Abstract
We give a simple proof of a standard zero-free region in the t-aspect for the Rankin–Selberg L-function \(L(s,\pi \times \widetilde{\pi })\) for any unitary cuspidal automorphic representation \(\pi \) of \(\mathrm {GL}_n(\mathbb {A}_F)\) that is tempered at every nonarchimedean place outside a set of Dirichlet density zero.
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1 Introduction
Let F be a number field, let n be a positive integer, and let \(\pi \) be a unitary cuspidal automorphic representation of \(\mathrm {GL}_n(\mathbb {A}_F)\) with L-function \(L(s,\pi )\), with \(\pi \) normalised such that its central character is trivial on the diagonally embedded copy of the positive reals. The proof of the prime number theorem due to de la Valleé–Poussin gives a zero-free region for the Riemann zeta function \(\zeta (s)\) of the form
for \(s = \sigma + it\), and this generalises to a zero-free region for \(L(s,\pi )\) of the form
for some absolute constant \(c > 0\), where \(\mathfrak {q}(\pi )\) is the analytic conductor of \(\pi \) in the sense of [12, Equation (5.7)], with the possible exception of a simple real-zero \(\beta _{\pi } < 1\) when \(\pi \) is self-dual. A proof of this is given in [12, Theorem 5.10]; the method requires constructing an auxiliary L-function having a zero of higher order than the order of the pole at \(s = 1\), then using an effective version of Landau’s lemma [12, Lemma 5.9].
Now let \(\pi '\) be a unitary cuspidal automorphic representation of \(\mathrm {GL}_{n'}(\mathbb {A}_F)\), and consider the Rankin–Selberg L-function \(L(s,\pi \times \pi ')\). Via the Langlands–Shahidi method, this extends meromorphically to the entire complex plane with at most a simple pole at \(s = 1\), with this pole occurring precisely when \(\pi ' \cong \widetilde{\pi }\). Moreover, this method shows that \(L(s,\pi \times \pi ')\) is nonvanishing in the closed right half-plane \(\mathfrak {R}(s) \ge 1\) [25, Theorem].
Remark 1.2
One can also obtain the nonvanishing of \(L(s,\pi \times \pi ')\) on the line \(\mathfrak {R}(s) = 1\) via the Rankin–Selberg method. For \(n = n'\) and \(\pi ' \ncong \widetilde{\pi }\), this is shown in [21, Theorem 6.1]; the method of proof nonetheless is equally valid for \(n \ne n'\) or \(\pi ' \cong \widetilde{\pi }\), noting in the latter case that \(L(s,\pi \times \widetilde{\pi })\) has a simple pole at \(s = 1\) (see also [24, Equation (1.5)]). Note, however, that the product of L-functions considered in [21, Remark, p. 198] may not be used to show the desired nonvanishing of \(L(1 + it,\pi \times \pi ')\), but merely the nonvanishing of \(L(1,\pi \times \pi ')\).
Proving zero-free regions for \(L(s,\pi \times \widetilde{\pi })\) akin to (1.1), on the other hand, seems to be much more challenging. The method of de la Valleé–Poussin relies on the fact that the Rankin–Selberg convolutions \(L(s,\pi \times \pi )\) and \(L(s,\pi \times \widetilde{\pi })\) exist and extend meromorphically to \(\mathbb {C}\) with at most a simple pole at \(s = 1\). For \(L(s,\pi \times \pi ')\), the associated Rankin–Selberg convolutions have yet to be proved to have these properties, so as yet this method is inapplicable.
Remark 1.3
Note that in [12, Exercise 4, p. 108], it is claimed that one can use this method to prove a zero-free region similar to (1.1) when \(\pi ' \ncong \pi \) and \(\pi ' \ncong \widetilde{\pi }\); however, the hint to this exercise is invalid, as the Dirichlet coefficients of the logarithmic derivative of the auxiliary L-function suggested in this hint are real but not necessarily nonpositive. (In particular, as stated, [12, Exercise 4, p. 108] would imply the nonexistence of Landau–Siegel zeroes upon taking f to be a quadratic Dirichlet character and g to be the trivial character.)
Remark 1.4
When at least one of \(\pi \) and \(\pi '\) is self-dual, then this method can be used to prove a zero-free region akin to (1.1). When both \(\pi \) and \(\pi '\) are self-dual, this is proved by Moreno [21, Theorem 3.3] (see also [24, Equation (1.6)]). When only one of \(\pi \) and \(\pi '\) is self-dual, such a zero-free region has been stated by various authors (in particular, see [5, p. 619], [6, p. 92], and [7, p. 1]); to the best of our knowledge, however, no proof of this claim has appeared in the literature. In the appendix to this article written by Farrell Brumley, a complete proof of this result is given.
In [5], Gelbart and Lapid generalise Sarnak’s effectivization of the Langlands–Shahidi method for \(\zeta (s)\) [24] to prove a zero-free region for \(L(s,\pi \times \pi ')\) of the form
for some positive constants \(c_{\pi ,\pi '}, N_{\pi ,\pi '}\) dependent on \(\pi \) and \(\pi '\), provided that |t| is sufficiently large; their method applies not only to automorphic representations of \(\mathrm {GL}_n(\mathbb {A}_F)\) but to more general reductive groups.
