On the density of integer points on generalised Markoff–Hurwitz and Dwork hypersurfaces

We use bounds of mixed character sums modulo a square-free integer q of a special structure to estimate the density of integer points on the hypersurf...

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Math. Z. (2016) 282:935–954 DOI 10.1007/s00209-015-1571-z

Mathematische Zeitschrift

On the density of integer points on generalised Markoff–Hurwitz and Dwork hypersurfaces Mei-Chu Chang1 · Igor E. Shparlinski2

Received: 20 August 2014 / Accepted: 29 September 2015 / Published online: 7 November 2015 © Springer-Verlag Berlin Heidelberg 2015

Abstract We use bounds of mixed character sums modulo a square-free integer q of a special structure to estimate the density of integer points on the hypersurface f 1 (x1 ) + · · · + f n (xn ) = ax1k1 . . . xnkn for some polynomials f i ∈ Z[X ] and nonzero integers a and ki , i = 1, . . . , n. In the case of f 1 (X ) = · · · = f n (X ) = X 2 and k1 = · · · = kn = 1 the above hypersurface is known as the Markoff–Hurwitz hypersurface, while for f 1 (X ) = · · · = f n (X ) = X n and k1 = · · · = kn = 1 it is known as the Dwork hypersurface. Our results are substantially stronger than those known for general hypersurfaces. Keywords

Integer points on hypersurfaces · Multiplicative character sums · Congruences

Mathematics Subject Classification

11D45 · 11D72 · 11L40

1 Introduction Studying the density of integer and rational points (x1 , . . . , xn ) on hypersurfaces has always been an active area of research, where many rather involved methods have led to remarkable

B

Igor E. Shparlinski [email protected] Mei-Chu Chang [email protected]

1

Department of Mathematics, University of California, Riverside, CA 92521, USA

2

Department of Pure Mathematics, University of New South Wales, Sydney, NSW 2052, Australia

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achievements, see [5,6,14,15,21,22,25,26,28] and references therein. More precisely, given a hypersurface F(x1 , . . . , xn ) = 0 defined by a polynomial F ∈ Z[X 1 , . . . , X n ] in n variables, the goal is to estimate the number N F (B) of solutions (x1 , . . . , xn ) ∈ Zn that fall in a hypercube B of the form B = [u 1 + 1, u 1 + h] × · · · × [u n + 1, u n + h].

(1)

Unfortunately, even in the most favourable situation, for some natural classes of polynomials, the currently known general approaches lead only to a bound of the form N F (B) = O h n−2+ε for any fixed ε > 0 or even weaker, see [6,15,25,26]. For some special types of hypersurfaces the strongest known bounds are due Heath-Brown [14] and Marmon [21,22]. For example, for hypercubes around the origin, Marmon [22] gives a bound of the form N F (B) = O h n−4+δn for a class of hypersurfaces, with some explicit function δn such that δn ∼ 37/n as n → ∞. Combining this bound with some previous results and methods, for a certain class of hypersurfaces, Marmon [22] also derives the bound N F (B) = O h n−4+δn + h n−3+ε which holds for an arbitrary hypercube B with any fixed ε > 0 and the implied constant that depends only of deg F, n and ε (note that δn > 1 for n < 29). Finally, we also recall that when the number of variables n is exponentially large compared to d and the highest degree form of F is nonsingular, then the methods developed as the continuation of the work of Birch [4] lead to much stronger bounds, of essentially optimal order of magnitude. Here, we show that in some interesting special cases, to which further developments of [4] do not apply (as the highest degree form is singular and the number of variables is not large enough) a modular approach leads to stronger bounds where the saving actually grows with n (at a logarithmic rate). More precisely we concentrate on hypersurfaces of the form f 1 (x1 ) + · · · + f n (xn ) = ax1k1 . . . xnkn

(2)

defined by some polynomials f i ∈ Z[X ] and nonzero integers a and ki , i = 1, . . . , n. In particular, we use Na,f,k (B) to denote the number of integer solutions to (2) with (x1 , . . . , xn ) ∈ B, where f = ( f 1 , . . . , f n ) and k = (k1 , . . . , kn ). In the case of f 1 (X ) = · · · = f n (X ) = X 2 and k1 = · · · = kn = 1,

(3)

Eq. (2) defines the Markoff–Hurwitz hypersurface , see [1–3,7], where various questions related to these hypersurfaces have been investigated. Furthermore, for f 1 (X ) = · · · = f n (X ) = X n and k1 = · · · = kn = 1,

(4)

Eq. (2) is known as the Dwork hypersurface, which has been intensively studied by various authors [12,13,18,19,30], in particular, as an example of a Calabi–Yau variety. We remark that solutions with at least one component xi = 0, i = 1, . . . , n, correspond to solutions of a diagonal equation n j=1 j =i

123

f j (x j ) = − f i (0)

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to which one can hope to apply the standard circle method. To clarify our ideas and to make the exposition simpler we concentrate here on the solutions ∗ to (2) with x1 . . . xn = 0. In particular, we use Na,f,k (B) to denote the number of such solutions. Clearly for the hypercubes B of the form (1) with u i > 0, i = 1, . . . , n, we have ∗ (B) = Na,f,k (B). Na,f,k

