst estimate the contribution of the T2 (s, f ) terms. By Cauchy’s inequality and Lemma 6.6, for some constant B > 0 we have

# A |(w)||B(w + s, f )||dw| ; q A |T2 (s, f )| ; q (−δ0 +δ1 ) X −δ0 +δ1 A(q) A(q) (1 + |t|)B X −δ0 +δ1 (1 + |t|)B q −(1−2ϑ)δ0 (1 + |t|)B M −2(1−ϒ)δ0 . It remains now to estimate the T1 contribution. As before, we have λf (n)c(n) −n/X −B e + O q . T1 (s, f ) = ns 1−ϒ 2 M

In order to bound A1(q) A T1 (s, f ) ; q , for M 1−ϒ < n ≤ X(log q)2 , we consider A λf (n) ; q 1 (log q)5 2 ωf · L(1, sym f )λf (n) + O = . A(q) ζ (2) q f ∈H2 (q)

We can replace L(1, sym2 f ) by the following Dirichlet series (see e.g., Iwaniec–Michel [8, Lemma 3.1]) λf (l 2 ) l V1 L(1, sym2 f ) = l q 1+ε l
w+k−1 )( w+k where L∞ (w, sym2 f ) := π −3w/2 ( w+1 2 )( 2 2 ) and

L∞ (w + u, sym2 f ) (q) 1 du Vw (y) := ζ (2w + 2u) . y−u 2πi L∞ (w, sym2 f ) u (2)

Here ζ (q) (w) stands for the partial zeta function with local factors at primes of q removed. Thus A λf (n) ; q 1 V1 (l/q) ωf · λf (l 2 )λf (n) = A(q) ζ (2) l 1+ε f ∈H2 (q)

l
L∞ V0 (l/q) ωf · λf (l 2 )λf (n) 2 qζ (2)L∞ (1, sym f ) f ∈H2 (q) l
(0, sym2 f )

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 22 of 26

We shall only deal with the ﬁrst term above, since the second one can be handled similarly. For l < M 1−ϒ , by applying Lemma 2.2, we arrive at √ V1 (l/q) 4πl n 1 S(l 2 , n; c) δn,l 2 − 2π J1 . ζ (2) l c c 1−ϒ c ≡ 0 (mod q)

l
The contribution from the ﬁrst term above to

qε

M (1−ϒ)/2
1

A(q)

A T1 (s, f ) ; q is

1 M −(1−ϒ)+ε . l3

By the Weil bound for the Kloosterman sums, we know that the contribution from the second term above to A1(q) A T1 (s, f ) ; q is √ 1 1 (c, n, l 2 )1/2 τ (c) l n ε q · l 1−ϒ n c1/2 c 1−ϒ 2 l
M

M

1−ϒ −1+ε

q

M

−(1−ϒ)

c≡0(q)

.

Hence we get that the contribution from l < M 1−ϒ to

1

A(q)

A T1 (s, f ) ; q is

M −(1−ϒ)+ε . Now we are going to treat the case M 1−ϒ ≤ l < q 1+ε . We will use the following two large sieve inequalities (see [3, Theorem 1]) 2 ωf λf (n)an q ε (N /q + 1) |an |2 , f ∈H2 (q)

n≤N

n≤N

and (see [8, Theorem 5.1]) 2 l ωf λf (l 2 )g q ε (X 2 /q + X). L f ∈H2 (q)

l

Here g is a smooth function supported in [1, 2] which satisﬁes g (j) (x) 1. By applying a smooth partition of unity to the l-sum, we know that the contribution of terms with M 1−ϒ ≤ l < q 1+ε is λf (n)an 1 l ωf λf (l 2 )g sup L ns M 1−ϒ Lq 1+ε L 1−ϒ 2 f ∈H2 (q)

1

sup M 1−ϒ Lq 1+ε

×

f ∈H2 (q)

ωf

L

f ∈H2 (q)

l

M

2 1/2 l ωf λf (l 2 )g L l

M 1−ϒ
λf (n)an 2 1/2 ns

M −(1−ϒ)+ε . Hence

A T1 (s, f ) ; q M −(1−ϒ)+ε , A(q)

and

A (LM(1/2 + δ0 + it, f ) − 1) ; q B,a (1 + |t|)B M −(2(1−ϒ)−ε)δ0 . A(q)

Goldfeld and Huang Res Math Sci 61:5)802(

Page 23 of 26

This completes the proof for Re(s) = 1/2 + δ0 = 1 +

10 log log q (1−ϒ) log q .

The result for

1 10 log log q ≤ δ ≤ 1/2 + log q (1 − ϒ) log q

follows from Lemma 6.6 and the convexity argument.

