arithmetic dynamics

Let {{mvar|S}} be a set and let {{math|F : S → S}} be a map from {{mvar|S}} to itself. The iterate of {{mvar|F}} with itself {{mvar|n}} times is denoted

:$F^\{(n)\}\; =\; F\; \backslash circ\; F\; \backslash circ\; \backslash cdots\; \backslash circ\; F.$

A point {{math|P ∈ S}} is periodic if {{math|F⁽ⁿ⁾(P) {{=}} P}} for some {{math|n ≥ 1}}.

The point is preperiodic if {{math|F^(k)(P)}} is periodic for some {{math|k ≥ 1}}.

The (forward) orbit of {{mvar|P}} is the set

:$O\_F(P)\; =\; \backslash left\; \backslash \{\; P,\; F(P),\; F^\{(2)\}(P),\; F^\{(3)\}(P),\; \backslash cdots\backslash right\backslash \}.$

Thus {{mvar|P}} is preperiodic if and only if its orbit {{math|O_F(P)}} is finite.

{{see also|Uniform boundedness conjecture for torsion points|Uniform boundedness conjecture for rational points}}

Let {{math|F(x)}} be a rational function of degree at least two with coefficients in {{math|Q}}. A theorem of Douglas Northcott{{cite journal | first=Douglas Geoffrey | last=Northcott | title=Periodic points on an algebraic variety | journal= Annals of Mathematics | volume=51 | pages=167–177 | doi=10.2307/1969504 | year=1950 | mr=0034607 | issue=1| jstor=1969504 }} says that {{mvar|F}} has only finitely many {{math|Q}}-rational preperiodic points, i.e., {{mvar|F}} has only finitely many preperiodic points in {{math|P¹(Q)}}. The uniform boundedness conjecture for preperiodic points{{cite journal | first1=Patrick | last1=Morton | first2=Joseph H. | last2=Silverman | title=Rational periodic points of rational functions | journal= International Mathematics Research Notices | volume=1994 | pages=97–110 | year=1994 | issue=2 | doi=10.1155/S1073792894000127 | mr=1264933| doi-access=free }} of Patrick Morton and Joseph Silverman says that the number of preperiodic points of {{mvar|F}} in {{math|P¹(Q)}} is bounded by a constant that depends only on the degree of {{mvar|F}}.

More generally, let {{math|F : P^N → P^N}} be a morphism of degree at least two defined over a number field {{mvar|K}}. Northcott's theorem says that {{mvar|F}} has only finitely many preperiodic points in

{{math|P^N(K)}}, and the general Uniform Boundedness Conjecture says that the number of preperiodic points in

{{math|P^N(K)}} may be bounded solely in terms of {{mvar|N}}, the degree of {{mvar|F}}, and the degree of {{mvar|K}} over {{math|Q}}.

The Uniform Boundedness Conjecture is not known even for quadratic polynomials {{math|F_c(x) {{=}} x² + c}} over the rational numbers {{math|Q}}. It is known in this case that {{math|F_c(x)}} cannot have periodic points of period four,{{cite journal | first=Patrick | last=Morton | title=Arithmetic properties of periodic points of quadratic maps | journal= Acta Arithmetica | volume=62 | issue=4 | pages=343–372 | year=1992 | mr=1199627| doi=10.4064/aa-62-4-343-372 | doi-access=free }} five,{{cite journal | first1=Eugene V. | last1=Flynn | first2=Bjorn | last2=Poonen | first3=Edward F. | last3=Schaefer | title=Cycles of quadratic polynomials and rational points on a genus-2 curve | journal= Duke Mathematical Journal | volume=90 | issue=3 | pages=435–463 | year=1997 | mr=1480542 | doi=10.1215/S0012-7094-97-09011-6| arxiv=math/9508211 | s2cid=15169450 }} or six,{{cite journal | first=Michael | last=Stoll | arxiv=0803.2836 | title=Rational 6-cycles under iteration of quadratic polynomials | year=2008 | journal= LMS Journal of Computation and Mathematics | volume=11 | doi=10.1112/S1461157000000644 | mr=2465796 | pages=367–380| bibcode=2008arXiv0803.2836S | s2cid=14082110 }} although the result for period six is contingent on the validity of the conjecture of Birch and Swinnerton-Dyer. Bjorn Poonen has conjectured that {{math|F_c(x)}} cannot have rational periodic points of any period strictly larger than three.{{cite journal | first=Bjorn | last=Poonen | title= The classification of rational preperiodic points of quadratic polynomials over {{math|Q}}: a refined conjecture | journal= Mathematische Zeitschrift | volume=228 | issue=1 | pages=11–29 | year=1998 | mr=1617987 | doi=10.1007/PL00004405| s2cid=118160396 }}