In [3] and [18, Appendix], Brumley proves a more explicit zero-free region for \(L(s,\pi \times \pi ')\) that is also valid in the analytic conductor aspect and not just the t-aspect. For \(\pi ' \ncong \widetilde{\pi }\), this is of the form
together with the bound
for s in this zero-free region, while for \(\pi ' \cong \widetilde{\pi }\), this is of the form
together with the bound
for s in this zero-free region.
Recently, Goldfeld and Li [7] have given a strengthening in the t-aspect of a particular case of Brumley’s result, namely the case \(\pi ' \cong \widetilde{\pi }\) subject to the restriction that \(F = \mathbb {Q}\) and that \(\pi \) is unramified and tempered at every nonarchimedean place outside a set of Dirichlet density zero. With these assumptions, they prove the lower bound
for \(|t| \ge 1\), which gives a zero-free region of the form
for some positive constant \(c_{\pi }\) dependent on \(\pi \) provided that \(|t| \ge 1\). Their proof, like that of Gelbart and Lapid [5], makes use of Sarnak’s effectivization of the Langlands–Shahidi method; the chief difference is that, like Sarnak but unlike Gelbart and Lapid, they are able to use sieve theory to obtain a much stronger zero-free region. On the downside, the proof is extremely long and technical, and, being written in the classical language instead of the adèlic language, any generalisation of their method to arbitrary number fields and allowing ramification of \(\pi \) would be a challenging endeavour. (Indeed, the Langlands–Shahidi method, in practice, is rather inexplicit at ramified places, though see [11] for explicit calculations for the case \(n = 1\) and \(F = \mathbb {Q}\), so that \(\pi \) corresponds to a primitive Dirichlet character.)
In this article, we give a simple proof of the following.
Theorem 1.9
Let \(\pi \) be a unitary cuspidal automorphic representation of \(\mathrm {GL}_n(\mathbb {A}_F)\) that is tempered at every nonarchimedean place outside a set of Dirichlet density zero. Then there exists an absolute constant \(c_{\pi }\) dependent on \(\pi \) (and hence also on n and F) such that \(L(s,\pi \times \widetilde{\pi })\) has no zeroes in the region
with \(|t| \ge 1\). Furthermore, we have the bound
for s in this region.
In particular, we improve the zero-free region (1.8) and lower bound (1.7) of Goldfeld and Li to (1.10) and (1.11) respectively while removing Goldfeld and Li’s restriction that \(F = \mathbb {Q}\) and that \(\pi \) is unramified at every place. Nonetheless, we still require that \(\pi \) be tempered at every nonarchimedean place outside a set of Dirichlet density zero; moreover, this zero-free region is only in the t-aspect, unlike Brumley’s zero-free region in the analytic conductor aspect.
The proof of Theorem 1.9 shares some similarities with the method of de la Valleé–Poussin. Once again, one creates an auxiliary L-function, though this has a zero of equal order to the order of the pole at \(s = 1\). While Landau’s lemma cannot be used in this setting to obtain a standard zero-free region, one can instead use sieve theory. This approach is discussed in [26, Section 3.8] when \(L(s,\pi \times \widetilde{\pi })\) is the Riemann zeta function, so that \(F = \mathbb {Q}\) and \(\pi \) is trivial, and this method can also be adapted to prove a standard zero-free region in the q-aspect for \(L(s,\chi )\), where \(\chi \) is a primitive Dirichlet character; cf. [1, 11].
This usage of sieve theory, however, seems to have limitations; it is unclear how to prove zero-free regions via sieve theory for Rankin–Selberg L-functions \(L(s,\pi \times \pi ')\) with \(\pi ' \ncong \widetilde{\pi }\), even in the particular case \(\pi ' = 1\) and \(n \ge 2\), so that \(L(s,\pi \times \pi ')\) is the standard L-function \(L(s,\pi )\). We expand upon this point in Remark 3.5.
By slightly different means, we sketch how to prove a weaker version of Theorem 1.9.
Theorem 1.12
Let \(\pi \) be a unitary cuspidal automorphic representation of \(\mathrm {GL}_n(\mathbb {A}_F)\) that is tempered at every nonarchimedean place outside a set of Dirichlet density zero. Then for \(|t| \ge 1\), we have the bound
and so there exists an absolute constant \(c_{\pi }\) dependent on \(\pi \) such that \(L(s,\pi \times \widetilde{\pi })\) has no zeroes in the region
Though this is a weaker result than Theorem 1.9, the method of proof is of particular interest; it is essentially a generalisation from \(\mathrm {GL}_1(\mathbb {A}_{\mathbb {Q}})\) to \(\mathrm {GL}_n(\mathbb {A}_F)\) of the method of Balasubramanian and Ramachandra [1]. It turns out that Brumley’s method [3] in proving (1.6) is a natural generalisation of [1] except that sieve theory is not used and so the resulting lower bounds for \(L(1 + it,\pi \times \widetilde{\pi })\) are not nearly as strong.