7 Proof of Theorem 1.2 The proofs depend on Selberg’s lemma in [12, Lemma 14] (see also [1, Lemma 2.1]) and are similar to those of [4, theorems 1.8 and 1.5]. One can see the similarity by replacing K in [4] with q 1/2 , so we don’t give the details. In this section, we will prove that for at least 49% of the modular L-functions of weight 2 and level q we have L(σ , f ) > 0 for σ ∈ (1/2, 1]. Let M = q (1−5ϑ)/2 . We apply Selberg’s lemma with the choices H=

S , log q

R 1 − , 2 log q

W0 =

W1 = 1 +

10 log log q , (1 − ϒ) log q

φ(s) = LM(s, f ),

where R and S are ﬁxed positive parameters which will be chosen later. It follows that 4S

π R + (β − 1/2) log q π γ log q sinh cos 2S 2S

β≥ 12 − logR q 2S 0≤γ ≤ 3 log q L(β+iγ ,f )=0

≤ I1 (f ) + I2 (f ) + I3 (f ),

(7.1)

where

S I1 (f ) := −S

πt cos 2S

2 u S 1 π(u + R) log LM + +i , f du, sinh 2S 2 log q log q

(W1 −1/2)

log q

I2 (f ) := −R

S I3 (f ) := −Re −S

R t 1 log LM − +i , f dt, 2 log q log q

(W1 − 1/2) log q − R + it t cos π log LM W1 + i , f dt. 2iS log q

Now, in the sum over zeros on the left-hand side of (7.1), the weight cos replaced by 1 (see [4, eq. (7.3)]). It follows that

4S

β≥ 12 − logR q 2S 0≤γ ≤ 3 log q L(β+iγ ,f )=0

π R + (β − 1/2) log q ≤ I1 (f ) + I2 (f ) + I3 (f ). sinh 2S

(7.2) πγ 2H

can be

(7.3)

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 24 of 26

Claim 7.1 We have

⎧ ⎪ 4S sinh π2SR , for all odd forms f ∈ H2 (q), ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ for all odd forms f ∈ H2 (q) and ⎪ ⎪ ⎪ ⎪ π R ⎪ ⎪ 12S sinh 2S , if L(s, f ) has a zero ρ = β + iγ ⎪ ⎨ 2S I1 (f ) + I2 (f ) + I3 (f ) ≥ with β ∈ (1/2, 1] and |γ | ≤ 3 log q, ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ for all even forms f ∈ H2 (q) and ⎪ ⎪ ⎪ ⎪ π R ⎪ ⎪ if L(s, f ) has a zero ρ = β + iγ ⎪8S sinh 2S , ⎪ ⎪ ⎪ ⎩ with β ∈ (1/2, 1] and |γ | ≤ 2S . 3 log q

Proof of Claim This is analogous to [4, Claim 7.4]. Note that for odd forms f ∈ H2 (q), we have L(1/2, f ) = 0 for all these f.

Let us now deﬁne

Nr (q) :=

1.

f ∈H2 (q) L(β+iγ ,f ) = 0 2S for some β∈(1/2,1], |γ |≤ 3 log q

By (2.10) and claim 7.1, we have A I1 (f ) + I2 (f ) + I3 (f ) ; q 1 A(q) + Nr (q) ≤ . 4 8S sinh π R 2S

That is A I1 (f ) + I2 (f ) + I3 (f ) ; q Nr (q) 1 ≤ − . A(q) 4 8S sinh π R A(q) 2S

It follows from Theorems 6.2 and 6.5, with the same argument as in [4, §7], that

Nr (q) 1 ≤ A(q) 8S sinh π2SR

∞ +

S

πu

πt cos 2S

log V (−R, t) dt

0

1 log V (u − R, S) du − + Oc (log q)−c , sinh 2S 4

(7.4)

0

for some constant c > 0, where (−u+iv)(1−5ϑ) − e(1−ϒ)(−u+iv)(1−5ϑ) 2 −2u e V (u, v) := 1 + e ϒ(−u + iv)(1 − 5ϑ) −2u

+ (1 − e

e−u(1−ϒ)(1−5ϑ) − e−u(1−5ϑ) ) . (uϒ(1 − 5ϑ))2

(7.5)

π . Then, by taking ϒ = 0.48 and R = 7, and Here we set ϑ = 10−10 and S = 2(1−ϒ)(1−20ϑ) a computer calculation of the integrals on the left-hand side of (7.4), we get

Nr (q) ≤ 0.5041, A(q)

(7.6)

Goldfeld and Huang Res Math Sci 61:5)802(

Page 25 of 26

when q is suﬃciently large. Hence the theorem follows easily.

8 Proof of Theorem 1.1 π In this section, we will take ϑ = 10−10 , ϒ = 0.64, R = 4.6 and S = 2(1−ϒ)(1−20ϑ) . Let J := [C log log q], where C is a large constant and [x] means the largest integer less than x. Set d := 2S/3 and deﬁne the regions: ⎧

⎪ β + iγ β > 12 , |γ | ≤ logd q , if j = 0, ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎨

jd (j+1)d Rj := if 1 ≤ j ≤ J − 1, β + iγ β ≥ 12 + log q , |γ | ≤ log q , ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪

⎪ ⎪ ⎩ β + iγ β ≥ 1 + Jd , |γ | ≤ 1 , if j = J, 2 log q and the zero counting sum Nj (q) :=

(where 0 ≤ j ≤ J ).

