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$\boldsymbol {p}$-ADIC QUOTIENT SETS: LINEAR RECURRENCE SEQUENCES

Published online by Cambridge University Press:  05 January 2023

DEEPA ANTONY
Affiliation:
Department of Mathematics, Indian Institute of Technology Guwahati, Assam PIN-781039, India e-mail: [email protected]
RUPAM BARMAN*
Affiliation:
Department of Mathematics, Indian Institute of Technology Guwahati, Assam PIN-781039, India
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Abstract

Let $(x_n)_{n\geq 0}$ be a linear recurrence of order $k\geq 2$ satisfying $x_n=a_1x_{n-1}+a_2x_{n-2}+\cdots +a_kx_{n-k}$ for all integers $n\geq k$, where $a_1,\ldots ,a_k,x_0,\ldots , x_{k-1}\in \mathbb {Z},$ with $a_k\neq 0$. Sanna [‘The quotient set of k-generalised Fibonacci numbers is dense in $\mathbb {Q}_p$’, Bull. Aust. Math. Soc. 96(1) (2017), 24–29] posed the question of classifying primes p for which the quotient set of $(x_n)_{n\geq 0}$ is dense in $\mathbb {Q}_p$. We find a sufficient condition for denseness of the quotient set of the kth-order linear recurrence $(x_n)_{n\geq 0}$ satisfying $ x_{n}=a_1x_{n-1}+a_2x_{n-2}+\cdots +a_kx_{n-k}$ for all integers $n\geq k$ with initial values $x_0=\cdots =x_{k-2}=0,x_{k-1}=1$, where $a_1,\ldots ,a_k\in \mathbb {Z}$ and $a_k=1$. We show that, given a prime p, there are infinitely many recurrence sequences of order $k\geq 2$ whose quotient sets are not dense in $\mathbb {Q}_p$. We also study the quotient sets of linear recurrence sequences with coefficients in certain arithmetic and geometric progressions.

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Research Article
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© The Author(s), 2023. Published by Cambridge University Press on behalf of Australian Mathematical Publishing Association Inc.

1 Introduction and statement of results

For a set of integers A, the set $R(A)=\{a/b:a,b\in A, b\neq 0\}$ is called the ratio set or quotient set of A. Several authors have studied the denseness of ratio sets of different subsets of $\mathbb {N}$ in the positive real numbers (see [Reference Brown, Dairyko, Garcia, Lutz and Someck3, Reference Bukor and Csiba5Reference Bukor and Tóth7, Reference Garcia, Poore, Selhorst-Jones and Simon15, Reference Hedman and Rose16Reference Mišík20, Reference Šalát24, Reference Šalát25, Reference Starni29, Reference Strauch and Tóth30]). An analogous study has also been done for algebraic number fields (see [Reference Garcia12, Reference Sittinger28]).

For a prime p, let $\mathbb {Q}_p$ denote the field of p-adic numbers. The denseness of ratio sets in $\mathbb {Q}_p$ has been studied by several authors (see [Reference Antony and Barman1, Reference Antony, Barman and Miska2, Reference Donnay, Garcia and Rouse10, Reference Garcia, Hong, Luca, Pinsker, Sanna, Schechter and Starr13, Reference Garcia and Luca14, Reference Miska21Reference Miska and Sanna23, Reference Sanna27]). Let $(F_n)_{n\geq 0}$ be the sequence of Fibonacci numbers, defined by $F_0=0$ , $F_1=1$ and $F_n=F_{n-1}+F_{n-2}$ for all integers $n\geq 2$ . In [Reference Garcia and Luca14], Garcia and Luca showed that the ratio set of Fibonacci numbers is dense in $\mathbb {Q}_p$ for all primes p. Later, Sanna [Reference Sanna27, Theorem 1.2] showed that, for any $k\geq 2$ and any prime p, the ratio set of the k-generalised Fibonacci numbers is dense in $\mathbb {Q}_p$ . Sanna remarked that his result could be extended to other linear recurrences over the integers. However, he used some specific properties of the k-generalised Fibonacci numbers in the proof. Therefore, he asked the following question.