Theorem 1.12 gives the same bounds as obtained by Goldfeld and Li, and this is no accident. Goldfeld and Li create an integral of an Eisenstein series and obtain upper bounds for this integral via the Maaß–Selberg relation together with upper bounds for \(L(1 + it, \pi \times \widetilde{\pi })\) and \(L'(1 + it, \pi \times \widetilde{\pi })\), while they use the Fourier expansion of the Eisenstein series together with sieve theory to find lower bounds for this integral. In the proof of Theorem 1.12, we follow Brumley’s method of studying a smoothed average of the Dirichlet coefficients of an auxiliary L-function. Upper bounds for this smoothed average are then obtained via Perron’s inversion formula and Cauchy’s residue theorem, in place of Goldfeld and Li’s usage of the Maaß–Selberg relation, together with upper bounds for \(L(1 + it, \pi \times \widetilde{\pi })\) and \(L'(1 + it, \pi \times \widetilde{\pi })\); lower bounds for this smoothed average stem once again from sieve theory.
2 Sieve theory
The L-function \(L(s,\pi )\) of \(\pi \) can be written as the Dirichlet series
for \(\mathfrak {R}(s)\) sufficiently large, where \({N(\mathfrak {a}) = N_{F/\mathbb {Q}}(\mathfrak {a}) :=\# \mathcal {O}_F / \mathfrak {a}}\), and extends to a meromorphic function on \(\mathbb {C}\) with at most a simple pole at \(s = 1\) if \(n = 1\) and \(\pi \) is trivial, so that \(L(s,\pi ) = \zeta _F(s)\). Similarly, the Rankin–Selberg L-function \(L(s,\pi \times \widetilde{\pi })\) is meromorphic on \(\mathbb {C}\) with only a simple pole at \(s = 1\). We denote by \(\Lambda _{\pi \times \widetilde{\pi }}(\mathfrak {a})\) the coefficients of the Dirichlet series for \(-\frac{L'}{L}(s,\pi \times \widetilde{\pi })\), so that
These coefficients are nonnegative; see [12, Remark, p. 138]. Moreover, the residue of this at \(s = 1\) is 1, and we have that
whenever \(\pi \) is unramified at \(\mathfrak {p}\).
We denote by \(S_{\pi }\) the set of places of F at which \(\pi \) is either ramified or nontempered.
Lemma 2.1
([7, Lemmata 12.12 and 12.15]) Suppose that \(\pi \) is tempered at every nonarchimedean place outside a set of Dirichlet density zero. For \(Y \gg _{\pi } (|t| + 3)^2\),
Proof
We use Ikehara’s Tauberian theorem and the fact that \(S_{\pi }\) has Dirichlet density zero to see that
The assumption that \(\pi \) is tempered at every nonarchimedean place outside a set of Dirichlet density zero implies that \(|\lambda _{\pi }(\mathfrak {p})| \le n\) whenever \(\mathfrak {p}\notin S_{\pi }\), so that for any \(C > 0\), the left-hand side of (2.2) is
and as
we ascertain that
Next, for \(C \in (0,2)\), we note that
for any integer m, and so via the bound \(|\sin x| \le |x|\), we have that
From [9, Proposition 2], we have that
for \(2 \le y \le x\), where \({\pi _F(x) :=\#\{N(\mathfrak {p}) \le x\}}\); the proof of this reduces to the case \(F = \mathbb {Q}\), in which case this is a well-known result that can be proven via the Selberg sieve (with the appearance of an additional error term) or the large sieve. So assuming that \(\frac{1}{2\sqrt{Y}} \le C \le \frac{|t| \log 2}{2}\) and \(Y > 4|t|^2\), the inner term on the right-hand side of (2.4) is bounded by
using the fact that \(\log (e^u + 1) \ge \log u\) and \(e^u - 1 \le 2u\) for \(u \in (0,1)\). Consequently,
Since
it follows that for \(Y \gg _F (|t| + 3)^2\),
By choosing C sufficiently small in terms of n and F, (2.3) and (2.5) imply that
from which the result follows. \(\square \)
Remark 2.6
The only point at which we make use of the assumption that \(\pi \) is tempered at every nonarchimedean place outside a set of Dirichlet density zero is in proving (2.3). It would be of interest whether an estimate akin to (2.3) could be proved unconditionally.
Remark 2.7
While the implicit constants in Theorems 1.9 and 1.12 depend on \(\pi \), much of the argument still works if we keep track of this dependence in terms of the analytic conductor of \(\pi \). The main issue seems to be the lower bound stemming from Lemma 2.1; in particular, the use of Ikehara’s Tauberian theorem to prove (2.2). We could instead use (1.6) together with an upper bound for \(L'(\sigma + it, \pi \times \widetilde{\pi })\) in the region (1.5) derived via the methods of Li [19] to prove (2.2) with an error term that is effective in terms of the analytic conductor of \(\pi \), but the payoff would not be great as the weaker zero-free region (1.5) would only give a weak error term.