1,

f ∈H2 (q) L(s,f ) has at least one zero in Rj

For j = 0, with our new choice of R and ϒ, by the method in Sect. 7, we have

N0 (q) ≤ 0.60934. A(q)

(8.1)

For 1 ≤ j ≤ J − 1, let Bj be the rectangular box with vertices W0,j ± Hj and W1 ± Hj , where W0,j :=

1 jd/2 + , 2 log q

Hj :=

3(j + 1)d/2 . log q

(8.2)

By Selberg’s lemma, and the argument in Sect. 7, we have ⎡

Nj (q) 1 ⎢ ⎣ ≤ πj A(q) 6(j + 1)d sinh 6(j+1)

∞

πu + sinh 3(j + 1)d 0 + Oc (log q)−c ,

3 2 (j+1)d

0

πt cos 3(j + 1)d

log V (jd/2, t) dt

⎤ log V (u + jd/2, 3(j + 1)d/2) du⎦ (8.3)

for some constant c > 0. By a computer calculation of the integrals on the right-hand side of (8.3), we obtain the following bounds:

N1 (q) ≤ 0.21032, A(q)

N2 (q) ≤ 0.03758, A(q)

20 Nj (q) ≤ 0.00528, A(q) j=4

provided q is suﬃciently large.

N3 (q) ≤ 0.00995, A(q) (8.4)

61

61

Goldfeld and Huang Res Math Sci 61:5)802(

Page 26 of 26

To obtain similar bounds for 21 ≤ j ≤ J − 1, we will, instead, use the following trivial bound for u ≥ 20 1 ≤ V (u, v) ≤ 1 + e−0.35u . In this case 21≤j≤J −1

Nj (q) ≤ 0.001 A(q)

(8.5)

for suitable choice of C. Note that by [9, Theorem 4] we also have

NJ (q) (log q)−c , A(q)

(8.6)

when C is large enough. Thus by (8.1), (8.4), (8.5), and (8.6), we get J Nj (q) N (q) ≤ ≤ 0.88, A(q) A(q) j=0

for suﬃciently large q. It immediately follows from the above that

M(q) = A(q) − N (q) ≥ 0.12 · A(q).

(8.7)

This completes the proof of our theorem. Author details 1 Department of Mathematics, Columbia University, New York, NY 10027, USA, 2 School of Mathematics, Shandong University, Jinan 250100, Shandong, China, 3 Present address: School of Mathematical Sciences, Tel Aviv University, 69978 Tel Aviv, Israel. Acknowledgements The second author would like to thank Professors Jianya Liu and Zeév Rudnick for their valuable advice and constant encouragement. Dorian Goldfeld is partially supported by NSA Grant H98230-16-1-0009, Bingrong Huang is supported by the European Research Council, under the European Union’s Seventh Framework Programme (FP7/2007-2013)/ERC Grant Agreement No. 320755. For Don Zagier on his 65th birthday.

Publisher’s Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional aﬃliations. Received: 8 October 2017 Accepted: 27 February 2018

References 1. Conrey, J.B., Soundararajan, K.: Real zeros of quadratic Dirichlet L-functions. Invent. Math. 150(1), 1–44 (2002) 2. Conrey, J.B., Soundararajan, K.: Real zeros of L-functions of modular forms. Private communication 3. Duke, W., Friedlander, J.B., Iwaniec, H.: Bounds for automorphic L-functions. II. Invent. Math. 115(2), 219–239 (1994) 4. Goldfeld, D., Huang, B.: Super-positivity of a family of L-functions. arXiv preprint arXiv: 1612.09359 (2016) 5. Hough, B.: Zero-density estimate for modular form L-functions in weight aspect. Acta Arith. 154(2), 187–216 (2012) 6. Iwaniec, H.: Topics in Classical Automorphic Forms, vol. 17. American Mathematical Society, Providence (1997) 7. Iwaniec, H., Kowalski, E.: Analytic Number Theory, vol. 53. American Mathematical Society, Providence (2004) 8. Iwaniec, H., Michel, P.: The second moment of the symmetric square L-functions. Ann. Acad. Sci. Fenn. Math. 26(2), 465–482 (2001) 9. Kowalski, E., Michel, P.: The analytic rank of J0 (q) and zeros of automorphic L-functions. Duke Math. J. 100(3), 503–542 (1999) 10. Kowalski, E., Michel, P.: Explicit upper bound for the (analytic) rank of J0 (q). Isr. J. Math. 120(part A), 179–204 (2000) 11. Kowalski, E., Michel, P.: A lower bound for the rank of J0 (q). Acta Arith. 94(4), 303–343 (2000) 12. Selberg, A.: Contributions to the theory of Dirichlet’s L-functions. Skr. Norske Vid. Akad. Oslo. I. 1946(3), 62 (1946) 13. Stark, H.M., Zagier, D.: A property of L-functions on the real line. J. Number Theory 12(1), 4952 (1980) 14. Yun, Z., Zhang, W.: Shtukas and the Taylor expansion of L-functions. Ann. Math. 187, 767–911 (2018)

Super-positivity of a family of L-functions in the level aspect

Recommend Documents