Jump to content

Bolza surface: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
Joroco246 (talk | contribs)
Citation bot (talk | contribs)
Add: url, s2cid. | Use this bot. Report bugs. | Suggested by Corvus florensis | #UCB_webform 94/2500
 
(38 intermediate revisions by 20 users not shown)
Line 1: Line 1:
{{Short description|In mathematics, a Riemann surface}}
In [[mathematics]], the '''Bolza surface''', alternatively, complex algebraic '''Bolza curve''' (introduced by {{harvs|txt|authorlink= Oskar Bolza|first=Oskar|last= Bolza|year=1887}}), is a compact [[Riemann surface]] of [[genus (mathematics)|genus]] 2 with the highest possible order of the [[conformal map|conformal]] [[automorphism group]] in this genus, namely GL<sub>2</sub>(3) of order 48. The full automorphism group (including reflections) is the [[semi-direct product]] <math>GL_{2}(3)\rtimes\mathbb{Z}_{2}</math> of order 96. An affine model for the Bolza surface can be obtained as the locus of the equation
In [[mathematics]], the '''Bolza surface''', alternatively, complex algebraic '''Bolza curve''' (introduced by {{harvs|txt|authorlink= Oskar Bolza|first=Oskar|last= Bolza|year=1887}}), is a compact [[Riemann surface]] of [[genus (mathematics)|genus]] <math>2</math> with the highest possible order of the [[conformal map|conformal]] [[automorphism group]] in this genus, namely <math>GL_2(3)</math> of order 48 (the [[general linear group]] of <math>2\times 2</math> matrices over the [[finite field]] <math>\mathbb{F}_3</math>). The full automorphism group (including reflections) is the [[semi-direct product]] <math>GL_{2}(3)\rtimes\mathbb{Z}_{2}</math> of order 96. An affine model for the Bolza surface can be obtained as the locus of the equation


:<math>y^2=x^5-x</math>
:<math>y^2=x^5-x</math>


in <math>\mathbb C^2</math>. The Bolza surface is the [[smooth completion]] of the affine curve. Of all genus 2 hyperbolic surfaces, the Bolza surface has the highest [[systolic geometry|systole]]. As a [[hyperelliptic curve|hyperelliptic]] Riemann surface, it arises as the ramified double cover of the Riemann sphere, with ramification locus at the six vertices of a regular [[octahedral symmetry|octahedron]] inscribed in the sphere, as can be readily seen from the equation above.
in <math>\mathbb C^2</math>. The Bolza surface is the [[smooth completion]] of the affine curve. Of all genus <math>2</math> hyperbolic surfaces, the Bolza surface maximizes the length of the [[systolic geometry|systole]] {{Harv|Schmutz|1993}}. As a [[hyperelliptic curve|hyperelliptic]] Riemann surface, it arises as the ramified double cover of the Riemann sphere, with ramification locus at the six vertices of a regular [[octahedral symmetry|octahedron]] inscribed in the sphere, as can be readily seen from the equation above.


The Bolza surface has attracted the attention of physicists, as it provides a relatively simple model for quantum chaos; in this context, it is usually referred to as the Hadamard-Gutzwiller model. The [[spectral theory]] of the [[Laplace-Beltrami operator]] acting on functions on the Bolza surface is of interest to both mathematicians and physicists, since the surface is conjectured to minimize the first positive [[eigenvalue]] of the Laplacian among all compact, closed [[Riemann surfaces]] of genus 2 with constant negative [[curvature]].
The Bolza surface has attracted the attention of physicists, as it provides a relatively simple model for [[quantum chaos]]; in this context, it is usually referred to as the [[Hadamard–Gutzwiller model]].<ref>{{cite journal|first1=R.|last1=Aurich|first2=M.|last2=Sieber|first3=F.|last3=Steiner|title=Quantum Chaos of the Hadamard–Gutzwiller Model|journal=Physical Review Letters|date=1 August 1988|pages=483–487|volume=61|issue=5|doi=10.1103/PhysRevLett.61.483|pmid=10039347|bibcode=1988PhRvL..61..483A|s2cid=20390243 |url=http://bib-pubdb1.desy.de/search?p=id:%22PUBDB-2017-04286%22}}</ref> The [[spectral theory]] of the [[Laplace–Beltrami operator]] acting on functions on the Bolza surface is of interest to both mathematicians and physicists, since the surface is conjectured to maximize the first positive [[eigenvalue]] of the Laplacian among all compact, closed [[Riemann surfaces]] of genus <math>2</math> with constant negative [[curvature]].


