西格爾零點

The way in which Siegel zeros appear in the theory of Dirichlet L-functions is as potential exceptions to the classical zero-free regions（英語：Dirichlet L-function#Zeros）, which can only occur when the L-function is associated to a real Dirichlet character.

For an integer q ≥ 1, a Dirichlet character modulo q is an arithmetic function（英語：arithmetic function） ${\textstyle \chi :\mathbb {Z} \to \mathbb {C} }$  satisfying the following properties:

• (Completely multiplicative（英語：Completely multiplicative function）) ${\textstyle \chi (mn)=\chi (m)\chi (n)}$  for every m, n;
• (Periodic) ${\textstyle \chi (n+q)=\chi (n)}$  for every n;
• (Support) ${\textstyle \chi (n)=0}$  if ${\displaystyle \mathrm {gcd} (n,q)>1}$ .

That is, χ is the lifting of a homomorphism（英語：homomorphism） ${\textstyle {\widetilde {\chi }}:(\mathbb {Z} /q\mathbb {Z} )^{\times }\to \mathbb {C} ^{*}}$ .

The trivial character is the character modulo 1, and the principal character modulo q, denoted ${\textstyle \chi _{0}~(\mathrm {mod} ~q)}$ , is the lifting of the trivial homomorphism ${\textstyle (\mathbb {Z} /q\mathbb {Z} )^{\times }\ni a\mapsto 1\in \mathbb {C} ^{*}}$ .

A character ${\textstyle \chi ~(\mathrm {mod} ~{q})}$  is called imprimitive if there exists some integer ${\textstyle d\neq q}$  with ${\textstyle d\mid q}$  such that the induced homomorphism ${\textstyle {\widetilde {\chi }}:(\mathbb {Z} /q\mathbb {Z} )^{\times }\to \mathbb {C} ^{*}}$  factors as

${\displaystyle (\mathbb {Z} /q\mathbb {Z} )^{\times }\twoheadrightarrow (\mathbb {Z} /d\mathbb {Z} )^{\times }\xrightarrow {\widetilde {\chi '}} \mathbb {C} ^{*}}$ 

for some character ${\textstyle \chi '~(\mathrm {mod} ~{d})}$ ; otherwise, ${\textstyle \chi ~(\mathrm {mod} ~{q})}$  is called primitive.

A character ${\textstyle \chi }$  is real (or quadratic) if it equals its complex conjugate（英語：complex conjugate） ${\displaystyle {\overline {\chi }}}$  (defined as ${\displaystyle {\overline {\chi }}(n):={\overline {\chi (n)}}}$ ), or equivalently if ${\textstyle \chi ^{2}=\chi _{0}}$ . The real primitive Dirichlet characters are in one-to-one correspondence with the 克羅內克符號s ${\textstyle (D|\,\cdot \,):\mathbb {Z} \to \{-1,0,1\}}$  for ${\textstyle D\in \mathbb {Z} }$  a fundamental discriminant（英語：fundamental discriminant） (i.e., the discriminant of a quadratic number field（英語：quadratic number field）).^[2] One way to define ${\textstyle (D|\,\cdot \,)}$  is as the completely multiplicative arithmetic function determined by (for p prime):

${\displaystyle {\bigg (}{\frac {D}{p}}{\bigg )}={\begin{cases}1,&(p){\text{ splits in }}\mathbb {Q} ({\sqrt {D}}),\\-1,&(p){\text{ is inert }}\cdots ,\\0,&(p){\text{ ramifies }}\cdots ,\end{cases}}\quad {\bigg (}{\frac {D}{-1}}{\bigg )}={\text{sign of }}D.}$ 

It is thus common to write ${\textstyle \chi _{D}:=(D|\,\cdot \,)}$ , which are real primitive characters modulo ${\textstyle |D|}$ .