3 Proof of Theorem 1.9
Let \(\pi \) and \(\pi '\) be unitary cuspidal automorphic representations of \(\mathrm {GL}_n(\mathbb {A}_F)\) and \(\mathrm {GL}_{n'}(\mathbb {A}_F)\) respectively. Let \(\rho = \beta + i\gamma \) be a nontrivial zero of \(L(s,\pi \times \pi ')\) with \(1/2 \le \beta < 1\) and \(\gamma \ne 0\). We define
This is an isobaric (noncuspidal) automorphic representation of \(\mathrm {GL}_{n + n'}(\mathbb {A}_F)\). The Rankin–Selberg L-function of \(\Pi \) and \(\widetilde{\Pi }\) factorises as
This is a meromorphic function on \(\mathbb {C}\) with a double pole at \(s = 1\), simple poles at \(s = 1 \pm i\gamma \) if \(\pi ' \cong \widetilde{\pi }\), and holomorphic elsewhere. We let \(\Lambda _{\Pi \times \widetilde{\Pi }}(\mathfrak {a})\) denote the coefficients of the Dirichlet series for \(-\frac{L'}{L}(s,\Pi \times \widetilde{\Pi })\), so that
Again, these coefficients are nonnegative.
Lemma 3.2
For \(\sigma > 1\),
Proof
By taking the real part of [12, (5.28)], we have that
for \(\sigma > 1\); cf. [12, (5.37)]. Similarly,
for \(\sigma > 1\) via [12, (5.37)], using the fact that \(\Lambda _{\pi \times \widetilde{\pi }}(\mathfrak {a})\) and \(\Lambda _{\pi ' \times \widetilde{\pi }'}(\mathfrak {a})\) are real. \(\square \)
Lemma 3.3
Suppose that \(\pi \) and \(\pi '\) are unramified at \(\mathfrak {p}\). Then
Proof
Indeed, (3.1) implies that
and
whenever \(\pi \) and \(\pi '\) are unramified at \(\mathfrak {p}\). \(\square \)
Now let us restrict to the case \(\pi ' = \widetilde{\pi }\).
Corollary 3.4
Suppose that \(\pi \) is tempered at every nonarchimedean place outside a set of Dirichlet density zero. Then for \(\sigma > 1\),
Proof
We have that
by dividing into dyadic intervals and applying Lemma 2.1.
Proof of Theorem 1.9
By combining Lemma 3.2 and Corollary 3.4 and choosing \(\sigma = 1 + c/\log (|\gamma | + 3)\), we find that
which gives the zero-free region (1.10). Now using [12, (5.28)], we find in the region
away from \(t = 0\), we have that
Next, we note that
for \(\mathfrak {R}(s) > 1\). So
Since \(L(s,\pi \times \widetilde{\pi })\) has a simple pole at \(s = 1\),
In particular, in the region
we have that
Now suppose that \(s = \sigma + it\) with
Then \(\log L(s, \pi \times \widetilde{\pi })\) is equal to
so again
Finally, we note that
which is equivalent to (1.11). \(\square \)
Remark 3.5
To prove Theorem 1.9 for \(L(s,\pi \times \pi ')\) with \(\pi ' \ncong \widetilde{\pi }\), we would need to replace Lemma 2.1 with a result of the form
but it is unclear how one might generalise the proof of Lemma 2.1 to obtain such a result.
4 Proof of Theorem 1.12
For \(t \in \mathbb {R}{\setminus } \{0\}\), define the isobaric automorphic representation \(\Pi \) of \(\mathrm {GL}_{n + n'}(\mathbb {A}_F)\) by
Then
This is a meromorphic function on \(\mathbb {C}\) with a double pole at \(s = 1\), simple poles at \(s = 1 \pm it\) if \(\pi ' \cong \widetilde{\pi }\), and holomorphic elsewhere.
We let \(\lambda _{\Pi \times \widetilde{\Pi }}(\mathfrak {a})\) denote the coefficients of the Dirichlet series for \(L(s,\Pi \times \widetilde{\Pi })\), so that
Again, the coefficients \(\lambda _{\Pi \times \widetilde{\Pi }}(\mathfrak {a})\) are nonnegative. Write
for s near 1 and
for s near \(1 \pm it\). Finally, we write
for s near 1.
Lemma 4.2
We have that
Similarly,
Proof
This follows from the factorisation \(L(s,\pi \times \widetilde{\pi }) = \zeta _F(s) L(s, {{\mathrm{ad}}}\pi )\). \(\square \)
Lemma 4.3
([7, Lemma 5.1]) We have that
Proof
This is proved by Goldfeld and Li in [7, Lemma 5.1] for \(F = \mathbb {Q}\) and \(\pi ' \cong \widetilde{\pi }\), but the proof in this more generalised setting (via the approximate functional equation) follows mutatis mutandis. \(\square \)
Together with the fact that \(L(1,{{\mathrm{ad}}}\pi ) \ne 0\), this shows the following.
Corollary 4.4
We have that
Now let \(\psi \in C^{\infty }_c(0,\infty )\) be a fixed nonnegative function satisfying \(\psi (x) = 1\) for \(x \in [1,2]\) and \(\psi (0) = 0\). The Mellin transform of \(\psi \) is
which is entire with rapid decay in vertical strips. Define
We let \(\mathfrak {q}(\Pi \times \widetilde{\Pi })\) denotes the analytic conductor of \(\Pi \times \widetilde{\Pi }\); from [12, (5.11)], we have that
On the other hand, it is easily seen that
Remark 4.6
While (4.5) is stated in [12, (5.11)], a complete proof does not seem to have appeared in the literature. In the appendix to this article, a proof of (a more general version of) this statement is given.