==Triangle surface==
==Triangle surface==


[[File:Order-3 octakis octagonal tiling.png|thumb|The tiling of the Bolza surface by reflection domains is a quotient of the [[order-3 bisected octagonal tiling]].]]
[[File:H2-8-3-kisrhombille.svg|thumb|The tiling of the Bolza surface by reflection domains is a quotient of the [[order-3 bisected octagonal tiling]].]]
[[File:Fundamental domain of Bolza surface.svg|thumb|The fundamental domain of the Bolza surface in the Poincaré disk; opposite sides are identified.]]


The Bolza surface is a (2,3,8) triangle surface – see [[Schwarz triangle]]. More specifically, the Fuchsian group defining the Bolza surface is a subgroup of the group generated by reflections in the sides of a hyperbolic triangle with angles <math>\tfrac{\pi}{2}, \tfrac{\pi}{3}, \tfrac{\pi}{8}</math>. More specifically, it is a subgroup of the [[Index of a subgroup|index]]-two subgroup of the group of reflections, which consists of products of an even number of reflections, which has an abstract presentation in terms of generators <math>s_2, s_3, s_8</math> and relations <math>s_2{}^2=s_3{}^3=s_8{}^8=1</math> as well as <math>s_2 s_3 = s_8</math>. The Fuchsian group <math>\Gamma</math> defining the Bolza surface is also a subgroup of the (3,3,4) [[triangle group]], which is a subgroup of index 2 in the (2,3,8) triangle group. The (2,3,8) group does not have a realisation in terms of a quaternion algebra, but the (3,3,4) group does.
The Bolza surface is conformally equivalent to a <math>(2,3,8)</math> triangle surface – see [[Schwarz triangle]]. More specifically, the [[Fuchsian group]] defining the Bolza surface is a subgroup of the group generated by reflections in the sides of a hyperbolic triangle with angles <math>\tfrac{\pi}{2}, \tfrac{\pi}{3}, \tfrac{\pi}{8}</math>. The group of orientation preserving isometries is a subgroup of the [[Index of a subgroup|index]]-two subgroup of the group of reflections, which consists of products of an even number of reflections, which has an abstract presentation in terms of generators <math>s_2, s_3, s_8</math> and relations <math>s_2{}^2=s_3{}^3=s_8{}^8=1</math> as well as <math>s_2 s_3 = s_8</math>. The Fuchsian group <math>\Gamma</math> defining the Bolza surface is also a subgroup of the (3,3,4) [[triangle group]], which is a subgroup of index 2 in the <math>(2,3,8)</math> triangle group. The <math>(2,3,8)</math> group does not have a realization in terms of a quaternion algebra, but the <math>(3,3,4)</math> group does.


Under the action of <math>\Gamma</math> on the [[Poincare disk]], the fundamental domain of the Bolza surface is a regular octagon with angles <math>\tfrac{\pi}{4}</math> and corners at
Under the action of <math>\Gamma</math> on the [[Poincare disk]], the fundamental domain of the Bolza surface is a regular octagon with angles <math>\tfrac{\pi}{4}</math> and corners at


:<math>p_{k}=2^{-\tfrac{1}{4}}e^{i\left(\tfrac{\pi}{8}+\tfrac{k\pi}{4}\right)},</math>
:<math>p_k=2^{-1/4}e^{i\left(\tfrac{\pi}{8}+\tfrac{k\pi}{4}\right)},</math>


where <math>k=0,\ldots, 7</math>. Opposite sides of the octagon are identified under the action of the Fuchsian group. Its generators are the matrices
where <math>k=0,\ldots, 7</math>. Opposite sides of the octagon are identified under the action of the Fuchsian group. Its generators are the matrices