The Dirichlet L-function associated to a character ${\textstyle \chi ~(\mathrm {mod} ~q)}$  is defined as the analytic continuation（英語：analytic continuation） of the 狄利克雷級數 ${\textstyle L(s,\chi )=\sum _{n\geq 1}\chi (n)n^{-s}}$  defined for ${\textstyle \mathrm {Re} (s)>1}$ , where s is a complex variable（英語：complex variable）. For ${\displaystyle \chi }$  non-principal, this continuation is entire（英語：Entire function）; otherwise it has a simple pole（英語：Zeros and poles） of residue（英語：Residue (complex analysis)） ${\textstyle \prod _{p\mid q}(1-p^{-1})}$  at s = 1 as its only singularity. For ${\textstyle \mathrm {Re} (s)>1}$ , Dirichlet L-functions can be expanded into an 歐拉乘積 ${\textstyle L(s,\chi )=\prod _{p}(1-\chi (p)p^{-s})^{-1}}$ , from where it follows that ${\textstyle L(s,\chi )}$  has no zeros in this region. The prime number theorem for arithmetic progressions（英語：Prime number theorem#Prime number theorem for arithmetic progressions） is equivalent (in a certain sense) to ${\textstyle L(1+it,\chi )\neq 0}$  (${\textstyle \forall t\in \mathbb {R} }$ ). Moreover, via the functional equation（英語：Dirichlet L-function#Functional equation）, we can reflect these regions through ${\textstyle s\mapsto 1-s}$  to conclude that, with the exception of negative integers of same parity as χ,^[3] all the other zeros of ${\textstyle L(s,\chi )}$  must lie inside ${\displaystyle \{0<\mathrm {Re} (s)<1\}}$ . This region is called the critical strip, and zeros in this region are called non-trivial zeros.

The classical theorem on zero-free regions (Grönwall,^[4] Landau,^[5] Titchmarsh^[6]) states that there exists a(n) (effectively computable) real number ${\textstyle A>0}$  such that, writing ${\displaystyle s=\sigma +it}$  for the complex variable, the function ${\textstyle L(s,\chi )}$  has no zeros in the region

${\displaystyle \sigma >1-{\frac {A}{(\log q(|t|+2))}}}$ 

if ${\textstyle \chi ~(\mathrm {mod} ~q)}$  is non-real. If ${\textstyle \chi }$  is real, then there is at most one zero in this region, which must necessarily be real and simple. This possible zero is the so-called Siegel zero.

The Generalized Riemann Hypothesis（英語：Generalized Riemann Hypothesis） (GRH) claims that for every ${\textstyle \chi ~(\mathrm {mod} ~q)}$ , all the non-trivial zeros of ${\textstyle L(s,\chi )}$  lie on the line ${\textstyle \mathrm {Re} (s)={\frac {1}{2}}}$ .

The definition of Siegel zeros as presented ties it to the constant A in the zero-free region. This often makes it tricky to deal with these objects, since in many situations the particular value of the constant A is of little concern.^[1] Hence, it is usual to work with more definite statements, either asserting or denying, the existence of an infinite family of such zeros, such as in:

• Conjecture ("no Siegel zeros"): If ${\textstyle \beta _{D}}$  denotes the largest real zero of ${\textstyle L(s,\chi _{D})}$ , then ${\displaystyle 1-\beta _{D}\gg {\frac {1}{\log |D|}}.}$ 

The possibility of existence or non-existence of Siegel zeros has a large impact in closely related subjects of number theory, with the "no Siegel zeros" conjecture serving as a weaker (although powerful, and sometimes fully sufficient) substitute for GRH (see below for an example involving Siegel–Tatuzawa's Theorem and the idoneal number（英語：idoneal number） problem). An equivalent formulation of "no Siegel zeros" that does not reference zeros explicitly is the statement:

${\displaystyle {\frac {L'}{L}}(1,\chi _{D})=O(\log |D|).}$ 

The equivalence can be deduced for example by using the zero-free regions and classical estimates for the number of non-trivial zeros of ${\textstyle L(s,\chi )}$  up to a certain height.^[7]

The first breakthrough in dealing with these zeros came from Landau, who showed that there exists an effectively computable constant B > 0 such that, for any ${\textstyle \chi _{D}}$  and ${\textstyle \chi _{D'}}$  real primitive characters to distinct moduli, if ${\textstyle \beta ,\beta '}$  are real zeros of ${\textstyle L(s,\chi _{D}),L(s,\chi _{D'})}$  respectively, then

${\displaystyle \min\{\beta ,\beta '\}<1-{\frac {B}{\log |DD'|}}.}$ 

This is saying that, if Siegel zeros exist, then they cannot be too numerous. The way this is proved is via a 'twisting' argument, which lifts the problem to the Dedekind zeta function（英語：Dedekind zeta function） of the biquadratic field（英語：biquadratic field） ${\textstyle \mathbb {Q} ({\sqrt {D}},{\sqrt {D'}})}$ . This technique is still largely applied in modern works.

This 'repelling effect' (see Deuring–Heilbronn phenomenon（英語：Deuring–Heilbronn phenomenon）), after more careful analysis, led Landau to his 1936 theorem,^[8] which states that for every ${\textstyle \varepsilon >0}$ , there is ${\textstyle C(\varepsilon )\in \mathbb {R} _{+}}$  such that, if ${\textstyle \beta }$  is a real zero of ${\textstyle L(s,\chi _{D})}$ , then ${\textstyle \beta <1-C(\varepsilon )|D|^{-{\frac {3}{8}}-\varepsilon }}$ . However, in the same year, in the same issue of the same journal, Siegel^[9] directly improved this estimate to

${\displaystyle \beta <1-C(\varepsilon )|D|^{-\varepsilon }.}$ 

Both Landau's and Siegel's proofs provide no explicit way to calculate ${\textstyle C(\varepsilon )\in \mathbb {R} _{+}}$ , thus being instances of an ineffective result（英語：Effective results in number theory）.