The orbit of a rational map may contain infinitely many integers. For example, if {{math|F(x)}} is a polynomial with integer coefficients and if {{mvar|a}} is an integer, then it is clear that the entire orbit {{math|O_F(a)}} consists of integers. Similarly, if {{math|F(x)}} is a rational map and some iterate {{math|F⁽ⁿ⁾(x)}} is a polynomial with integer coefficients, then every {{mvar|n}}-th entry in the orbit is an integer. An example of this phenomenon is the map {{math|F(x) {{=}} x^−d}}, whose second iterate is a polynomial. It turns out that this is the only way that an orbit can contain infinitely many integers.

:Theorem.{{cite journal | first=Joseph H. | last=Silverman | title= Integer points, Diophantine approximation, and iteration of rational maps | journal= Duke Mathematical Journal | volume=71 | issue=3 | pages=793–829 | year=1993 | mr=1240603 | doi=10.1215/S0012-7094-93-07129-3}} Let {{math|F(x) ∈ Q(x)}} be a rational function of degree at least two, and assume that no iterateAn elementary theorem says that if {{math|F(x) ∈ C(x)}} and if some iterate of {{mvar|F}} is a polynomial, then already the second iterate is a polynomial. of {{mvar|F}} is a polynomial. Let {{math|a ∈ Q}}. Then the orbit {{math|O_F(a)}} contains only finitely many integers.

There are general conjectures due to Shouwu Zhang{{cite encyclopedia | first=Shou-Wu | last=Zhang | chapter=Distributions in algebraic dynamics | title=Differential Geometry: A Tribute to Professor S.-S. Chern | series=Surveys in Differential Geometry | volume=10 | publisher=International Press | location=Somerville, MA | year=2006 | pages=381–430 | mr=2408228 | doi=10.4310/SDG.2005.v10.n1.a9 | isbn=978-1-57146-116-2 | editor-first=Shing Tung | editor-last=Yau| doi-access=free }}

and others concerning subvarieties that contain infinitely many periodic points or that intersect an orbit in infinitely many points. These are dynamical analogues of, respectively, the Manin–Mumford conjecture, proven by Michel Raynaud, and the Mordell–Lang conjecture, proven by Gerd Faltings. The following conjectures illustrate the general theory in the case that the subvariety is a curve.

:Conjecture. Let {{math|F : P^N → P^N}} be a morphism and let {{math|C ⊂ P^N}} be an irreducible algebraic curve. Suppose that there is a point {{math|P ∈ P^N}} such that {{mvar|C}} contains infinitely many points in the orbit {{math|O_F(P)}}. Then {{mvar|C}} is periodic for {{mvar|F}} in the sense that there is some iterate {{math|F^(k)}} of {{mvar|F}} that maps {{mvar|C}} to itself.

The field of p-adic dynamics is the study of classical dynamical questions over a field {{mvar|K}} that is complete with respect to a nonarchimedean absolute value. Examples of such fields are the field of {{mvar|p}}-adic rationals {{math|Q_p}} and the completion of its algebraic closure {{math|C_p}}. The metric on {{mvar|K}} and the standard definition of equicontinuity leads to the usual definition of the Fatou and Julia sets of a rational map {{math|F(x) ∈ K(x)}}. There are many similarities between the complex and the nonarchimedean theories, but also many differences. A striking difference is that in the nonarchimedean setting, the Fatou set is always nonempty, but the Julia set may be empty. This is the reverse of what is true over the complex numbers. Nonarchimedean dynamics has been extended to Berkovich space,{{cite book | first1=Robert | last1=Rumely | author1-link=Robert Rumely | first2=Matthew | last2=Baker | arxiv=math/0407433 | title=Potential theory and dynamics on the Berkovich projective line | year=2010 | series=Mathematical Surveys and Monographs | volume=159 | publisher=American Mathematical Society | location=Providence, RI | isbn=978-0-8218-4924-8 | doi=10.1090/surv/159 | mr=2599526}} which is a compact connected space that contains the totally disconnected non-locally compact field {{math|C_p}}.