:<math>g_{k}=\begin{pmatrix}1+\sqrt{2} & (2+\sqrt{2})\alpha e^{\tfrac{ik\pi}{4}}\\(2+\sqrt{2})\alpha e^{ -\tfrac{ik\pi}{4}} & 1+\sqrt{2}\end{pmatrix},</math>
:<math>g_k=\begin{pmatrix}1+\sqrt{2} & (2+\sqrt{2})\alpha e^{\tfrac{ik\pi}{4}}\\(2+\sqrt{2})\alpha e^{ -\tfrac{ik\pi}{4}} & 1+\sqrt{2}\end{pmatrix},</math>


where <math>\alpha=\sqrt{\sqrt{2}-1}</math> and <math>k=0,\ldots, 3</math>, along with their inverses. The generators satisfy the relation
where <math>\alpha=\sqrt{\sqrt{2}-1}</math> and <math>k=0,\ldots, 3</math>, along with their inverses. The generators satisfy the relation


:<math>g_{0}g_{1}^{-1}g_{2}g_{3}^{-1}g_{0}^{-1}g_{1}g_{2}^{-1}g_{3}=1.</math>
:<math>g_0 g_1^{-1} g_2 g_3^{-1} g_0^{-1} g_1 g_2^{-1} g_3=1.</math>


These generators are connected to the [[length spectrum]]. We have
These generators are connected to the [[length spectrum]], which gives all of the possible lengths of geodesic loops.  The shortest such length is called the ''systole'' of the surface. The systole of the Bolza surface is


:<math>\cosh\left(\tfrac{l_0}{2}\right)=1+\sqrt{2},</math>
:<math>\ell_1=2\operatorname{\rm arcosh}(1+\sqrt{2})\approx 3.05714.</math>


where <math>l_0</math> is the length of the systole. All other [[geodesics]] in the spectrum take the form
The <math>n^\text{th}</math> element <math>\ell_n</math> of the length spectrum for the Bolza surface is given by


:<math>\cosh\left(\tfrac{l_{n-1}}{2}\right)=m+\sqrt{2}n,</math>
:<math>\ell_n=2\operatorname{\rm arcosh}(m+n\sqrt{2}),</math>


where <math>m,\,n\in\mathbb{N}</math>, <math>n</math> runs through the [[natural numbers]] (apart from 48 and 72), and <math>m</math> is the unique odd number that minimises
where <math>n</math> runs through the [[positive integers]] (but omitting 4, 24, 48, 72, 140, and various higher values) {{Harv|Aurich|Bogomolny|Steiner|1991}} and where <math>m</math> is the unique odd integer that minimizes


:<math>\vert m/n-\sqrt{2}\vert.</math>
:<math>\vert m-n\sqrt{2}\vert.</math>


Here we have already seen a closed formula for the systole length. It is possible to obtain an equivalent form directly from the triangle group. [[hyperbolic triangle|Formulae]] exist to calculate the side lengths of a (2,3,8) triangles explicitly. The systole is equal to four times the length of the side of medial length in a (2,3,8) triangle, that is,
It is possible to obtain an equivalent closed form of the systole directly from the triangle group. [[hyperbolic triangle|Formulae]] exist to calculate the side lengths of a (2,3,8) triangles explicitly. The systole is equal to four times the length of the side of medial length in a (2,3,8) triangle, that is,


:<math>4\cosh^{-1}\left(\tfrac{\csc\left(\tfrac{\pi}{8}\right)}{2}\right)\approx 3.05714183896.</math>
:<math>\ell_1=4\operatorname{\rm arcosh}\left(\tfrac{\csc\left(\tfrac{\pi}{8}\right)}{2}\right)\approx 3.05714.</math>


The geodesic lengths <math>\ell_n</math> also appear in the [[Fenchel–Nielsen coordinates]] of the surface. A set of Fenchel-Nielsen coordinates for a surface of genus 2 consists of three pairs, each pair being a length and twist.  Perhaps the simplest such set of coordinates for the Bolza surface is <math>(\ell_2,\tfrac{1}{2};\; \ell_1,0;\; \ell_1,0)</math>, where <math>\ell_2=2\operatorname{\rm arcosh}(3+2\sqrt{2})\approx 4.8969</math>.
The systole also appears in the [[Fenchel-Nielsen coordinates]] of the surface; in particular, one set of coordinates is