In 1951, T. Tatuzawa（英語：Tikao Tatsuzawa） proved an 'almost' effective version of Siegel's theorem,^[10] showing that for any fixed ${\textstyle 0<\varepsilon <{\frac {1}{11.2}}}$ , if ${\textstyle |D|>e^{1/\varepsilon }}$  then

${\displaystyle L(1,\chi _{D})>0.655|D|^{-\varepsilon },}$ 

with the possible exception of at most one fundamental discriminant. Using the 'almost effectivity' of this result, P. J. Weinberger（英語：Peter J. Weinberger） (1973)^[11] showed that Euler's list of 65 idoneal numbers（英語：Idoneal number） is complete except for at most one element.

Siegel zeros often appear as more than an artificial issue in the argument for deducing zero-free regions, since zero-free region estimates enjoy deep connections to the arithmetic of quadratic fields. For instance, the identity ${\textstyle \zeta _{\mathbb {Q} ({\sqrt {D}})}(s)=\zeta (s)L(s,\chi _{D})}$  can be interpreted as an analytic formulation of quadratic reciprocity（英語：quadratic reciprocity） (see Artin reciprocity law §Statement in terms of L-functions（英語：Artin reciprocity law#Statement in terms of L-functions）). The precise relation between the distribution of zeros near s = 1 and arithmetic comes from Dirichlet's class number formula（英語：Class number formula#Dirichlet class number formula）:

${\displaystyle L(1,\chi _{D})={\begin{cases}{\dfrac {2\pi }{w_{D}{\sqrt {|D|}}}}\,h(D),&{\text{if }}D<0\\[.5em]{\dfrac {\log \varepsilon _{D}}{\sqrt {D}}}\,h(D),&{\text{if }}D>0,\end{cases}}}$ 

where:

• ${\textstyle h(D)}$  is the ideal class number（英語：Ideal class group#Properties） of ${\textstyle \mathbb {Q} ({\sqrt {D}})}$ ;
• ${\textstyle w_{D}}$  is the number of roots of unity（英語：Root of unity） in ${\textstyle \mathbb {Q} ({\sqrt {D}})}$  (D < 0);
• ${\textstyle \varepsilon _{D}}$  is the fundamental unit（英語：Fundamental unit (number theory)） of ${\textstyle \mathbb {Q} ({\sqrt {D}})}$  (D > 0).

This way, estimates for the largest real zero of ${\textstyle L(s,\chi _{D})}$  can be translated into estimates for ${\textstyle L(1,\chi _{D})}$  (via, for example, the fact that ${\textstyle |L'(\sigma ,\chi )|=O(\log ^{2}q)}$  for ${\textstyle 1-{\frac {1}{\log q}}\leq \sigma \leq 1}$ ),^[12] which in turn become estimates for ${\textstyle h(D)}$ . Classical works in the subject treat these three quantities essentially interchangeably, although the case D > 0 brings additional complications related to the fundamental unit.

There is a sense in which the difficulty associated to the phenomenon of Siegel zeros in general is entirely restricted to quadratic extensions. It is a consequence of the Kronecker–Weber theorem（英語：Kronecker–Weber theorem）, for example, that the Dedekind zeta function（英語：Dedekind zeta function） ${\textstyle \zeta _{K}(s)=\sum _{I\subseteq {\mathfrak {O}}_{K}}[{\mathfrak {O}}_{K}:I]^{-s}}$  of an abelian number field（英語：Abelian extension） ${\textstyle K/\mathbb {Q} }$  can be written as a product of Dirichlet L-functions.^[13] Thus, if ${\textstyle \zeta _{K}(s)}$  has a Siegel zero, there must be some subfield ${\textstyle F\subseteq K}$  with ${\textstyle [F:\mathbb {Q} ]=2}$  such that ${\textstyle \zeta _{F}(s)}$  has a Siegel zero.