Throughout the paper, the implied constants in the symbols “O”, “” and “ ” may depend on the polynomials deg f i , the coefficient a and the exponents ki in (2), i = 1, . . . , n, and also on the integer positive parameters r and ν. We recall that the expressions A = O(B), A B and B A are each equivalent to the statement that |A| ≤ cB for some constant c. Here, we use some ideas from [27], combined a new bound of mixed character sums, that can be of independent interest, to derive the following result: Theorem 1 For any integer r ≥ 1, there is a constant C(r ) depending only on r , such that, for every integer d ≥ 1 and integer n with n > (d + 1)(d + 2)2r max {2r, 3r − 9/2} + 2, for arbitrary polynomials f 1 (X ), . . . , f n (X ) ∈ Z[X ] of degrees at most d, and odd integers k1 , . . . , kn ≥ 1, uniformly over all boxes B of the form (1) with max |u i | ≤ exp(C(r )h 4/9 )

i=1,...,n

for the solutions to Eq. (2), we have ∗ (B) h n−4r/9 . Na,f,k

The proof of Theorem 1 is based on a bound of mixed character sums which combines the ideas from [9,16]. In particular, in the case of the Markoff–Hurwitz hypersurface (3) the condition on n and r becomes n > 2r max {24r, 36r − 54} + 2. So the value r = 9 is admissible, improving on all previous approaches, provided that n > 138,242. Unfortunately Theorem 1 does not apply to the Dwork hypersurface as the degrees of the polynomials in (4) are too large for our argument to work. So here apply an alternative approach that is based on the method of Postnikov [23,24] (see also [10] and the references therein for further developments). This leads to a much more precise bound which however applies only when the degree of the polynomials f 1 (X ), . . . , f n (X ) are sufficiently large. Theorem 2 There is an absolute constant C such that, for any integers n, r ≥ 1 with n > 2r 3 + 1, for arbitrary polynomials f 1 (X ), . . . , f n (X ) ∈ Z[X ] with min deg f i ≥ r

i=1,...,n

and odd integers k1 , . . . , kn ≥ 1, uniformly over all boxes B of the form (1) with max |u i | ≤ exp(Ch 1/3 )

i=1,...,n

for the solutions to Eq. (2), we have ∗ Na,f,k (B) h n−r/3 .

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In particular, in the case of the Dwork hypersurface (4) we can take r = ((n − 1)/2)1/3 − 1, in Theorem 2, which for n > 3457 leads to values r ≥ 12, also improving on all previous approaches. We remark that Theorems 1 and 2 are very rare examples of the results where the saving against the trivial bound O(h n−1 ) tends to infinity with n. Finally, in some cases the arithmetic structure of the right hand side of Eq. (2) allows to derive a much stronger bound via the result of [8]. We illustrate this in the special case of the equation x1d + · · · + xnd = ax1k1 . . . xnkn and the box B aligned along the main diagonal, that is, of the form B = [u + 1, u + h] × · · · × [u + 1, u + h]

(5)

with some integers u and h. Theorem 3 Let f 1 (X ) = · · · = f n (X ) = X d and let a, k1 , . . . , kn be arbitrary nonzero integers. Then, uniformly over all boxes B of the form (5), for the solutions to the Eq. (2) we have ∗ Na,f,k (B) h d(d+1)/2+o(1) .

2 Some bounds of classical exponential and character sums We denote e(z) = exp(2πi z). We start with recording the following trivial implication of the orthogonality of exponential functions. Lemma 4 For an integer q ≥ 1 and any linear polynomial G(X ) = a X ∈ Z[X ] with gcd(a, q) = 1

H e(G(z)/q) ≤ q. z=1

For quadratic polynomials, we see that [17, Theorem 8.1] yields: Lemma 5 For an integer q ≥ 1 and any quadratic polynomial G(X ) = a X 2 + bX ∈ Z[X ] with gcd(a, q) = 1

H e(G(z)/q) H q −1/2 + q 1/2 log q. z=1

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One of our main tools is the following very special case of a much more general bound of Wooley [29, Theorem 7.3], that applies to polynomials with arbitrary real coefficients. Lemma 6 For any polynomial G(X ) =

s ai i=1

qi

X i ∈ Q[X ]

of degree s ≥ 3 with gcd(ai , qi ) = 1 and positive integer H , for every j = 2, . . . , s we have H σ −1 −j e(G(z)) H 1+o(1) q −1 + H + q H j j z=1

where σ =

1 . 2(s − 1)(s − 2)

Let Xq be the set of ϕ(q) multiplicative characters modulo q, where ϕ(q) is the Euler function. We also denote by Xq∗ = Xq \{χ0 } the set of nonprincipal characters (we set χ(k) = 0 for all χ ∈ Xq and integers k with gcd(k, q) > 1). We appeal to [17] for a background on the basic properties of multiplicative characters and exponential functions, such as orthogonality. We use the following well-known bound that is implied by the Weil bound for mixed sums of additive and multiplicative characters, see [20, Chapter 6, Theorem 3], and a reduction between complete and incomplete sums, see [17, Section 12.2], we also derive the following well-known estimate: Lemma 7 For any χ ∈ X p , λ ∈ F p , nonlinear polynomial F(X ) ∈ F p [X ] and integers u and h ≤ p, we have u+h

χ(x) e(λF(x)) p 1/2 log p

x=u+1

provided that (χ, λ) = (χ0 , 0).