Question 1.1 [Reference Sanna27, Question 1.3].

Let $(S_n)_{n\geq 0}$ be a linear recurrence of order $k\geq 2$ satisfying $S_n=a_1S_{n-1}+a_2S_{n-2}+\cdots +a_kS_{n-k}$ for all integers $n\geq k$ , where $a_1,\ldots ,a_k,S_0,\ldots ,S_{k-1}\in \mathbb {Z},$ with $a_k\neq 0.$ For which prime numbers p is the quotient set of $(S_n)_{n\geq 0}$ dense in $\mathbb {Q}_p?$

In [Reference Garcia, Hong, Luca, Pinsker, Sanna, Schechter and Starr13], Garcia et al. studied the quotient sets of certain second-order recurrences: given two fixed integers r and s, let $(a_n)_{n\geq 0}$ be defined by $a_{n}=ra_{n-1}+sa_{n-2}$ for $n\geq 2$ with initial values $a_0=0$ and $a_1=1$ , and let $(b_n)_{n\geq 0}$ be defined by $b_{n}=rb_{n-1}+sb_{n-2}$ for $n\geq 2$ with initial values $b_0=2$ and $b_1=r$ .

Theorem 1.2 [Reference Garcia, Hong, Luca, Pinsker, Sanna, Schechter and Starr13, Theorem 5.2].

With the notation as above, let $A=\{a_n: n\geq 0\}$ and $B=\{b_n: n\geq 0\}$ .

  1. (a) If $p\mid s$ and $p\nmid r$ , then $R(A)$ is not dense in $\mathbb {Q}_p$ .

  2. (b) If $p\nmid s$ , then $R(A)$ is dense in $\mathbb {Q}_p$ .

  3. (c) For all odd primes p, $R(B)$ is dense in $\mathbb {Q}_p$ if and only if there exists a positive integer n such that $p\mid b_n$ .

We study ratio sets of some other linear recurrences over the set of integers. Our results give some answers to Question 1.1. Our first result gives a sufficient condition for the denseness of the ratio sets of certain kth-order recurrence sequences. Finding a general solution to Question 1.1 seems to be a difficult problem. Hence, in Theorem 1.3, we consider kth-order recurrence sequences for which $a_k=1$ and with initial values $x_0=\cdots =x_{k-2}=0$ , $x_{k-1}=1$ . Recall that a Pisot number is a positive algebraic integer greater than $1$ all of whose conjugate elements have absolute value less than $1$ .

Theorem 1.3. Let $(x_n)_{n\geq 0}$ be a $kth$ -order linear recurrence satisfying

$$ \begin{align*} x_{n}=a_1x_{n-1}+a_2x_{n-2}+\cdots+a_{k-1}x_{n-k+1}+x_{n-k} \end{align*} $$

for all integers $n\geq k$ with initial values $x_0=x_1=\cdots =x_{k-2}=0, x_{k-1}=1$ and $a_1,\ldots ,a_{k-1}\in \mathbb {Z}$ . Suppose that the characteristic polynomial of the recurrence sequence has a root $\pm \alpha $ , where $\alpha $ is a Pisot number. If p is a prime such that the characteristic polynomial of the recurrence sequence is irreducible in $\mathbb {Q}_p$ , then the quotient set of $(x_n)_{n\geq 0}$ is dense in $\mathbb {Q}_p$ .

If we take $k=3$ in Theorem 1.3, then we have the following corollary.

Corollary 1.4. Let $(x_n)_{n\geq 0}$ be a third-order linear recurrence satisfying

$$ \begin{align*} x_{n}=ax_{n-1}+bx_{n-2}+x_{n-3} \end{align*} $$

for all integers $n\geq 3$ with initial values $x_0=x_1=0, x_2=1$ , where the integers a and b are such that $(a+b)(b-a-2)<0$ . If p is a prime such that the characteristic polynomial of the recurrence sequence is irreducible in $\mathbb {Q}_p$ , then the quotient set of $(x_n)_{n\geq 0}$ is dense in $\mathbb {Q}_p$ .

We discuss two examples as applications of Corollary 1.4.