While for the non-abelian case ${\textstyle \zeta _{K}(s)}$  can only be factored into more complicated Artin L-function（英語：Artin L-function）s, the same is true:

• Theorem (Stark（英語：Harold Stark）, 1974).^[14] Let ${\textstyle K/\mathbb {Q} }$  be a number field of degree n > 1. There is a constant ${\textstyle c(n)}$  (${\textstyle =4}$  if ${\textstyle K/\mathbb {Q} }$  is normal, ${\textstyle =4n!}$  otherwise) such that, if there is a real ${\textstyle \beta }$  in the range

$1-{\frac {c(n)}{\log |\Delta _{K}|}}\leq \beta <1$ 

with ${\textstyle \zeta _{K}(\beta )=0}$ , then there is a quadratic subfield ${\textstyle F\subseteq K}$  such that ${\textstyle \zeta _{F}(\beta )=0}$ . Here, ${\textstyle \Delta _{K}}$  is the field discriminant（英語：Discriminant of an algebraic number field） of the extension ${\textstyle K/\mathbb {Q} }$ .

When dealing with quadratic fields, the case ${\textstyle D>0}$  tends to be elusive due to the behaviour of the fundamental unit. Thus, it is common to treat the cases ${\textstyle D<0}$  and ${\textstyle D>0}$  separately. Much more is known for the negative discriminant case:

In 1918, Hecke（英語：Erich Hecke） showed that "no Siegel zeros" for ${\textstyle D<0}$  implies that ${\textstyle h(D)\gg {\sqrt {|D|}}(\log |D|)^{-1}}$ ^[5] (see Class number problem（英語：Class number problem） for comparison). This can be extended to an equivalence, as it is a consequence of Theorem 3 in Granville–Stark（英語：Harold Stark） (2000):^[15]

${\displaystyle {\text{``No Siegel zeros'' for }}D<0\quad \iff \quad h(D)\gg {\frac {\sqrt {|D|}}{\log |D|}}\sum _{(a,b,c)}{\frac {1}{a}},}$ 

where the summation runs over the reduced（英語：Binary quadratic form#Reduction and class numbers） binary quadratic forms（英語：Binary quadratic form） ${\textstyle ax^{2}+bxy+cy^{2}}$  of discriminant ${\textstyle D}$ . Using this, Granville and Stark showed that a certain uniform formulation of the abc conjecture（英語：abc conjecture） for number fields implies "no Siegel zeros" for negative discriminants.

In 1976, D. Goldfeld（英語：Dorian Goldfeld）^[16] proved the following unconditional, effective lower bound for ${\textstyle h(D)}$ :

${\displaystyle h(D)\gg \prod _{p\mid D}{\bigg (}1-{\frac {2{\sqrt {p}}}{p+1}}{\bigg )}\,\log |D|.}$ 

Another equivalence for "no Siegel zeros" for ${\textstyle D<0}$  can be given in terms of upper bounds（英語：Upper and lower bounds） for heights（英語：Height function） of singular moduli（英語：Complex multiplication#Singular moduli）:

${\displaystyle h(j(\tau _{D}))\ll \log |D|,}$ 

where:

• ${\textstyle h}$  is the absolute logarithmic naïve height（英語：Height function#Height functions in Diophantine geometry） for number fields;
• ${\textstyle j}$  is the j-invariant function（英語：j-invariant）;
• ${\textstyle \tau _{D}:=(D+{\sqrt {D}})/2}$ .

The number ${\textstyle j(\tau _{D})}$  generates the Hilbert class field（英語：Hilbert class field） of ${\textstyle \mathbb {Q} ({\sqrt {D}})}$ , which is its maximal unramified abelian extension.^[17] This equivalence is a direct consequence of the results in Granville–Stark (2000),^[15] and can be seen in C. Táfula (2019).^[18]

A precise relation between heights and values of L-functions was obtained by P. Colmez（英語：Pierre Colmez） (1993,^[19] 1998^[20]), who showed that, for an elliptic curve ${\textstyle E_{D}/\mathbb {C} }$  with complex multiplication（英語：complex multiplication） by ${\textstyle \mathbb {Z} [\tau _{D}]}$ , we have

${\displaystyle -2h_{\mathrm {Fal} }(E_{D})-{\frac {1}{2}}\log |D|={\frac {L'}{L}}(0,\chi _{D})+\log 2\pi ,}$ 

where ${\textstyle h_{\mathrm {Fal} }}$  denotes the Faltings height（英語：Height function#Height functions in Diophantine geometry）.^[21] Using the identities ${\textstyle h_{\mathrm {Fal} }(E_{D})={\frac {1}{12}}h(j(\tau _{D}))+O(\log h(j(\tau _{D})))}$ ^[22] and ${\textstyle {\frac {L'}{L}}(1,\chi _{D})=-{\frac {L'}{L}}(0,\chi _{D})-\log |D|+\log 2\pi +\gamma }$ ,^[23] Colmez' theorem also provides a proof for the equivalence above.