3 Character sums with square-free moduli For a real Q ≥ 3 and an integer r ≥ 1 we denote by Pr (Q) the set of integers q of the form q = p1 . . . pr where p1 , . . . pr ∈ [Q, 2Q] are pairwise distinct primes. Here we obtain a new bound of mixed character sums with multiplicative characters modulo q ∈ Pr (Q) which can be of independent interest. We note that recently several bounds of such sums have been obtained for prime q = p, see [9,16]. However for our applications moduli q ∈ Pr (Q) are more suitable. Our result is based on the bound of [17, Theorem 12.10] and in fact can be considered as its generalisation. As in Sect. 2, we use Xq for the set of ϕ(q) = ( p1 −1) . . . ( pr −1) multiplicative characters modulo q = p1 . . . pr ∈ Pr (Q) and also let Xq∗ = Xq \{χ0 }. Furthermore, we also continue to use e(z) = exp(2πi z). We start with recalling the bound of [17, Theorem 12.10], which we present in a somewhat simplified form adjusted to our applications. In particular, some simplifications come from the fact that the modulus q ∈ Ps (Q) is square-free.

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Lemma 8 Let q = 1 . . . s ∈ Ps (Q) for some primes 1 , . . . , s and let ψ = χ1 . . . χs be a n multiplicative character of conductor q and of order t, where χ j are arbitrary multiplicative characters modulo j , j = 1, . . . , s − 1, and χs is a nontrivial multiplicative character modulo s . Assume f (X ) is a rational function that can be written as f (X ) =

m

(X − vi )di i=1

with some arbitrary integers v1 , . . . , vm and nonzero integers d1 , . . . , dm with gcd(d1 , . . . , dm , t) = 1. Then for any integers u and h with h ≥ (2Q)9/4 , we have u+h 2−s ψ( f (x)) ≤ 4h gcd( , s ) −1 , s x=u+1

where

=

(vi − v j ).

m≥i> j≥1

We are now ready to present one of our main technical results which can be of independent interest. Lemma 9 For any r = 1, 2, . . ., a sufficiently large Q ≥ 1, a modulus q ∈ Pr (Q), a polynomial F(X ) ∈ R[X ] of degree d and integers u and h with h ≥ (2Q)9/4 , we have u+h χ(x) e(F(x)) h Q −γ max∗ χ ∈Xq x=u+1

where γ =

2r +1 (d

1 . + 1)(d + 2)

and the implied constant depends only on d and r . Proof Let us fix some χ ∈ Xq∗ . Without loss of generality we can write χ = χ1 . . . χr , where χ j is a multiplicative character modulo a prime p j , j = 1, . . . , r and χr is a nonprincipal character (as before, we write q = p1 . . . pr for r distinct primes). Set p = p1 . Then for any positive integer M for the sum S=

u+h

χ(x) e(F(x))

x=u+1

we have

u+h M−1 χ(x + py) e(F(x + py)) + 2M p x=u+1 y=0 u+h M−1 1 + 4M Q, ≤ ψ(x + py) e(F(x + py)) M x=u+1 y=0

1 S≤ M

gcd(x, p)=1

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where ψ = χ2 . . . χr . We note that ψ is of conductor q/ p rather that q, so this explains the condition gcd(x, p) = 1 in the sum over x. We can however not simply discard this condition and write u+h M−1 1 (6) S≤ ψ(x + py) e(F(x + py)) + 4M Q. M x=u+1 y=0 We divide the unit cube [0, 1]d+1 into K = M (d+1)(d+2)/2 cells of the form

a0 a0 + 1 ad ad + 1 Ua = , , × ··· × , M M M d+1 M d+1

where a = (a0 , . . . , ad ) ∈ Zd+1 runs through the set A of integer vectors with components aν = 0, . . . , M ν+1 − 1, ν = 0, . . . , d. We now write F(X + pY ) = F0 (X ) + F1 (X )Y + · · · + Fd (X )Y d and define a = {x ∈ {u + 1, . . . , u + h} : (F0 (x), . . . , Fd (x)) ∈ Ua }, a ∈ A. It is easy to see that for x ∈ a we have e(F(x + py)) = E a (y) + O(M −1 ), uniformly over y with |y| ≤ M, where a ad a1 0 E a (y) = e + 2 y + · · · + d+1 y d . M M M Hence we see from (6) that S where

1 W + h/M + Q M, M

(7)

M−1 . ψ(x + py)E (y) W = a a∈A x∈a y=0

We now fix some integer k ≥ 1 and apply the Hölder inequality to W 2k , getting 2k ⎛ ⎞2k−1 M−1 W 2k ≤ ⎝ 1⎠ ψ(x + py)E (y) a a∈A x∈a a∈A x∈a y=0 2k M−1 . = h 2k−1 ψ(x + py)E (y) a a∈A x∈a y=0 Next, we extend the inner summation over the integers x ∈ a to all x ∈ {u + 1, . . . , u + h}. Opening up the 2kth power, changing the order of summations and using that |E a (y)| = 1,