Example 1.5. For $a\in \mathbb {N}$ , let $\ell $ be an odd positive integer less than $2a$ . Let $(x_n)_{n\geq 0}$ be a linear recurrence satisfying $x_{n}=ax_{n-1}+(a-\ell )x_{n-2}+x_{n-3}$ for all integers $n\geq 3$ with initial values $x_0=x_1=0, x_2=1$ . Then a and $b:=a-\ell $ satisfy $(a+b)(b-a-2) <0$ . The characteristic polynomial $p(x)=x^3-ax^2-(a-\ell )x-1$ is irreducible in $\mathbb {Q}_2$ because $p(0)\neq 0$ and $p(1)=-2a+\ell \not \equiv 0\pmod {2}$ . Therefore, by Theorem 1.3, $R((x_n)_{n\geq 0})$ is dense in $\mathbb {Q}_2$ .

Example 1.6. For $a\in \mathbb {N}$ such that $3\nmid a$ , let $\ell $ be an odd positive integer less than $2a$ and such that $3\mid \ell $ . Let $(x_n)_{n\geq 0}$ be a linear recurrence satisfying $x_{n}=ax_{n-1}+(a-\ell )x_{n-2}+ x_{n-3}$ for all integers $n\geq 3$ with initial values $x_0=x_1=0, x_2=1$ . Then a and $b=a-\ell $ satisfy $(a+b)(b-a-2)<0$ . The characteristic polynomial $p(x)=x^3-ax^2-(a-\ell ) x-1$ is irreducible in $\mathbb {Q}_3$ because $p(0)\neq 0$ , $p(1)=-2a+\ell \not \equiv 0\pmod {3}$ and $p(2)=-6a+2\ell +7\not \equiv 0\pmod {3}$ . Therefore, by Theorem 1.3, $R((x_n)_{n\geq 0})$ is dense in $\mathbb {Q}_3$ .

Next, we consider recurrence sequences whose nth term depends on all the previous $n-1$ terms and obtain the following results.

Theorem 1.7. Let $(x_n)_{n\geq 0}$ be a linear recurrence satisfying

$$ \begin{align*} x_{n}=x_{n-1}+2x_{n-2}+\cdots+(n-1)x_1+nx_0 \end{align*} $$

for all integers $n\geq 1$ with initial value $x_0=1$ . Then the quotient set of $(x_n)_{n\geq 0}$ is dense in $\mathbb {Q}_p$ for all primes p.

The recurrence relation given in Theorem 1.7 generates a subsequence of the Fibonacci sequence.

Theorem 1.8. Let $(x_n)_{n\geq 0}$ be a linear recurrence satisfying

$$ \begin{align*} x_{n}=ax_{n-1}+arx_{n-2}+\cdots+ar^{n-1}x_0 \end{align*} $$

for all integers $n\geq 1$ , with $x_0, a,r\in \mathbb {Z}$ . Then the quotient set of $(x_n)_{n\geq 0}$ is not dense in $\mathbb {Q}_p$ for all primes p.

In Theorem 1.2, Garcia et al. studied second-order recurrence relations with specific initial values. In the following result, we consider a particular second-order recurrence sequence with arbitrary initial values $x_0$ and $x_1$ in the set of integers.

Theorem 1.9. Let $(x_n)_{n\geq 0}$ be a second-order linear recurrence satisfying $x_{n}=2ax_{n-1}-a^2x_{n-2}$ for all integers $n\geq 2$ , where $a,x_0,x_1\in \mathbb {Z}$ . Then the quotient set of $(x_n)_{n\geq 0}$ is dense in $\mathbb {Q}_p$ for all primes p satisfying $p\nmid a(x_1-ax_0)$ .

