Standard zero-free regions for Rankin–Selberg L-functions via sieve theory

Abstract: We give a simple proof of a standard zero-free region in the t-aspect for the Rankin-Selberg L-function L(s, π × π) for any unitary cuspidal automorphic representation π of GL n (A F ) that is tempered at every nonarchimedean place outside a set of Dirichlet density zero.

“…Given π ∈ F n and π ′ ∈ F n ′ , let L(s, π × π ′ ) be the associated Rankin-Selberg L-function, and let π ∈ F n and π ′ ∈ F n ′ be the contragredient representations. When π ′ ∈ { π, π ′ }, work of Brumley [29,Appendix] and the authors [30] shows that there exists an absolute and effectively computable constant c 1 > 0 such that L(s, π × π ′ ) has a "standard" zero-free region of the shape…”

“…If π ′ ∈ { π, π ′ }, then L(s, π × π ′ ) has the standard zero-free region (1.1) apart from a possible Landau-Siegel zero, which must be both real and simple. In all other cases, it follows from work of Brumley (see [8], [29,Section 1], and [41,Appendix]) that there exists an absolute and effectively computable constant c 2 > 0 such that L(s, π × π ′ ) = 0 in the much narrower region (2.1) Re(s)…”

Zeros of Rankin-Selberg $L$-functions in families

“…Given π ∈ F n and π ′ ∈ F n ′ , let L(s, π × π ′ ) be the associated Rankin-Selberg L-function, and let π ∈ F n and π ′ ∈ F n ′ be the contragredient representations. When π ′ ∈ { π, π ′ }, work of Brumley [29,Appendix] and the authors [30] shows that there exists an absolute and effectively computable constant c 1 > 0 such that L(s, π × π ′ ) has a "standard" zero-free region of the shape…”

“…If π ′ ∈ { π, π ′ }, then L(s, π × π ′ ) has the standard zero-free region (1.1) apart from a possible Landau-Siegel zero, which must be both real and simple. In all other cases, it follows from work of Brumley (see [8], [29,Section 1], and [41,Appendix]) that there exists an absolute and effectively computable constant c 2 > 0 such that L(s, π × π ′ ) = 0 in the much narrower region (2.1) Re(s)…”

Zeros of Rankin-Selberg $L$-functions in families

“…and by the bounds for 1 ( ), 2 ( ) given in (7.0.12), P 2,2 ,Φ ( , 1, 1), = Note that the bound for the case that |Im( 1 )| is small involves the non-existence of Siegel zeros that is proved in [HR95] while the case when |Im( 1 )| is large was first proved in [Mor85]. See also [GL18], [HB19]. Applying these bounds, the Theorem 7.0.3 bound, together with Stirling's bound to estimate the integral in 1 , we find, as claimed, that…”

An orthogonality relation for (with an appendix by Bingrong Huang)

“…Such a uniform bound is known to be a consequence of the Rankin–Selberg theory. However, it is apparent that the first proof of this fact in the literature is given by Brumley [, Lemma A.2]. Also, we do require the bound of the Rankin–Selberg conductors established by Bushnell and Henniart .…”

“…To end this section, we further remark that the prime number theorem and log‐free zero‐density estimates for automorphic L‐functions have been studied in . Moreover, it is possible to obtain the error terms for the above estimates by invoking the zero‐free regions of the Rankin–Selberg L‐functions (see, e.g., ).…”

Bombieri–vinogradov Theorems for Modular Forms and Applications