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we derive W 2k

u+h k

x + pyν 2k−1 ≤h ψ x + pyk+ν a∈A y1 ,...,y2k =0 x=u+1 ν=1 k M−1 u+h

x + pyν 2k−1 =h K ψ . x + pyk+ν

M−1

y1 ,...,y2k =0 x=u+1

(8)

ν=1

Now, for O(M k ) vectors (y1 , . . . , y2k ) where each value appears at least twice we estimate the inner sum trivially as h. For the remaining O(M 2k ) vectors (y1 , . . . , y2k ) we apply Lemma 8. More precisely, we use it for s = r − 1 with i = pi+1 . The rational function f (X ) after making all cancellation and combining equal terms becomes of the form f (X ) =

m

(X + pz i )di ,

i=1

where 1 ≤ z 1 < · · · < z m ≤ M and at least one di = ±1. We now assume that M < Q.

(9)

Then we have gcd(z i − z j , pr ) = 1 for m ≥ i > j ≥ 1. Hence, we also see that ⎞ ⎞ ⎛ ⎛

( pz i − pz j ), pr ⎠ = gcd ⎝ (z i − z j ), pr ⎠ = 1. gcd ⎝ m≥i> j≥1

m≥i> j≥1

With the above simplifications, the bound of Lemma 8 becomes u+h k

x + pyν −r+1 ψ . ≤ 4h Q −2 x + pyk+ν x=u+1

ν=1

Therefore, by (8), −r+1 W 2k h 2k−1 K M k h + M 2k h Q −2 −r+1 , = h 2k M (d+1)(d+2)/2 M k + M 2k Q −2 which after the substitution in (7) implies −r S h M (d+1)(d+2)/4k M −1/2 + Q −2 /k + h/M + Q M h M (d+1)(d+2)/4k−1/2 + h M (d+1)(d+2)/4k Q −2

−r /k

+ h 8/9

(since by (9) we have Q M ≤ Q 2 h 8/9 , provided that h ≥ (2Q)9/4 and the term h/M gets −r+1 /k (to balance the first two terms), absorbed in first term). We now choose M = Q 2 so (9) holds, getting S h Q −((d+1)(d+2)/2k−1)2

−r /k

Choosing k = (d + 1)(d + 2) we conclude the proof.

123

+ h 8/9 .

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We remark, that the idea of the proof also works with a simpler shift F(x) → F(x + y), however using the shift F(x) → F(x + py) allows to reduce the conductor (from q to q/ p) and thus leads to a slightly stronger bound as the conductor of ψ is now a product of only r − 1 primes. This idea can be used in more generality leading to stronger bounds for more limited ranges of parameters. We note that we do not impose any conditions on the polynomial F in Lemma 9, which, in particular can be a constant polynomial, in which case, we have the bound of [17, Theorem 12.10].

4 Character sums with prime-power moduli As in Sect. 2, we use Xq for the set of ϕ(q) = pr −1 ( p − 1) multiplicative characters modulo q and let Xq∗ = Xq \{χ0 }. We also continue to use e(z) = exp(2πi z). Since group of units modulo q is cyclic then so is Xq . So we now fix a character χ ∈ Xq that generates this group, so that Xq = {χ μ : μ = 0, . . . , pr −1 ( p − 1) − 1}.

The following result is due to Postnikov [23, Lemma 2] (see also [24]). We present in a form reducing sums of multiplicative character to exponential sums which is more suitable for our applications and is given by [17, Equation (12.89)]. Lemma 10 Assume that q = pr for an integer r ≥ 1 and a prime p > max{2, r }. There exist a polynomial F(Z ) =

r −1

Ak Z k ∈ Z[Z ]

k=1

of degree r − 1 with coefficients satisfying gcd(Ak , p) = 1, k = 1, . . . , r − 1, such that for any integers y and z with gcd(y, p) = 1, we have χ(y + pz) = χ(y) e (F( pwz)/q) , where w is defined by wy ≡ 1

(mod q) and 1 ≤ w < q.

Lemma 11 Assume that q = pr for an integer r ≥ 1 and a prime p > max{2, r }. Then for any polynomial f (X ) ∈ Z[X ] of degree d ≥ r with the leading coefficient ad satisfying gcd(ad , p) = 1, integers u and h with q ≥ h ≥ p 3 and integers λ ∈ {0, . . . , pr − 1} and μ ∈ {0, . . . , ( p − 1) pr −1 − 1} with λ + μ > 0, we have u+h 2 μ χ (x) e(λ f (x)/q) h 1−1/4r , x=u+1

where the implied constant depends only on d.

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Proof Let H = h/ p. Then u+h

χ μ (x) e(λ f (x)/q) = S + O(H ),

(10)

x=u+1

where S=

u+ p

H

χ μ (y + pz) e(λ f (y + pz)/q).

y=u+1 z=0

Therefore, using Lemma 10 we obtain u+ p

S=

χ μ (y) e λ f (y)/ pr

y=u+1 gcd(y, p)=1

×

H

e

r −1

z=0

k=1

1 pr −k

−k (k) k μAk y + λ f (y)/k! z .