For a prime p, let $\nu _p$ denote the p-adic valuation. The following theorem gives a set of linear recurrence sequences of order k whose ratio sets are not dense in $\mathbb {Q}_p.$

Theorem 1.10. Let $(x_n)_{n\geq 0}$ be a linear recurrence of order $k\geq 2$ satisfying

$$ \begin{align*} x_{n}=a_1x_{n-1}+\cdots+a_kx_{n-k} \end{align*} $$

for all integers $n\geq k$ , where $x_0,\ldots ,x_{k-1}, a_1,\ldots ,a_k\in \mathbb {Z}$ . If p is a prime such that $p\nmid a_k$ and $\min \{\nu _p(a_j):1\leq j<k\}>\max \{\nu _p(x_m)-\nu _p(x_n):0\leq m,n<k\}$ , then the quotient set of $(x_n)_{n\geq 0}$ is not dense in $\mathbb {Q}_p$ .

The next example is an application of Theorem 1.10. Given a prime p, this example gives infinitely many recurrence sequences of order $k\geq 2$ whose quotient sets are not dense in $\mathbb {Q}_p$ .

Example 1.11. Let $(x_n)_{n\geq 0}$ be a linear recurrence of order $k\geq 2$ satisfying

$$ \begin{align*} x_{n}=a_1x_{n-1}+\cdots+a_kx_{n-k} \end{align*} $$

for all integers $n\geq k$ , where $x_0=x_1=\cdots =x_{k-1}=1$ and $a_1,\ldots ,a_k\in \mathbb {Z}$ . If p is a prime such that $p\mid a_j,1\leq j\leq k-1$ , and $p\nmid a_k$ , then by Theorem 1.10, the quotient set of $(x_n)_{n\geq 0}$ is not dense in $\mathbb {Q}_p$ .

2 Preliminaries

Let p be a prime and r be a nonzero rational number. Then r has a unique representation of the form $r= \pm p^k a/b$ , where $k\in \mathbb {Z}, a, b \in \mathbb {N}$ and $\gcd (a,p)= \gcd (p,b)=\gcd (a,b)=1$ . The p-adic valuation of r is $\nu _p(r)=k$ and its p-adic absolute value is $\|r\|_p=p^{-k}$ . By convention, $\nu _p(0)=\infty $ and $\|0\|_p=0$ . The p-adic metric on $\mathbb {Q}$ is $d(x,y)=\|x-y\|_p$ . The field $\mathbb {Q}_p$ of p-adic numbers is the completion of $\mathbb {Q}$ with respect to the p-adic metric. The p-adic absolute value can be extended to a finite normal extension field K over $\mathbb {Q}_p$ of degree n. For $\alpha \in K$ , define $\|\alpha \|_p$ as the nth root of the determinant of the matrix of the linear transformation from the vector space K over $\mathbb {Q}_p$ to itself defined by $x\mapsto \alpha x$ for all $x\in K$ . Also, define $\nu _p(\alpha )$ as the unique rational number satisfying $\|\alpha \|_p=p^{-\nu _p(\alpha )}$ .

The following results will be used in the proofs of our theorems.

Lemma 2.1 [Reference Garcia, Hong, Luca, Pinsker, Sanna, Schechter and Starr13, Lemma 2.1].

If S is dense in $\mathbb {Q}_p$ , then for each finite value of the p-adic valuation, there is an element of S with that valuation.

Lemma 2.2 [Reference Garcia, Hong, Luca, Pinsker, Sanna, Schechter and Starr13, Lemma 2.3].

Let $A\subset \mathbb {N}$ .

  1. (1) If A is p-adically dense in $\mathbb {N}$ , then $R(A)$ is dense in $\mathbb {Q}_p$ .

  2. (2) If $R(A)$ is p-adically dense in $\mathbb {N}$ , then $R(A)$ is dense in $\mathbb {Q}_p$ .

Theorem 2.3 [Reference Brumer4, Theorem 1].

Let $\alpha _1,\ldots ,\alpha _n$ be units in $\Omega _p$ , the completion of the algebraic closure of $\mathbb {Q}_p,$ which are algebraic over the rationals $\mathbb {Q}$ and whose p-adic logarithms are linearly independent over $\mathbb {Q}$ . These logarithms are then linearly independent over the algebraic closure of $\mathbb {Q}$ in $\Omega _p$ .

3 Proof of the theorems

Proof of Theorem 1.3.