Lemma 4.7
(Cf. [3, Proof of Theorem 3]) For \(Y \ge \mathfrak {q}(\Pi \times \widetilde{\Pi })\), there exists \(\delta > 0\) such that
Proof
Indeed,
for \(\sigma > 1\), and moving the contour to the left shows that
for any \(\sigma < 1\). The convexity bound of Li [19] and the rapid decay of \(\widehat{\psi }\) in vertical strips imply that
from which the result follows. \(\square \)
In [3, 18], Brumley notes that
and that \(\lambda _{\Pi \times \widetilde{\Pi }}(\mathfrak {a}^{2n}) \ge 1\). This is paired with a modified version of Lemma 4.7 in order to prove effective lower bounds for \(\left| L(1 + it, \pi \times \widetilde{\pi })\right| \) in terms of the analytic conductor \(\mathfrak {q}(\pi \times \widetilde{\pi }, 1 + it)\). Instead of restricting the sum over integral ideals to those that are 2n-powers and using the fact that \(\lambda _{\Pi \times \widetilde{\Pi }}(\mathfrak {a}^{2n}) \ge 1\), our approach is to restrict to prime ideals at which \(\pi \) is unramified and tempered and use sieve theory to show that \(\lambda _{\Pi \times \widetilde{\Pi }}(\mathfrak {p})\) is often not too small on dyadic intervals.
Lemma 4.8
Suppose that \(\pi \) and \(\pi '\) are unramified at \(\mathfrak {p}\). Then
Proof
This follows via the same method as the proof of Lemma 3.3. \(\square \)
We now restrict to the case \(\pi ' = \widetilde{\pi }\).
Proof of Theorem 1.12
From Lemma 4.7 and Corollary 4.4, we have that for \(Y \ge \mathfrak {q}(\Pi \times \widetilde{\Pi })\), there exists \(\delta > 0\) such that
On the other hand, Lemmata 4.8 and 2.1 imply that for \(Y \gg _{\pi } (|t| + 3)^2\),
This gives the lower bound (1.13). Then as in [7, Proof of Theorem 1.2], (1.14) follows via the mean value theorem. \(\square \)
Notes
I would like thank Philippe Michel and Étienne Fouvry for suggesting that I write up a proof of Theorem A.1. I am grateful as well to Peter Humphries for allowing me to include this appendix to his paper, and for suggesting many improvements to the proofs and exposition.
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Acknowledgements
The author would like to thank Peter Sarnak, Dorian Goldfeld, and Farrell Brumley for helpful discussions and comments, as well as Dimitris Koukoulopoulos for alerting the author to an error in an earlier version of this article.
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Research supported by the European Research Council grant agreement 670239.
With an appendix by Farrell Brumley.
Appendix A. Standard zero-free regions when at least one factor is self-dual, (by Farrell Brumley)
Supported by ANR grant 14-CE25.
Appendix A. Standard zero-free regions when at least one factor is self-dual, (by Farrell Brumley)
The aim of this appendix is to provide a proof of the claim, stated in Gelbart–Lapid–Sarnak [6, p. 92] and Gelbart–Lapid [5, p. 619], that Rankin–Selberg L-functions are known to satisfy a standard zero-free region whenever at least one of the forms is self-dual. This is Theorem A.1 below. The method is through the classical argument of de la Vallée–Poussin. We take advantage of the occasion to clarify parts of the literature, and to justify, in Lemma A.2, another oft claimed inequality on the archimedean conductor.Footnote 2
Theorem A.1
Let \(n,n'\ge 1\). Let F be a number field. Let \(\pi \) and \(\pi '\) be unitary cuspidal automorphic representations of \(\mathrm {GL}_{n}(\mathbb {A}_F)\) and \(\mathrm {GL}_{n'}(\mathbb {A}_F)\), respectively. We normalize \(\pi \) and \(\pi '\) so that their central characters are trivial on the diagonally embedded copy of the positive reals. Assume that \(\pi '\) is self-dual.
There is an effective absolute constant \(c>0\) such that \(L(s,\pi \times \pi ')\) is non-vanishing for all \(s=\sigma +it\in \mathbb {C}\) verifying
with the possible exception of one real zero whenever \(\pi \) is also self-dual.
Remark A.1
In [22] it is shown that when \(n=n'=2\), \(L(s,\pi \times \pi ')\) satisfies the conclusions of Theorem A.1, except possibly when it is divisible by the L-function of a quadratic character. A similar result holds for \(n=n'=3\) when \(\pi \) and \(\pi '\) are symmetric square lifts from self-dual forms on \(\mathrm {GL}_2\).