(11)

Let ord p t denote the p-adic order of an integer t (where we formally set ord p 0 = ∞). We set m = min{ord p λ, ord p μ}. In particular, for the inner sum over z in (11) we have r −1 H 1 −k (k) k μAk y + λ f (y)/k! z e pr −k z=0 k=1 r −m−1 H 1 ∗ −k ∗ (k) k μ Ak y + λ f (y)/k! z , e = (12) pr −m−k z=0

μ∗

μ/ p m

k=1

λ∗

= and = λ/ p m are integers. where We now consider three different cases. If m = r − 1 then we see from (12) that the inner sum over z in (11) is trivial and thus is equal to H . Note that if pr −1 | μ then χ μ (y) becomes a character modulo p, and it is either a nontrivial character modulo p or gcd(λ∗ , p) = 1). Thus, using Lemma 7, we derive for the sum S S = H

u+ p

χ μ (y) e λ∗ f (y)/ p H p 1/2 log p

y=u+1 gcd(y, p)=1

hp −1/2 log h h 1−1/2r log h.

(13)

If r − 3 ≤ m ≤ r − 2 then we see that the sum (12) is a sum with either linear or quadratic polynomial in z. Let Y be the set of solutions the congruence μ∗ Ar −m−1 y −r +m+1 + λ∗ f (r −m−1) (y)/(r − m − 1)! ≡ 0

(mod p)

where y = u + 1, . . . , u + p, gcd(y, p) = 1. Recalling that gcd(Ar −m−1 , p) = 1 and the condition on the leading coefficient of f , we see that #Y ≤ d. Now, for y ∈ / Y , the sum (12) is

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• either a sum with a linear polynomial and a denominator p (when m = r − 2); • or a sum with a quadratic polynomial and a denominator p 2 (when m = r − 3). Moreover, these polynomials have the leading coefficient which is relatively prime to p. In the case of linear polynomial (that is, m = r − 2), by Lemma 4 we bound this sum as O(p). In the case of a quadratic polynomial (that is, m = r − 3), we bound this sum as O H p −1 + p log p , which dominates the previous bound. Thus, estimating the sum (12) trivially as H for y ∈ Y , we derive S H + p H p −1 + p log p H + p 2 log p h/ p + h 2/3 log h h 1−1/r log h. Finally, assume that m ≤ r − 4. For

r −m j= 2

(14)

≥ 2,

let Y be the set of solutions to the congruence μ∗ A j y − j + λ∗ f ( j) (y)/j! ≡ 0

(mod p),

where y = u + 1, . . . , u + p, gcd(y, p) = 1. Recalling that gcd(A j , p) = 1 and the condition on the leading coefficient of f we see / Y , we estimate the inner sum over z by Lemma 6 with that #Y ≤ d. Furthermore, for y ∈ s = r − m − 1 ≥ 3 and q j = pr −m− j , getting for the sum (12): r −m−1 H 1 ∗ −k ∗ (k) k μ Ak y + λ f (y)/k! z e pr −m−k z=0 k=1 σ H 1+o(1) p −r +m+ j + H −1 + pr −m− j H − j , (15) where σ =

1 . 2(r − m − 2)(r − m − 3)

Since H ≥ p 2 and j ≥ (r − m)/2 we have pr −m− j H − j ≤ pr −m−3 j ≤ p −(r −m)/2 . On the other hand, since j ≤ (r − m + 1)/2, we also have p −r +m+ j ≤ p −(r −m−1)/2 . Therefore, the bound (15) implies that if y ∈ / Y then H r −m−1 1 ∗ −k ∗ (k) k μ Ak y − λ f (y)/k! z e pr −m−k z=0

H

k=1 1+o(1)

( p −(r −m−1)/2 + H −1 )σ .

(16)

We now note that for m ≤ r − 4 we have r −m−1 r −m−1 1 σ = > . 2 4(r − m − 2)(r − m − 3) 4r

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and also 2 1 1 σ = > 2. 3 3(r − m − 2)(r − m − 3) 3r Since p ≥ h 1/r and H h/ p ≥ h 2/3 , we finally derive from (16) that r −m−1 H 1 2 ∗ −k ∗ (k) k μ Ak y − λ f (y)/k! z H h −1/4r . e pr −m−k z=0

(17)

k=1

So, estimating the sum (12) trivially for y ∈ Y and using (17) for y ∈ / Y , we conclude that S H + p H h −1/4r h 1−1/r + h 1−1/4r h 1−1/4r . 2

2

2

(18)

Comparing (13), (14) and (18), we see that the bound (18) dominates, and the result follows.