Let $p(x)=x^k-a_1x^{k-1}-a_2x^{k-2}-\cdots -a_{k-1}x-1$ be the characteristic polynomial of the recurrence. Let $\alpha _1,\ldots ,\alpha _{k}$ be the k distinct roots of the characteristic polynomial in its splitting field, say, K over $\mathbb {Q}_p$ . The generating function of the sequence is

$$ \begin{align*} t(x)=\frac{x^{k-1}}{1-a_1x-a_2x^2-\cdots-x^k}=\sum_{i=1}^k\frac{1}{q(\alpha_i)}\sum_{n=0}^{\infty}\alpha_i^nx^n, \end{align*} $$

where $q(x):=p'(x)$ , the derivative of the polynomial $p(x)$ . Hence, the nth term of the sequence is given by

$$ \begin{align*} x_n=\sum_{i=1}^{k}\frac{1}{q(\alpha_i)}\alpha_i^n,\quad n\geq0. \end{align*} $$

Since $p(0)=-1$ , the roots of $p(x)$ are units in the ring formed by elements in K with p-adic absolute value less than or equal to $1$ . Following Sanna’s proof of [Reference Sanna27, Theorem 1.2], we can choose an even $t\in \mathbb {N}$ such that the function

$$ \begin{align*} G(z):=\sum_{i=1}^{k}\frac{1}{q(\alpha_i)}\exp_p(z\log_p(\alpha_i^t)) \end{align*} $$

is analytic over $\mathbb {Z}_p$ and the Taylor series of $G(z)$ around $0$ converges for all $z\in \mathbb {Z}_p$ . Also, note that $x_{nt}=G(n)$ for $n\geq 0$ .

We now use a variant of the following lemma which gives the multiplicative independence of any $k-1$ roots among the k roots $\alpha _1,\ldots ,\alpha _k$ of the characteristic polynomial $x^k-x^{k-1}-\cdots -x-1$ of the k-generalised Fibonacci sequence in the field of complex numbers.

Lemma 3.1 [Reference Fuchs, Hutle, Luca and Szalay11, Lemma 1].

With the notation above, each set of $k-1$ different roots $\alpha _1,\ldots ,\alpha _{k-1}$ is multiplicatively independent, that is, $\alpha _1^{e_1}\cdots \alpha _{k-1}^{e_{k-1}}=1$ for some integers $e_1,\ldots ,e_{k-1}$ if and only if $e_1=\cdots =e_{k-1}=0$ .

Let $\sigma(\alpha_1) = \pm \alpha$ , where $\alpha$ is a Pisot number with absolute value greater than 1, the other roots, $\sigma (\alpha _2),\ldots ,\sigma (\alpha _k)$ , having absolute values less than $1$ , where $\sigma $ is an isomorphism from $\mathbb {Q}(\alpha _1,\ldots ,\alpha _k)$ to the splitting field of $p(x)$ over $\mathbb {Q}$ in the field of complex numbers. Therefore, the proof of Lemma 3.1 holds true for the roots of $p(x)$ , which are $\sigma (\alpha _1),\ldots , \sigma (\alpha _k)$ , since $\log |\sigma (\alpha _1)|$ is positive and $\log |\sigma (\alpha _2)|,\ldots ,\log |\sigma (\alpha _k)|$ are negative. Hence, $\sigma (\alpha _1),\ldots ,\sigma (\alpha _{k-1}$ ) are multiplicatively independent, implying that $\alpha _1^t,\ldots , \alpha _{k-1}^t$ are multiplicatively independent. Thus, $\log _p(\alpha _1^t),\ldots ,\log _p(\alpha _{k-1}^t)$ are linearly independent over $\mathbb {Z}$ and hence linearly independent over the algebraic numbers by Theorem 2.3.