There is also a "symmetric" set of coordinates <math>(\ell_1,t;\; \ell_1,t;\; \ell_1,t)</math>, where all three of the lengths are the systole <math>\ell_1</math> and all three of the twists
:<math>\left(l_1,t_1;l_2,t_2;l_3,t_3\right)=\left(2\cosh^{-1}(3+2\sqrt{2}),\tfrac{1}{2};2\cosh^{-1}(1+\sqrt{2}),0;2\cosh^{-1}(1+\sqrt{2}),0\right).</math>
are given by<ref>{{cite journal |last1=Strohmaier |first1=Alexander |editor1-last=Girouard |editor1-first=Alexandre |title=Compuration of eigenvalues, spectral zeta functions and zeta-determinants on hyperbolic surfaces |journal=Contemporary Mathematics |date=2017 |volume=700 |page=194 |doi=10.1090/conm/700 |publisher=Centre de Recherches Mathématiques and American Mathematical Society |location=Montréal|isbn=9781470426651 |arxiv=1603.07356 }}</ref>

:<math>t=\frac{\operatorname{\rm arcosh}\left(\sqrt{\tfrac{2}{7}(3+\sqrt{2})}\right)}{\operatorname{\rm arcosh}(1+\sqrt{2})}\approx 0.321281.</math>
There is also a "symmetric" set of coordinates where all the length parameters are given by the systole, and have equal twist parameters, namely

:<math>\left(l_1,t_1;l_2,t_2;l_3,t_3\right)=\left(2\cosh^{-1}(1+\sqrt{2}),\tfrac{\sqrt{\sqrt{2}-1}}{2};2\cosh^{-1}(1+\sqrt{2}),\tfrac{\sqrt{\sqrt{2}-1}}{2};2\cosh^{-1}(1+\sqrt{2}),\tfrac{\sqrt{\sqrt{2}-1}}{2}\right).</math>


==Symmetries of the surface==
==Symmetries of the surface==
Line 53: Line 53:
[[File:Symmetries of the Bolza surface.png|thumb|The four generators of the symmetry group of the Bolza surface]]
[[File:Symmetries of the Bolza surface.png|thumb|The four generators of the symmetry group of the Bolza surface]]


When we view the fundamental domain of the Bolza surface as a regular octagon in the Poincaré disk, the four symmetric actions that generate the (full) symmetry group are:
The fundamental domain of the Bolza surface is a regular octagon in the Poincaré disk; the four symmetric actions that generate the (full) symmetry group are:
*R - rotation of order 8 about the centre of the octagon;
*''R'' rotation of order 8 about the centre of the octagon;
*S - reflection in the real line;
*''S'' reflection in the real line;
*T - reflection in the side of one of the 16 (4,4,4) triangles that tessellate the octagon;
*''T'' reflection in the side of one of the 16 (4,4,4) triangles that tessellate the octagon;
*U - rotation of order 3 about the centre of a (4,4,4) triangle.
*''U'' rotation of order 3 about the centre of a (4,4,4) triangle.
These are shown by the bold lines in the adjacent figure. They satisfy the following set of relations:
These are shown by the bold lines in the adjacent figure. They satisfy the following set of relations:


:<math>\langle R,\,S,\,T,\,U\, |\,R^{8}=S^{2}=T^{2}=U^{3}=RSRS=STST=RTR^{3}T=e,\,UR=R^{7}U^{2},\,U^{2}R=STU,\,US=SU^{2},\, UT=RSU\rangle,</math>
: <math> \langle R,\,S,\,T,\,U\mid R^8=S^2=T^2=U^3=RSRS=STST=RTR^3 T=e, \,UR=R^7 U^2,\,U^2 R=STU,\,US=SU^2,\, UT=RSU \rangle,</math>


where <math>e</math> is the trivial (identity) action. One may use this set of relations in [[GAP (computer algebra system)|GAP]] to retrieve information about the representation theory of the group. In particular, we find that there are four 1 dimensional, two 2 dimensional, four 3 dimensional, and three 4 dimensional irreducible representations. Indeed, we can check that these satisfy [[Burnside's lemma]], that is
where <math>e</math> is the trivial (identity) action. One may use this set of relations in [[GAP (computer algebra system)|GAP]] to retrieve information about the representation theory of the group. In particular, there are four 1-dimensional, two 2-dimensional, four 3-dimensional, and three 4-dimensional irreducible representations, and


:<math>4(1^2)+2(2^2)+4(3^2)+3(4^2)=96,</math>
:<math>4(1^2)+2(2^2)+4(3^2)+3(4^2)=96</math>

as expected.