5 Multiplicative congruences and equations We make use of a result of Cochrane and Shi [11, Theorem 2] that generalises several previous results, which we present in the following slightly less precise form. Lemma 12 For arbitrary integers u and h ≤ q, the number of solutions to wx ≡ yz

(mod q)

in variables w, x, y, z ∈ {u + 1, . . . , u + h} and gcd(wx yz, q) = 1, is bounded by h 4 q −1+o(1) + h 2+o(1) . Note that in Lemma 12 no assumption on the modulus q is made (although we apply it only for q ∈ Pr (Q)). We also need a bound of [8, Proposition 3] on the number of divisors in short intervals. Lemma 13 For any interval I = [u + 1, u + h] with h ≥ 3, u ≥ 0 and integer z ≥ 1, we have log h n #{(x1 , . . . , xn ) ∈ I : z = x1 . . . xn } ≤ exp Cn log log h where Cn is some absolute constant depending only on n.

6 Sets in reduced residue classes For a real Q ≥ 3, a vector k = (k1 , . . . , kn ) ∈ Nn and an integer r ≥ 1 we denote by Pk,r (Q) the set of integers q = p1 , . . . pr ∈ Pr (Q) as in Sect. 3 with the additional condition gcd(k1 . . . kn , p j − 1) = 1, We need the following simple statement

123

j = 1, . . . , r.

(19)

On the density of integer points on generalised…

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Lemma 14 Let H ≥ 3 be a real number and let S be arbitrary set of nonzero integers s with |s| ≤ H . For any vector k ∈ Nn integer r ≥ 1 there exists a constant c(k, r ) depending only on k and r , such that for any sufficiently large real Q ≥ c(k, r ) log H , there exists q ∈ Pk,r (Q) with #{s ∈ S : gcd(s, q) = 1} ≥ Proof We have #{s ∈ S : gcd(s, q) > 1} = q∈Pk,r (Q)

1 #S . 2

1≤r

s∈S q∈Pk,r (Q) gcd(s,q)>1

ω(s)

s∈S

1,

q∈Pk,r−1 (Q)

where as usual, ω(s) denotes the number of prime divisors of s = 0. We now use that, ω(s)

log |s| log H log(2 + log |s|) log log H

(since, trivially ω(s)! ≤ s) and also that by the asymptotic formula for the number of primes in an arithmetic progression, we have ν ν Q Q #Pk,ν (Q) , ν = 1, 2, . . . . log Q log Q provided that Q is large enough, where the implied constants depend of k and ν. Thus, we derive r −1 Q log H #{s ∈ S : gcd(s, q) > 1} #S . log log H log Q q∈Pk,r (Q)

Therefore, 1 #Pk,r (Q)

#{s ∈ S : gcd(s, q) > 1} #S

q∈Pk,r (Q)

log H log Q · log log H Q

and the result now follows.

7 Proof of Theorem 1 Take Q = 0.5h 4/9 . By the condition on B and Lemma 14 [applied to the set of all coordinates ∗ of all Na,f,k (B) solutions] there exists q ∈ Pk,r (Q) such that we have ∗ Na,f,k (B) ≤ 2T,

(20)

where T is the number of solutions to the congruence f 1 (x1 ) + · · · + f n (xn ) ≡ ax1k1 . . . xnkn

(mod q)

(21)

with (x1 , . . . , xn ) ∈ B and gcd(x1 . . . xn , q) = 1. Hence it is now sufficient to estimate T . As before, we use Xq to denote the set of multiplicative characters modulo q and also let Xq∗ = Xq \{χ0 } be the set of nonprincipal characters.

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We now proceed as in the proof of [27, Theorem 3.2]. Let Si (χ; λ) =

u i +h

χ ki (x) e (λ f i (x)/q) , i = 1, . . . , n.

x=u i +1

We also introduce the Gauss sums G(χ, λ) =

q

χ(y) e(λy/q), χ ∈ Xq , λ ∈ Z.

y=1

Clearly, we can assume that at least one of the polynomials f 1 , . . . , f n is not a constant polynomial as otherwise the result is immediate. Without loss of generality, we can now assume that deg f 1 ≥ 1. Furthermore, we can also assume that h is sufficiently large so that gcd(a, q) = 1 and also the leading coefficients of the polynomial f n is relatively prime to q (recall that q is composed out of primes in the interval [Q, 2Q]). We now introduce one more variable y that runs through the reduced residue system modulo q and rewrite (21) as a system of congruences f 1 (x1 ) + · · · + f n (xn ) ≡ y ax1k1

. . . xnkn

≡y

(mod q),

(mod q).

Then exactly as in [27, Equation (3.3)], we write T =

q n

1 G(χ, λ) Si (χ, λ), qϕ(q) λ=1 χ ∈Xq

i=1

where, as before, ϕ(q) is the Euler function and G(χ, λ) is the complex conjugate of the Gauss sum. As in the proof of [27, Theorem 3.2], we see that, under the condition (19), we have: T where R1 =

1 (R1 + R2 ) , qϕ(q)

q

|G(χ, λ)|

λ=1 χ ∈Xq∗

R2 =

q

|Si (χ, λ)|,

i=1

|G(χ0 , λ)|

λ=1

n

(22)

n

|Si (χ0 , λ)|.

i=1

To estimate R1 we first use Lemma 9 for n − 2 sums and infer that R1 h (1−4γ /9)(n−2)

q λ=1 χ ∈Xq∗

where γ is as in Lemma 9.