Remark A.2
Theorem A.1 implies a standard zero-free region for the L-function of a non-self dual cusp form \(\pi \) on \(\mathrm {GL}_n\), by taking \(\pi '\) to be the trivial character on \(\mathrm {GL}_1\). The fact that \(L(s,\pi )\) admits no exceptional zeros whenever \(\pi \) is not self-dual is originally due to Moreno [20, Theorem 5.1] when \(n=2\) and Hoffstein–Ramakrishnan [10, Corollary 3.2] for \(n\ge 3\). (For complex characters it is classical.)
Remark A.3
If \(\pi \) is self-dual on \(\mathrm {GL}_n\), then Theorem A.1 allows for the possibility of a single exceptional zero, necessarily real, of \(L(s,\pi )\). There are cases when this exceptional zero can be provably eliminated. To the best of our knowledge, these cases are, at the time of this writing, limited to the following situations:
-
(1)
when \(\pi \) is a cusp form on \(\mathrm {GL}_2\), due to Hoffstein–Ramakrishnan [10, Theorem C];
-
(2)
when \(\pi \) is a cusp form on \(\mathrm {GL}_3\). This is due to Banks [2, Theorem 1], who verifies Hypothesis 6.1 in [10].
-
(3)
when \(\pi \) is a cusp form on \(\mathrm {GL}_5\) which arises as the symmetric fourth power lift of a cusp form on \(\mathrm {GL}_2\) which is not of solvable polynomial type. This is due to Ramakrishnan-Wang [22]; see the comments after Corollary C in loc cit.;
-
(4)
for the L-functions \(L(s,\pi ,{\mathrm{sym}}^6)\) and \(L(s,\pi ,{\mathrm{sym}}^8)\), when \(\pi \) is a self-dual cusp from on \(\mathrm {GL}_2\). This is Theorem D in [22].
All of these results build on the groundbreaking work of [8]. Moreover, cases (3) and (4) make full use of the advances in functoriality by Kim and Shahidi [15, 16].
Remark A.4
We emphasize the importance of the cuspidality condition in (1) and (2) in the above remark, which rules out the divisibility of \(L(s,\pi )\) by the L-function of a quadratic character.
For example, if \(\pi \) is a dihedral form on \(\mathrm {GL}_2\) over F, induced by a Hecke character \(\chi \) of a quadratic field extension E, then \(L(s,\pi )=L(s,\chi )\). Now if \(\pi \) is cuspidal, \(\chi \) does not factor through the norm, which (as was remarked in [22]) rules out \(\chi \) real. One can then obtain a standard zero-free region for \(\pi \) by appealing to the classical \(\mathrm {GL}_1\) case for complex (Hecke) characters over E. The original argument given in [10, Theorem B and Remark 4.3] for dihedral forms on \(\mathrm {GL}_2\) is, on the surface, more complicated, but this is simply due to to the more general framework in which it is set.
Similarly, the cuspidality condition for \(\mathrm {GL}_3\) rules out the possibility that \(\pi \) arises as the symmetric square lift of a dihedral form on \(\mathrm {GL}_2\).
All of the above remarks pertain to results in the full conductor aspect only; for the t-aspect, we refer to the body of the paper.
Proof
For \(t\in \mathbb {R}\) let
and \(D(s)=L(s,\Pi \times \widetilde{\Pi })\). Then we have the factorization \(D(s)=L_1(s)L_2(s)\), where
and
Let \(m\ge 1\) be the order of the pole of D(s) at \(s=1\). Then [12, Theorem 5.9] (which is based on [8, Lemma]) states that there is a constant \(\kappa >0\) such that D(s) has no more than m real zeros in the interval
Let us calculate the integer m. The factor \(L_1(s)\) has a pole of order 3 at \(s=1\). Moreover, if \(t\ne 0\) the factor \(L_2(s)\) is holomorphic at \(s=1\). When \(t=0\), the regularity of \(L_2(s)\) at \(s=1\) depends on whether or not \(\pi \) is self-dual:
-
(1)
if \(\pi \) is not self-dual and \(t=0\), the function \(L_2(s)\) is holomorphic at \(s=1\), since necessarily \(\pi \ne \pi '\) and \(\pi \ne \widetilde{\pi }'\);
-
(2)
if \(\pi \) is self-dual and \(t=0\), the function \(L_2(s)\) has a pole of order 2 or 4, according to whether \(\pi \ne \pi '\) or \(\pi =\pi '\).
We deduce that \(m=3\) when either \(\pi \) is not self-dual or \(t\ne 0\). When \(\pi \) is self-dual and \(t=0\), we have \(m=5\) or 7, according to whether \(\pi \ne \pi '\) or \(\pi =\pi '\).
Now let \(\sigma \in (0,1)\) and suppose that \(L(s,\pi \times \pi ')\) vanishes to order r at \(s=\sigma +it\). By the functional equation and the self-duality of \(\pi '\), this is equivalent to \(L(\sigma -it,\widetilde{\pi }\times \pi ')\) vanishing to order r at \(s=\sigma -it\). From this it follows that \(L_2(s)\), and hence D(s), has a zero at \(s=\sigma \) of order 4r. Moreover, this is the case regardless of the value of t or whether \(\pi \) is self-dual. If \(\sigma \) lies in the range (A.5), then since \(4r\le m\), we deduce from the previous paragraph that \(r=0\) whenever \(\pi \) is not self-dual or \(t\ne 0\), and \(r\le 1\) whenever \(\pi \) is self-dual and \(t=0\).