which is the order of the group (including reflections) as expected. These representations are investigated further in {{Harv|Cook|2018}}, where group theoretic and analytical methods are combined to prove results about the Laplace spectrum.
==Spectral theory==
==Spectral theory==


[[File:First eigenspace of the Bolza surface.png|center|frame|Plots of the three eigenfunctions corresponding to the first positive eigenvalue of the Bolza surface. Functions are zero on the light blue lines. These plots were produced using [[FreeFEM++]].]]
Here we disucss the spectral theory of the Laplacian, <math>\Delta</math>. The first eigenspace (that is, the eigenspace corresponding to the first positive eigenvalue) of the Bolza surface has been shown to be three dimensional, and the second, four dimensional {{Harv|Cook|2018}}. It is thought that investigating [[perturbations]] of the nodal lines of functions in the first eigenspace in [[Teichmüller space]] will yield the conjectured result in the introduction. This conjecture is based on extensive numerical computations of eigenvalues of the surface and other surfaces of genus 2. In particular, the spectrum of the Bolza surface has been computed to a very high accuracy by {{Harvcoltxt|Strohmaier|Uski|2013}}, where the authors present an algorithm for computing the eigenvalues of the Laplace operator on hyperbolic surfaces with a given precision. The algorithm is based on an adaption of the method of particular solutions to the case of locally symmetric spaces. The following table gives the first ten positive eigenvalues of the Bolza surface, computed using this method; more eigenvalues have been computed and these can be found as an ancillary file on the corresponding arXiv page.

Here, spectral theory refers to the spectrum of the Laplacian, <math>\Delta</math>. The first eigenspace (that is, the eigenspace corresponding to the first positive eigenvalue) of the Bolza surface is three-dimensional, and the second, four-dimensional {{Harv|Cook|2018}}, {{Harv|Jenni|1981}}. It is thought that investigating [[perturbation theory|perturbations]] of the nodal lines of functions in the first eigenspace in [[Teichmüller space]] will yield the conjectured result in the introduction. This conjecture is based on extensive numerical computations of eigenvalues of the surface and other surfaces of genus 2. In particular, the spectrum of the Bolza surface is known to a very high accuracy {{Harv|Strohmaier|Uski|2013}}. The following table gives the first ten positive eigenvalues of the Bolza surface.


{| class="wikitable"
{| class="wikitable"
Line 124: Line 126:
|}
|}


Strohmaier and Uski also computed the [[functional determinant|spectral determinant]] and [[Casimir energy]] <math>\zeta(-1/2)</math> of the surface. They are
The [[functional determinant|spectral determinant]] and [[Casimir energy]] <math>\zeta(-1/2)</math> of the Bolza surface are
:<math>\det{}_{\zeta}(\Delta)\approx 4.72273280444557</math>
:<math>\det{}_{\zeta}(\Delta)\approx 4.72273280444557</math>
and
and
:<math>\zeta{}_\Delta(-1/2)\approx -0.65000636917383</math>
:<math>\zeta_\Delta(-1/2)\approx -0.65000636917383</math>
respectively, where all decimal places are believed to be correct. The authors conjecture that the spectral determinant is maximized in genus 2 for the Bolza surface.
respectively, where all decimal places are believed to be correct. It is conjectured that the spectral determinant is maximized in genus 2 for the Bolza surface.


==Quaternion algebra==
==Quaternion algebra==
Line 140: Line 142:
*[[Hyperelliptic curve]]
*[[Hyperelliptic curve]]
*[[Klein quartic]]
*[[Klein quartic]]
*[[Bring's curve]]
*[[Macbeath surface]]
*[[Macbeath surface]]
*[[First Hurwitz triplet]]