123

|G(χ, λ)||S1 (χ; λ)||S2 (χ; λ)|,

(23)

On the density of integer points on generalised…

949

Using the Hölder inequality, and then expanding the summation to all χ ∈ Xq , we obtain q

|G(χ, λ)||S1 (χ; λ)||S2 (χ; λ)|

λ=1 χ ∈Xq

≤

q λ=1

⎛ ⎝

⎞1/2 ⎛ |G(χ, λ)|2 ⎠

⎝

χ ∈Xq

⎞1/4 ⎛ |S1 (χ; λ)|4 ⎠

⎝

χ ∈Xq

⎞1/4 |S2 (χ; λ)|4 ⎠

. (24)

χ ∈Xq

Using the orthogonality of multiplicative characters we see that χ ∈Xq

u 1 +h

|S1 (χ; λ)|4 = ϕ(q)

e

w,x,y,z=u 1 +1 gcd(wx yz,q)=1 wx≡yz (mod q)

λ ( f 1 (w) + f 1 (x) − f 1 (y) − f 1 (z)) q

≤ q W, where W is the number of solutions to wx ≡ yz

(mod q)

in variables w, x, y, z ∈ {u 1 + 1, . . . , u 1 + h} and gcd(wx yz, q) = 1. Using Lemma 12, we obtain |S1 (χ; λ)|4 ≤ h 4 q o(1) + h 2+o(1) q. χ ∈Xq

Similarly we obtain the same inequality for the 4th moment of the sums S2 (χ; λ), and also |G(χ, λ)|2 q 2 . χ ∈Xq

Thus, collecting these bounds together which together with (23) and (24), we derive R1 h (1−4γ /9)(n−2) q 2 h 2 q o(1) + h 1+o(1) q 1/2 (25) = h n−4γ (n−2)/9−1 hq 2+o(1) + q 5/2+o(1) . For R2 , using the trivial bound |Si (χ0 ; λ)| ≤ h, i = 1, . . . , n − 1, we write R2 ≤ h n−1

q

|G(χ0 ; λ)||S1 (χ0 ; λ)|.

λ=1

We remark that G(χ0 ; λ) =

q

e(λy/q)

y=1 gcd(y,q)=1

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M.-C. Chang, I. E. Shparlinski

is the Ramanujan sum and thus for a square-free q we obtain |G(χ0 ; λ)| = ϕ(gcd(λ, q)) see [17, Section 3.2]. Collecting together the values of λ with the same gcd(λ, q) = q/s, where s runs over all 2r divisors of q, and then using the Cauchy inequality, we obtain R2 ≤ h n−1 q

s 1 s|q

s

|S1 (χ0 ; μq/s)|

μ=1

u +h 1 1 n−1 e (μf 1 (x)/s) ≤h q s μ=1 x=u 1 +1 s|q gcd(x,q)=1 s

2 ⎞1/2 u +h s 1 1 ⎜ ⎟ ⎟ . ⎜ ≤ h n−1 q e (x)/s) (μf 1 ⎠ ⎝ 1/2 s μ=1 x=u 1 +1 s|q gcd(x,q)=1 ⎛

By the orthogonality of exponential functions, 2 u 1 +h s ≤ sUs . e (x)/s) (μf 1 μ=1 x=u 1 +1 gcd(x,q)=1 Where Us is the number of solutions to the congruence f 1 (x) ≡ f 1 (y)

(mod s), x, y ∈ {u 1 + 1, . . . , u 1 + h}.

Since the leading coefficient of f 1 (X ) is relatively prime to q, using the Chinese Remainder Theorem we obtain Us h 2 /s + h. Collecting the above inequalities, yields the bound 1 1/2 R2 h n−1 q ≤ h n q. h 2 + hs s 1/2

(26)

s|q

Substituting the bounds (25) and (26) in (22) and using that ϕ(q) q for q ∈ Pk,r (Q) and also that q h 4r/9 q we obtain T h n−4γ (n−2)/9−1 h + q 1/2 q o(1) + h n q −1 h n−4γ (n−2)/9 + h n−4γ (n−2)/9−1+2r/9 q o(1) + h n−4r/9 . (27) Clearly, if −4γ (n − 2)/9 < −4r/9 and

− 4γ (n − 2)/9 − 1 < −2r/3

or, equivalently

n > max 2r +1 (d + 1)(d + 2)r, 2r +1 (d + 1)(d + 2)(3r/2 − 9/4) + 2,

then the last term dominates in (27). Using (20) we conclude the proof.

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8 Proof of Theorem 2 Take Q = 0.5h 1/3 . By the condition on B and Lemma 14 [applied to the set of all ∗ coordinates of all Na,f,k (B) solutions and the set Pk,1 (Q)] there exists a prime p ∈ [Q, 2Q] with gcd(k1 . . . kn , p − 1) = 1. (28) such that we have the bound (20) where now T is the number of solutions to the congruence f 1 (x1 ) + · · · + f n (xn ) ≡ ax1k1 . . . xnkn

(mod pr )

(29)

with (x1 , . . . , xn ) ∈ B and gcd(x1 . . . xn , p) = 1. Hence it is now sufficient to estimate T . As before, we use X pr to denote the set of multiplicative characters modulo pr and also let X p∗r = X pr \{χ0 } be the set of nonprincipal characters. We now proceed as in the proof of [27, Theorem 3.2]. Let Si (χ; λ) =

u i +h

χ ki (x) e λ f i (x)/ pr , i = 1, . . . , n.