Suppose $G'(0)=\sum _{i=0}^{k}({1}/{q(\alpha _i)})\log _p(\alpha _i^t)=0$ . Since $\log _p(\alpha _k^t)=-\log _p(\alpha _1^t)-\cdots -\log _p(\alpha _k^t)$ as the product of the roots is $-1$ and t is even, we obtain

$$ \begin{align*} \sum_{i=1}^{k-1} \bigg(\frac{1}{q(\alpha_i)}-\frac{1}{q(\alpha_k)}\bigg)\log_p(\alpha_i^t)=0. \end{align*} $$

By linear independence of $\log _p(\alpha _1^t),\ldots ,\log _p(\alpha _{k-1}^t)$ , we have ${1}/{q(\alpha _1)}=\cdots = {1}/{q(\alpha _k)}=c$ , for some p-adic number c. This gives k distinct roots $\alpha _1,\ldots ,\alpha _k$ of the ( $k-1$ )-degree polynomial $q(x)-{1}/{c}$ , which is not possible.Therefore, $G'(0)\neq 0$ . Since

$$ \begin{align*} G(z)=\sum_{j=0}^\infty\frac{G^{(\,j)}(0)}{j!}z^{\,j} \end{align*} $$

converges at $z=1$ , it follows that $\|{G^{(\,j)}(0)}/{j!}\|_p\rightarrow 0$ . Hence, there exists an integer $\ell $ such that $\nu _p(G^{(\,j)}(0)/j!)\geq -\ell $ for all j. Thus, we obtain $G(mp^h)=G'(0)mp^h+d$ where $\nu _p(d)\geq 2h-\ell $ for all $m,h\geq 0$ . Also, $G(0)=0$ for $h>h_0:=\ell +\nu _p(G'(0))$ and hence

$$ \begin{align*} \nu_p\bigg( \frac{G(mp^h)}{G(p^h)}-m\bigg)\geq h-h_0. \end{align*} $$

This yields

$$ \begin{align*} \lim_{h\rightarrow\infty}\bigg\lVert\frac{G(mp^h)}{G(p^h)}-m\bigg\rVert_p=0, \end{align*} $$

and hence $R(G(n)_{n\geq 0})$ is p-adically dense in $\mathbb {N}$ . Since $x_{nt}=G(n),n\geq 0$ , we find that $R((x_n)_{n\geq 0})$ is also p-adically dense in $\mathbb {N}$ . Therefore, by Lemma 2.2, $R((x_n)_{n\geq 0})$ is dense in $\mathbb {Q}_p$ .

Proof of Corollary 1.4.

Since $p(1)p(-1){\kern-1pt}={\kern-1pt}(-a{\kern-1pt}-{\kern-1pt}b)(b{\kern-1pt}-{\kern-1pt}a{\kern-1pt}-{\kern-1pt}2){\kern-1pt}>{\kern-1pt}0$ and $p(0){\kern-1pt}=-1$ , by continuity of the polynomial function in $\mathbb {R}$ , $p(x)$ has one real root with absolute value greater than 1 and two other roots with absolute values less than $1$ . Hence, the characteristic polynomial has a root $\pm \alpha$ , where $\alpha$ is a Pisot number, and the corollary follows from Theorem 1.3.

We need the following result to prove Theorem 1.7.

Corollary 3.2 [Reference Cîrnu9, Corollary 2.2].

The linear recurrence relation $x_{n+1}=x_n+2x_{n-1}+\cdots +nx_1+(n+1)x_0,n\geq 0$ , with the initial data $x_0=1$ has the solution

$$ \begin{align*}x_n=\frac{1}{\sqrt{5}}\bigg({\bigg(\frac{3+\sqrt{5}}{2}\bigg)}^n-{\bigg(\frac{3-\sqrt{5}}{2}\bigg)}^n\bigg),\quad n\geq 1.\end{align*} $$

Proof of Theorem 1.7.

By Corollary 3.2, for $n\geq 1$ ,

$$ \begin{align*} x_n=\frac{1}{\sqrt{5}}\bigg({\bigg(\frac{3+\sqrt{5}}{2}\bigg)}^n-{\bigg(\frac{3-\sqrt{5}}{2}\bigg)}^n\bigg) =\frac{\alpha^{2n}-\beta^{2n}}{\sqrt{5}} =F_{2n}, \end{align*} $$