To finish the argument we must now majorize \(\log \mathfrak {q}(\Pi \times \widetilde{\Pi })\). Corresponding to the factorization of D(s) we have
The bounds of [4, Theorem 1], applied to the finite conductor of each factor above, yield
For the archimedean conductor, Lemma A.2 below implies that
for an absolute constant \(C_1>0\). This yields
for an absolute constant \(C_2>0\), which finishes the proof. \(\square \)
The following result — the analog at archimedean places of the Bushnell–Henniart bounds (A.6) on the Rankin–Selberg conductor — has been claimed without proof in many sources, including [12, (5.11)] and our own [3] (to name just two). Nevertheless, there does not seem an available proof in the literature.
Lemma A.2
Let \(F_v\) be \(\mathbb {R}\) or \(\mathbb {C}\). Let \(n,n'\ge 1\) be integers. Let \(\pi _v\) and \(\pi _v'\) be irreducible unitary generic representations of \(\mathrm {GL}_n(F_v)\) and \(\mathrm {GL}_{n'}(F_v)\), respectively. There is an absolute constant \(C>0\) such that
Remark A.8
The constant C in Lemma A.2 can be explicitly computed, and the proof gives an exact value. But since the archimedean conductor should not be considered an “exact quantity” (and conventions for the definition vary according to the source), it makes little sense to include the precise value of C in the estimate.
Remark A.9
In the course of the proof, we shall recall the definition of the archimedean Rankin–Selberg and standard analytic conductor as given by Iwaniec–Sarnak in [13]. Their ad hoc recipe boils down to taking the product over all Gamma shifts arising in the local L-factors. It will be apparent that the definition of \(\mathfrak {q}_v(it;\pi \times \pi ')\) can be made in the admissible (rather than unitary generic) dual. One may drop the hypothesis of genericity (but not unitarity) in the statement of Lemma A.2 at the price of allowing the constant C to depend linearly on n and \(n'\).
Remark A.10
In [10, Lemma b], the authors prove something close to Lemma A.2, but their result only yields an upper bound of the form
for some constants \(B,C>0\), depending on n and \(n'\). Indeed, the archimedean factor of the “thickened level” \(M(\pi )\) introduced in [loc. cit., Definition 1.4], is defined using the sum, rather than the product, of all Gamma shifts. (Note that in [8] the max of the Gamma shifts is taken.) Thus \(M_v(\pi )\), for \(v\mid \infty \), behaves quantitatively much differently than the archimedean factor of the analytic conductor of Iwaniec–Sarnak [13]. Since its appearance, the latter has become the preferred measure of complexity in the study of L-functions.
It should be emphasized that since
the bounds (A.7) with unspecified exponents are consequences of the work of Hoffstein–Ramakrishnan. Thus the proof of Lemma A.1 can be made to be independent of Lemma A.2, at the price of an inexplicit dependence in the implied constant on n and \(n'\).
In any case, the proof of Lemma A.2 is closely modelled on that of [10, Lemma b], with the appropriate modifications for dealing with analytic conductor.
Proof
Using Langlands’ classification of the admissible dual of \(\mathrm {GL}_n(F_v)\) (see, for example, [17]), \(\pi _v\) and \(\pi _v'\) correspond to \(\oplus \varphi _i\) and \(\oplus \varphi _j'\), for irreducible representations \(\varphi _i\) and \(\varphi _j'\) of the Weil group \(W_{F_v}\) of \(F_v\). By definition, we have
which gives rise to similar factorizations of the associated conductors. Let \(d_i,d_j'\) denote the dimensions of \(\varphi _i\) and \(\varphi _j'\), respectively, so that \(n=\sum d_i\) and \(n'=\sum d_j'\). Dropping the indices i and j, we must therefore prove that for irreducible representations \(\varphi \) and \(\varphi '\) of \(W_{F_v}\), of respective dimensions d and \(d'\), we have
for an absolute constant \(C>0\).
When \(F_v=\mathbb {C}\), one has \(W_\mathbb {C}=\mathbb {C}^\times \), so that all irreducible representations are one-dimensional. We may write any such character as \(\chi _{k,\nu }(z)=(z/|z|)^k|z|^{2\nu }\), for \(k\in \mathbb {Z}\) and \(\nu \in \mathbb {C}\). Letting \(\mu =\nu +|k|/2\), the associated L-factor (see [17, (4.6)]) is \(\Gamma _\mathbb {C}(s+\mu )\). The recipe of Iwaniec–Sarnak [13, (21) and (31)] gives
Now if \(\varphi =\chi _{k,\nu }\) and \(\varphi '=\chi _{k',\nu '}\), then \(\varphi \otimes \varphi '=\chi _{k+k',\nu +\nu '}\). This implies that
An application of the triangle inequality yields
We claim that \(\frac{|k|}{2}+|\nu |\ll |\frac{|k|}{2}+\nu |=|\mu |\). We may assume that \(k\ne 0\). On one hand,
On the other, since \(\pi \) and \(\pi '\) are unitary generic, the Jacquet–Shalika bounds \(|\mathrm{Re}(\nu )|\le 1/2\) [14, Corollary 2.5] (extended to the archimedean places by Rudnick–Sarnak in [23, §A.3]) imply
This proves the claim and implies \(\mathfrak {q}_v(it;\varphi \otimes \varphi ')\ll (1+|t|+|\mu |+|\mu '|)^2\). Using
we establish (A.12) in the case \(F_v=\mathbb {C}\).