==References==
==References==


*{{citation||last=Bolza|first= Oskar|title=On Binary Sextics with Linear Transformations into Themselves|journal= American Journal of Mathematics|volume= 10|issue= 1|year= 1887|pages= 47–70|jstor=2369402|doi=10.2307/2369402}}
*{{citation|last=Bolza|first= Oskar|title=On Binary Sextics with Linear Transformations into Themselves|journal= American Journal of Mathematics|volume= 10|issue= 1|year= 1887|pages= 47–70|jstor=2369402|doi=10.2307/2369402}}
*{{cite journal |last=Katz |first=M. |last2=Sabourau |first2=S. |title=An optimal systolic inequality for CAT(0) metrics in genus two |journal=[[Pacific Journal of Mathematics|Pacific J. Math.]] |volume=227 |year=2006 |issue=1 |pages=95–107 |arxiv=math.DG/0501017 |doi=10.2140/pjm.2006.227.95}}
*{{cite journal |last1=Katz |first1=M. |last2=Sabourau |first2=S. |title=An optimal systolic inequality for CAT(0) metrics in genus two |journal=[[Pacific Journal of Mathematics|Pacific J. Math.]] |volume=227 |year=2006 |issue=1 |pages=95–107 |arxiv=math.DG/0501017 |doi=10.2140/pjm.2006.227.95|s2cid=16510851 }}
*{{cite journal |last=Schmutz |first=P. |title=Riemann surfaces with shortest geodesic of maximal length |journal=[[Geometric and Functional Analysis|GAFA]] |volume=3 |year=1993 |issue=6 |pages=564–631 |doi=10.1007/BF01896258|s2cid=120508826 }}
*{{cite thesis |ref=harv|type=PhD, unpublished|last=Cook |first=J. |title=Properties of Eigenvalues on Riemann Surfaces with Large Symmetry Groups|publisher=Loughborough University|year=2018}}
*{{cite journal |ref=harv|last=Strohmaier |first=A. |last2=Uski |first2=V. |title=An Algorithm for the Computation of Eigenvalues, Spectral Zeta Functions and Zeta-Determinants on Hyperbolic Surfaces|journal=Communications in Mathematical Physics |volume=317 |year=2013 |issue=3 |pages=827-869|arxiv=1110.2150v4 |doi= 10.1007/s00220-012-1557-1}}
*{{cite journal |last1=Aurich |first1=R.|last2=Bogomolny|first2=E.B.|last3=Steiner|first3=F. |title=Periodic orbits on the regular hyperbolic octagon |journal=Physica D: Nonlinear Phenomena |volume=48 |year=1991 |issue=1 |pages=91–101 |doi=10.1016/0167-2789(91)90053-C|bibcode=1991PhyD...48...91A|url=https://bib-pubdb1.desy.de/record/588747 }}
*{{cite book |last=Maclachlan |first=C. |last2=Reid |first2=A. |title=The Arithmetic of Hyperbolic 3-Manifolds |series=Graduate Texts in Math. |volume=219 |publisher=Springer |location=New York |year=2003 |isbn=0-387-98386-4 }}
*{{cite thesis |type=PhD thesis, unpublished|last=Cook |first=J. |title=Properties of Eigenvalues on Riemann Surfaces with Large Symmetry Groups|publisher=Loughborough University |year=2018 |url=https://dspace.lboro.ac.uk/2134/36294 }}
*{{cite thesis |type=PhD thesis|last=Jenni |first=F. |title=Über das Spektrum des Laplace-Operators auf einer Schar kompakter Riemannscher Flächen |publisher=University of Basel |year=1981 |oclc=45934169 }}
*{{cite journal |last1=Strohmaier |first1=A. |last2=Uski |first2=V. |title=An Algorithm for the Computation of Eigenvalues, Spectral Zeta Functions and Zeta-Determinants on Hyperbolic Surfaces|journal=Communications in Mathematical Physics |volume=317 |year=2013 |issue=3 |pages=827–869|arxiv=1110.2150 |doi= 10.1007/s00220-012-1557-1|bibcode=2013CMaPh.317..827S|s2cid=14305255 }}
*{{cite book |last1=Maclachlan |first1=C. |last2=Reid |first2=A. |title=The Arithmetic of Hyperbolic 3-Manifolds |series=Graduate Texts in Math. |volume=219 |publisher=Springer |location=New York |year=2003 |isbn=0-387-98386-4 }}

;Specific
<references />


{{Algebraic curves navbox}}
{{Algebraic curves navbox}}

Latest revision as of 15:48, 7 December 2023

In mathematics, the Bolza surface, alternatively, complex algebraic Bolza curve (introduced by Oskar Bolza (1887)), is a compact Riemann surface of genus with the highest possible order of the conformal automorphism group in this genus, namely of order 48 (the general linear group of matrices over the finite field ). The full automorphism group (including reflections) is the semi-direct product of order 96. An affine model for the Bolza surface can be obtained as the locus of the equation

in . The Bolza surface is the smooth completion of the affine curve. Of all genus hyperbolic surfaces, the Bolza surface maximizes the length of the systole (Schmutz 1993). As a hyperelliptic Riemann surface, it arises as the ramified double cover of the Riemann sphere, with ramification locus at the six vertices of a regular octahedron inscribed in the sphere, as can be readily seen from the equation above.