where $\alpha ={(1+\sqrt {5})}/{2}, \beta ={(1-\sqrt {5})}/{2}$ and $F_n$ denotes the nth Fibonacci number which is obtained by the Binet formula. From [Reference Garcia and Luca14], the ratio set of the Fibonacci numbers is dense in $\mathbb {Q}_p$ for all primes p. Therefore, by Lemma 2.1, $\nu _p(F_n)$ is not bounded. Hence, for any $j\in \mathbb {N}$ , there exists $F_m$ such that $\nu _p(F_m)\geq j$ , that is, ${(\alpha ^{m}-\beta ^{m})}/{\sqrt {5}}\equiv 0 \pmod {p^{\,j}}$ which gives $\alpha ^m\equiv \beta ^m\pmod {p^{\,j}}$ . This yields

$$ \begin{align*} \alpha^{2mp^{\,j-1}(p-1)}=(\alpha^m\alpha^m)^{p^{\,j-1}(p-1)}\equiv(\alpha^m\beta^m)^{p^{\,j-1}(p-1)}\pmod{p^{\,j}}. \end{align*} $$

Since $\alpha \beta =-1$ , by using Euler’s theorem, we find that

$$ \begin{align*} \alpha^{2mp^{\,j-1}(p-1)}\equiv(\alpha^m\beta^m)^{p^{\,j-1}(p-1)}\equiv1\pmod{p^{\,j}}. \end{align*} $$

This gives $\alpha ^{2k}\equiv \beta ^{2k}\equiv 1\pmod {p^{\,j}}$ , where $k=mp^{\,j-1}(p-1)$ . Hence,

$$ \begin{align*} \frac{x_{kn}}{x_{k}}=\frac{F_{2kn}}{F_{2k}}=\frac{(\alpha^{2k})^n-(\beta^{2k})^n}{\alpha^{2k}-\beta^{2k}}=(\alpha^{2k})^{(n-1)}+(\alpha^{2k})^{n-2}\beta^{2k}+\cdots+(\beta^{2k})^{n-1}, \end{align*} $$

which is congruent to n modulo $p^{\,j}$ . Since, for $n\in \mathbb {N}$ , there exists $k\in \mathbb {N}$ such that $\|{x_{kn}}/{x_k}-n\|_p\leq p^{-j}$ , $R((x_n)_{n\geq 0})$ is p-adically dense in $\mathbb {N}$ . Therefore, by Lemma 2.2, $R((x_n)_{n\geq 0})$ is dense in $\mathbb {Q}_p$ .

We need the following results to prove Theorem 1.8.

Theorem 3.3 [Reference Cîrnu9, Theorem 3.1].

The numbers $x_n$ are solutions of the linear recurrence relation with constant coefficients in geometric progression $x_{n+1}=ax_n+aqx_{n-1}+\cdots +aq^{n-1}x_1+aq^nx_0,n\geq 0$ , with initial data $x_0$ , if and only if they form the geometric progression given by the formula $x_n=ax_0(a+q)^{n-1},n\geq 1$ .

Lemma 3.4 [Reference Garcia, Hong, Luca, Pinsker, Sanna, Schechter and Starr13, Lemma 2.2].

If A is a geometric progression in $\mathbb {Z}$ , then $R(A)$ is not dense in any $\mathbb {Q}_p$ .

Proof of Theorem 1.8.

By Theorem 3.3, $(x_n)_{n\geq 1}$ forms a geometric progression whose nth term is $ax_0(a+r)^{n-1}$ for $n\geq 1$ . Hence, by Lemma 3.4, $R((x_n)_{n\geq 0})$ is not dense in $\mathbb {Q}_p$ for any prime p.

To prove Theorem 1.9 we need some results on the uniform distribution of sequences of integers. Recall that a sequence $(x_n)_{n\geq 0}$ is said to be uniformly distributed modulo m if each residue occurs equally often, that is,

$$ \begin{align*}\lim_{N\rightarrow\infty}\frac{\# \{n\leq N \mid x _n\equiv t \pmod{m}\}}{N}=\frac{1}{m} \quad\mbox{for all } t\in\mathbb{Z}.\end{align*} $$

Proposition 3.5 [Reference Bumby8, Proposition 1].