There are natural generalizations of arithmetic dynamics in which {{math|Q}} and {{math|Q_p}} are replaced by number fields and their {{mvar|p}}-adic completions. Another natural generalization is to replace self-maps of {{math|P¹}} or {{math|P^N}} with self-maps (morphisms) {{math|V → V}} of other affine or projective varieties.

There are many other problems of a number theoretic nature that appear in the setting of dynamical systems, including:

• dynamics over finite fields.
• dynamics over function fields such as {{math|C(x)}}.
• iteration of formal and {{mvar|p}}-adic power series.
• dynamics on Lie groups.
• arithmetic properties of dynamically defined moduli spaces.
• equidistribution{{cite encyclopedia | title=Equidistribution in number theory, an introduction | editor1-first=Andrew | editor1-last=Granville | editor2-first=Zeév | editor2-last=Rudnick | publisher=Springer Netherlands | location=Dordrecht | year=2007 | isbn=978-1-4020-5403-7 | series=NATO Science Series II: Mathematics, Physics and Chemistry | volume=237 | doi=10.1007/978-1-4020-5404-4 | mr=2290490}} and invariant measures, especially on {{mvar|p}}-adic spaces.
• dynamics on Drinfeld modules.
• number-theoretic iteration problems that are not described by rational maps on varieties, for example, the Collatz problem.
• symbolic codings of dynamical systems based on explicit arithmetic expansions of real numbers.{{cite encyclopedia | last=Sidorov | first=Nikita | chapter=Arithmetic dynamics | zbl=1051.37007 | editor1-last=Bezuglyi | editor1-first=Sergey | editor2-last=Kolyada | editor2-first=Sergiy | title=Topics in dynamics and ergodic theory. Survey papers and mini-courses presented at the international conference and US-Ukrainian workshop on dynamical systems and ergodic theory, Katsiveli, Ukraine, August 21–30, 2000 | location=Cambridge | publisher=Cambridge University Press | isbn=0-521-53365-1 | series=Lond. Math. Soc. Lect. Note Ser. | volume=310 | pages=145–189 | year=2003 | mr=2052279| doi=10.1017/CBO9780511546716.010 | s2cid=15482676 }}

The [http://www.math.brown.edu/~jhs/ADSBIB.pdf Arithmetic Dynamics Reference List] gives an extensive list of articles and books covering a wide range of arithmetical dynamical topics.

• Arithmetic geometry
• Arithmetic topology
• Combinatorics and dynamical systems
• Arboreal Galois representation

{{reflist}}

• [http://swc.math.arizona.edu/aws/2010/2010SilvermanNotes.pdf Lecture Notes on Arithmetic Dynamics Arizona Winter School], March 13–17, 2010, Joseph H. Silverman
• Chapter 15 of [https://books.google.com/books?id=fGGP482b54sC A first course in dynamics: with a panorama of recent developments], Boris Hasselblatt, A. B. Katok, Cambridge University Press, 2003, {{ISBN|978-0-521-58750-1}}

• [http://www.math.brown.edu/~jhs/ADSHome.html The Arithmetic of Dynamical Systems home page]
• [http://www.math.brown.edu/~jhs/ADSBIB.pdf Arithmetic dynamics bibliography]
• [https://arxiv.org/abs/math/0407433 Analysis and dynamics on the Berkovich projective line]
• [https://www.ams.org/bull/2009-46-01/S0273-0979-08-01216-0/S0273-0979-08-01216-0.pdf Book review] of Joseph H. Silverman's "The Arithmetic of Dynamical Systems", reviewed by Robert L. Benedetto

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Category:Dynamical systems

Category:Algebraic number theory