The Bolza surface has attracted the attention of physicists, as it provides a relatively simple model for quantum chaos; in this context, it is usually referred to as the Hadamard–Gutzwiller model.[1] The spectral theory of the Laplace–Beltrami operator acting on functions on the Bolza surface is of interest to both mathematicians and physicists, since the surface is conjectured to maximize the first positive eigenvalue of the Laplacian among all compact, closed Riemann surfaces of genus with constant negative curvature.

Triangle surface

[edit]
The tiling of the Bolza surface by reflection domains is a quotient of the order-3 bisected octagonal tiling.
The fundamental domain of the Bolza surface in the Poincaré disk; opposite sides are identified.

The Bolza surface is conformally equivalent to a triangle surface – see Schwarz triangle. More specifically, the Fuchsian group defining the Bolza surface is a subgroup of the group generated by reflections in the sides of a hyperbolic triangle with angles . The group of orientation preserving isometries is a subgroup of the index-two subgroup of the group of reflections, which consists of products of an even number of reflections, which has an abstract presentation in terms of generators and relations as well as . The Fuchsian group defining the Bolza surface is also a subgroup of the (3,3,4) triangle group, which is a subgroup of index 2 in the triangle group. The group does not have a realization in terms of a quaternion algebra, but the group does.

Under the action of on the Poincare disk, the fundamental domain of the Bolza surface is a regular octagon with angles and corners at

where . Opposite sides of the octagon are identified under the action of the Fuchsian group. Its generators are the matrices

where and , along with their inverses. The generators satisfy the relation

These generators are connected to the length spectrum, which gives all of the possible lengths of geodesic loops.  The shortest such length is called the systole of the surface. The systole of the Bolza surface is

The element of the length spectrum for the Bolza surface is given by

where runs through the positive integers (but omitting 4, 24, 48, 72, 140, and various higher values) (Aurich, Bogomolny & Steiner 1991) and where is the unique odd integer that minimizes

It is possible to obtain an equivalent closed form of the systole directly from the triangle group. Formulae exist to calculate the side lengths of a (2,3,8) triangles explicitly. The systole is equal to four times the length of the side of medial length in a (2,3,8) triangle, that is,

The geodesic lengths also appear in the Fenchel–Nielsen coordinates of the surface. A set of Fenchel-Nielsen coordinates for a surface of genus 2 consists of three pairs, each pair being a length and twist.  Perhaps the simplest such set of coordinates for the Bolza surface is , where .

There is also a "symmetric" set of coordinates , where all three of the lengths are the systole and all three of the twists are given by[2]

Symmetries of the surface

[edit]
The four generators of the symmetry group of the Bolza surface

The fundamental domain of the Bolza surface is a regular octagon in the Poincaré disk; the four symmetric actions that generate the (full) symmetry group are:

  • R – rotation of order 8 about the centre of the octagon;
  • S – reflection in the real line;
  • T – reflection in the side of one of the 16 (4,4,4) triangles that tessellate the octagon;
  • U – rotation of order 3 about the centre of a (4,4,4) triangle.

These are shown by the bold lines in the adjacent figure. They satisfy the following set of relations:

where is the trivial (identity) action. One may use this set of relations in GAP to retrieve information about the representation theory of the group. In particular, there are four 1-dimensional, two 2-dimensional, four 3-dimensional, and three 4-dimensional irreducible representations, and

as expected.

Spectral theory

[edit]
Plots of the three eigenfunctions corresponding to the first positive eigenvalue of the Bolza surface. Functions are zero on the light blue lines. These plots were produced using FreeFEM++.