Suppose $(G_n)_{n\ge 0}$ is the sequence of integers determined by the recurrence relation $G_{n+1}=AG_n-BG_{n-1}$ with initial values $G_0,G_1$ where $A,B,G_0,G_1\in \mathbb {Z}$ . If $A=2a,B=a^2$ , then $(G_n)_{n\ge 0}$ is uniformly distributed modulo a prime p if and only if $p\nmid a(G_1-aG_0)$ .

Theorem 3.6 [Reference Bumby8, Theorem].

Suppose $(G_n)_{n\ge 0}$ is the sequence of integers determined by the recurrence relation $G_{n+1}=AG_n-BG_{n-1}$ with initial values $G_0,G_1$ where $A,B,G_0,G_1\in \mathbb {Z}$ . If $(G_n)_{n\ge 0}$ is uniformly distributed modulo p, then $(G_n)_{n\ge 0}$ is uniformly distributed modulo $p^h$ with $h>1$ if and only if

  1. (1) $p>3$ ; or

  2. (2) $p=3$ and $A^2\not \equiv B\pmod {9}$ ; or

  3. (3) $p=2, A\equiv 2\pmod {4},B\equiv 1\pmod {4}$ .

Proof of Theorem 1.9.

Let p be a prime. The given recurrence sequence $(x_n)_{n\geq 0}$ satisfies the hypotheses of Proposition 3.5, and hence $(x_n)_{n\geq 0}$ is uniformly distributed modulo p. If $p>3$ , then by Theorem 3.6(1), $(x_n)_{n\geq 0}$ is uniformly distributed modulo $p^k$ with $k>1$ , that is,

$$ \begin{align*}\lim_{N\rightarrow\infty}\frac{\# \{n\leq N\mid x _n\equiv t \pmod{p^k}\}}{N}=\frac{1}{p^k}>0.\end{align*} $$

Therefore, for all $t\in \mathbb {N}$ and for all $k>1$ , there exists $x_n$ such that $\| x_n-t\|_p\leq p^{-k}$ . Hence, $R((x_n)_{n\geq 0})$ is p-adically dense in $\mathbb {N}$ . Therefore, by Lemma 2.2, $R((x_n)_{n\geq 0})$ is dense in $\mathbb {Q}_p$ .

We next consider the remaining primes $p=2,3$ . Since $p\nmid a(x_1-ax_0)$ , we have $p\nmid a$ . It is easy to check that $p=3$ satisfies the condition given in Theorem 3.6(2) and $p=2$ satisfies the condition given in Theorem 3.6(3). The rest of the proof follows similarly as shown in the case $p>3$ . This completes the proof of the theorem.

We need the following lemma to prove Theorem 1.10.

Lemma 3.7 [Reference Sanna26, Lemma 3.3].

Let $(r_n)_{n\geq 0}$ be a linearly recurring sequence of order $k\geq 2$ given by $r_n=a_1r_{n-1}+\cdots +a_k r_{n-k}$ for each integer $n\geq k$ , where $r_0,\ldots ,r_{k-1}$ and $a_1,\ldots ,a_k$ are all integers. Suppose that there exists a prime number p such that $p\nmid a_k$ and $\min \{\nu _p(a_j):1\leq j<k\}>\max \{\nu _p(r_m)-\nu _p(r_n):0\leq m,n<k\}$ . Then $\nu _p(r_n)=\nu _p(r_{n\pmod {k}})$ for each nonnegative integer n.

Proof of Theorem 1.10.

By Lemma 3.7,

$$ \begin{align*} \nu_p(x_n/x_m)=\nu_p(x_{n\pmod{k}})-\nu_p(x_{m\pmod{k}})\leq M \end{align*} $$

for all $n,m\in \mathbb {N}\cup \{0\}$ , where $M=\max \{\nu _p(x_i):i=0,1,\ldots ,k-1\}$ . Therefore, by Lemma 2.1, $R((x_n)_{n\geq 0})$ is not dense in $\mathbb {Q}_p$ .

Acknowledgements

We are very grateful to the referee for a careful reading of the paper and for comments which helped us to make improvements. We thank Piotr Miska for many helpful discussions.

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