When \(F_v=\mathbb {R}\), each irreducible representation \(\varphi \) of \(W_\mathbb {R}=\mathbb {C}^\times \cup j\mathbb {C}^\times \) is of dimension 1 or 2. If \(\varphi \) is one-dimensional, then its restriction to \(\mathbb {C}^\times \) is \(\chi _{0,\nu }\) for \(\nu \in \mathbb {C}\) (see [17, (3.2)]). We let \(k=1-\varphi (j)\in \{0,2\}\). Writing \(\mu =\nu +k/2\), we have \(L(s,\varphi )=\Gamma _\mathbb {R}(s+\mu )\) and
If \(\varphi \) is two-dimensional, then it is the induction of \(\chi _{k,\nu }\) from \(\mathbb {C}^\times \) to \(\mathrm {GL}_2(\mathbb {R})\), where \(k\ge 1\) and \(\nu \in \mathbb {C}\). Putting \(\mu =\nu +k/2\) we have \(L(s,\varphi )=\Gamma _\mathbb {C}(s+\mu )\) and
In either case, let \((k,\nu )\) and \((k',\nu ')\) be the parameters associated with \(\varphi \) and \(\varphi '\), respectively. We now examine the tensor products parameters.
-
(1)
If both \(\varphi \) and \(\varphi '\) are one-dimensional, then so is \(\varphi \otimes \varphi '\), with parameter \((1-\varphi (j)\varphi '(j),\nu +\nu ')\). Then (A.12) reads
$$\begin{aligned} 1+\bigg |it+\frac{1-\varphi (j)\varphi '(j)}{2}+\nu +\nu '\bigg |\le C(1+|\mu |)(1+|\mu '|)(1+|t|). \end{aligned}$$Applying the triangle inequality and \(1-\varphi (j)\varphi '(j)\le (1-\varphi (j))+(1-\varphi '(j))=k+k'\), the left-hand side is bounded above by
$$\begin{aligned} 1+|t|+\left( \frac{k}{2}+|\nu |\right) +\left( \frac{k'}{2}+|\nu '|\right) . \end{aligned}$$The same reasoning as in the complex case then establishes (A.12).
-
(2)
If \(\varphi \) is one-dimensional, and \(\varphi '\) is irreducible and two-dimensional, then the twist \(\varphi \otimes \varphi '\) is irreducible and two-dimensional, induced from \(\mathbb {C}^\times \) by the character \(\chi _{0,\nu }\chi _{k',\nu '}=\chi _{k',\nu +\nu '}\). Thus \(\varphi \otimes \varphi '\) has parameters \((k',\nu +\nu ')\). Inequality (A.12) is then equivalent to
$$\begin{aligned} 1+|it+\mu +\mu '|\le C(1+|\mu |)(1+|\mu '|)(1+|t|). \end{aligned}$$This follows (with \(C=1\)) from the triangle inequality and (A.13).
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(3)
Suppose that \(\varphi \) and \(\varphi '\) are both irreducible and two-dimensional, and let \(k\ge k'\). Then \(\varphi \otimes \varphi '\) is the direct sum of two two-dimensional representations, induced from \(\mathbb {C}^\times \) from the characters \(\chi _{k,\nu }\chi _{k',\nu '}=\chi _{k+k',\nu +\nu '}\) and \(\chi _{-k,-\nu }\chi _{k',\nu '}=\chi _{k'-k,\nu '-\nu }\). (Note that the latter representation is reducible when \(k=k'\).) This shows that
$$\begin{aligned} L(s,\varphi \otimes \varphi ')=\Gamma _\mathbb {C}(s+\mu +\mu ')\Gamma _\mathbb {C}(s+\mu -\mu ') \end{aligned}$$and
$$\begin{aligned} \mathfrak {q}_v(it;\varphi \otimes \varphi ')=(1+|\mu +\mu '|)^2(1+|\mu -\mu '|)^2. \end{aligned}$$Then (A.12) is equivalent to
$$\begin{aligned} (1+|it+\mu +\mu '|)(1+|it+\mu -\mu '|)\le C(1+|\mu |)^2(1+|\mu '|)^2(1+|t|)^2. \end{aligned}$$This follows (with \(C=1\)) from applying the triangle inequality and (A.13) to each factor on the left-hand side.
This completes the proof of Lemma A.2. \(\square \)
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Humphries, P., Brumley, F. Standard zero-free regions for Rankin–Selberg L-functions via sieve theory. Math. Z. 292, 1105–1122 (2019). https://doi.org/10.1007/s00209-018-2136-8
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DOI: https://doi.org/10.1007/s00209-018-2136-8