Here, spectral theory refers to the spectrum of the Laplacian, . The first eigenspace (that is, the eigenspace corresponding to the first positive eigenvalue) of the Bolza surface is three-dimensional, and the second, four-dimensional (Cook 2018), (Jenni 1981). It is thought that investigating perturbations of the nodal lines of functions in the first eigenspace in Teichmüller space will yield the conjectured result in the introduction. This conjecture is based on extensive numerical computations of eigenvalues of the surface and other surfaces of genus 2. In particular, the spectrum of the Bolza surface is known to a very high accuracy (Strohmaier & Uski 2013). The following table gives the first ten positive eigenvalues of the Bolza surface.

Numerical computations of the first ten positive eigenvalues of the Bolza surface
Eigenvalue Numerical value Multiplicity
0 1
3.8388872588421995185866224504354645970819150157 3
5.353601341189050410918048311031446376357372198 4
8.249554815200658121890106450682456568390578132 2
14.72621678778883204128931844218483598373384446932 4
15.04891613326704874618158434025881127570452711372 3
18.65881962726019380629623466134099363131475471461 3
20.5198597341420020011497712606420998241440266544635 4
23.0785584813816351550752062995745529967807846993874 1
28.079605737677729081562207945001124964945310994142 3
30.833042737932549674243957560470189329562655076386 4

The spectral determinant and Casimir energy of the Bolza surface are

and

respectively, where all decimal places are believed to be correct. It is conjectured that the spectral determinant is maximized in genus 2 for the Bolza surface.

Quaternion algebra

[edit]

Following MacLachlan and Reid, the quaternion algebra can be taken to be the algebra over generated as an associative algebra by generators i,j and relations

with an appropriate choice of an order.

See also

[edit]

References

[edit]
  • Bolza, Oskar (1887), "On Binary Sextics with Linear Transformations into Themselves", American Journal of Mathematics, 10 (1): 47–70, doi:10.2307/2369402, JSTOR 2369402
  • Katz, M.; Sabourau, S. (2006). "An optimal systolic inequality for CAT(0) metrics in genus two". Pacific J. Math. 227 (1): 95–107. arXiv:math.DG/0501017. doi:10.2140/pjm.2006.227.95. S2CID 16510851.
  • Schmutz, P. (1993). "Riemann surfaces with shortest geodesic of maximal length". GAFA. 3 (6): 564–631. doi:10.1007/BF01896258. S2CID 120508826.
  • Aurich, R.; Bogomolny, E.B.; Steiner, F. (1991). "Periodic orbits on the regular hyperbolic octagon". Physica D: Nonlinear Phenomena. 48 (1): 91–101. Bibcode:1991PhyD...48...91A. doi:10.1016/0167-2789(91)90053-C.
  • Cook, J. (2018). Properties of Eigenvalues on Riemann Surfaces with Large Symmetry Groups (PhD thesis, unpublished). Loughborough University.
  • Jenni, F. (1981). Über das Spektrum des Laplace-Operators auf einer Schar kompakter Riemannscher Flächen (PhD thesis). University of Basel. OCLC 45934169.
  • Strohmaier, A.; Uski, V. (2013). "An Algorithm for the Computation of Eigenvalues, Spectral Zeta Functions and Zeta-Determinants on Hyperbolic Surfaces". Communications in Mathematical Physics. 317 (3): 827–869. arXiv:1110.2150. Bibcode:2013CMaPh.317..827S. doi:10.1007/s00220-012-1557-1. S2CID 14305255.
  • Maclachlan, C.; Reid, A. (2003). The Arithmetic of Hyperbolic 3-Manifolds. Graduate Texts in Math. Vol. 219. New York: Springer. ISBN 0-387-98386-4.
Specific
  1. ^ Aurich, R.; Sieber, M.; Steiner, F. (1 August 1988). "Quantum Chaos of the Hadamard–Gutzwiller Model". Physical Review Letters. 61 (5): 483–487. Bibcode:1988PhRvL..61..483A. doi:10.1103/PhysRevLett.61.483. PMID 10039347. S2CID 20390243.
  2. ^ Strohmaier, Alexander (2017). Girouard, Alexandre (ed.). "Compuration of eigenvalues, spectral zeta functions and zeta-determinants on hyperbolic surfaces". Contemporary Mathematics. 700. Montréal: Centre de Recherches Mathématiques and American Mathematical Society: 194. arXiv:1603.07356. doi:10.1090/conm/700. ISBN 9781470426651.