x=u i +1

We also introduce the Gauss sums r

G(χ, λ) =

p

χ(y) e(λy/ pr ), χ ∈ X pr , λ ∈ Z,

y=1

Clearly, we can assume that at least one of the polynomials f 1 , . . . , f n is not a constant polynomial as otherwise the result is immediate. Without loss of generality, we can now assume that deg f 1 ≥ 1. Furthermore, we can also assume that h is sufficiently large so that gcd(a, p) = 1 and also the leading coefficients of the polynomial f n is relatively prime to p (recall that p ∈ [Q, 2Q]). We now introduce one more variable y that runs through the reduced residue system modulo q and rewrite (29) as a system of congruences f 1 (x1 ) + · · · + f n (xn ) ≡ y ax1k1 . . . xnkn ≡ y

(mod pr ),

(mod pr ).

Then exactly as in [27, Equation (3.3)], we write r

p n

1 T = r G(χ, λ) Si (χ, λ), p ϕ( pr ) λ=1 χ ∈X pr

i=1

where, as before, ϕ(q) is the Euler function and G(χ, λ) is the complex conjugate of the Gauss sum. We see that the contribution from the term corresponding to λ = pr and the principal character χ = χ0 is O(h n / pr ). so the under the condition (28), we have: T h n / pr +

1 R pr ϕ( pr )

(30)

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M.-C. Chang, I. E. Shparlinski

where

R=

|G(χ, λ)|

1≤λ≤ pr , χ ∈X pr (λ,χ ) =( pr ,χ0 )

n

|Si (χ, λ)|

i=1

To estimate R we first use Lemma 11 for n − 2 sums and infer that R h (1−1/4r

2 )(n−2)

q

|G(χ, λ)||S1 (χ; λ)||S2 (χ; λ)|.

λ=1 χ ∈Xq∗

We now proceed exactly as in estimating R1 in the proof of Theorem 1, getting instead of (25) the bound 2 R h (1−1/4r )(n−2) p 2r h 2 p o(1) + h 1+o(1) pr/2 . Since h 1/3 p h 1/3 and r ≥ 6, this simplifies as R h (1−1/4r

2 )(n−2)+1+o(1)

p 5r/2

(31)

Substituting the bound (31) in (30), we obtain T h n−1−(n−2)/4r h n−1−(n−2)/4r

2 +o(1)

pr/2 + h n / pr

2 +r/6+o(1)

+ h n−r/3 .

(32)

Clearly, if r3 ≤

n−2 2

or, equivalently n ≥ 2r 3 + 2 then the last term dominates in (32). Using (20) we conclude the proof.

9 Proof of Theorem 3 Clearly for (x1 , . . . , xn ) ∈ B where B is of the form (5) we have x1d + · · · + xnd ∈ Z , where Z=

d d ν=0

ν

z ν u d−ν : z ν ∈ [0, nh ν ], ν = 0, . . . , d .

In particular, #Z h d(d+1)/2 . Applying Lemma 13 to every z ∈ Z , we obtain the result.

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On the density of integer points on generalised…

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10 Comments We remark that Theorem 1 applies to the Markoff–Hurwitz hypersurface corresponding to (3). in which case the condition on n becomes n > 12 · 2r max {2r, 3r − 9/2} + 2. We note that the condition of Theorem 1 requires n to be only quadratic in d, while the saving grows with n as 4 log n > 0.64 log n, 9 log 2 when d is fixed and n tends to infinity. On the other hand, Theorem 1 does not apply to the Dwork hypersurface, but Theorem 2 does and leads to the saving that grows with n as (n/2)1/3 > 0.26n 1/3 . 3 It is also easy to see that our methods also works for a more general form of (2), namely for the equation ( f 1 (x1 ) + · · · + f n (xn ))m = ax1k1 . . . xnkn with a nonzero integer m. Furthermore, one can apply our approach to the variants of Eq. (2) when the left hand side instead of n univariate polynomials in n distinct variables, we have several multivariate polynomials supported on disjoint groups of variables. However the particular details depend on particular properties of these polynomials such as their number, the number of variables each of them depend on, the degrees and also more involved algebraic properties such as nonsingularity. Hence it is difficult to formulate a concise general result. One can easily remove the condition on the parity of k1 , . . . , kn at the cost of essentially only typographical changes. Indeed, if some of k1 , . . . , kn are even that we take all our primes p to satisfy p ≡ 3 (mod 2k1 . . . kn ) instead of (19) and (28), and then we deal with contribution from characters or order 2 as we have done for the principal character. Finally, we note that using the bounds of mixed sums from [16] within our method leads to weaker estimates, but makes them fully uniform with respect to the box B. That is, the conditions on maxi=1,...,n |u i | in Theorems 1 and 2 can be removed at the cost of weakening the final bound. Acknowledgments The authors are grateful to Oscar Marmon for many useful comments and to Roger Heath-Brown and Lillian Pierce for informing them about their work [16] when it was still in progress and then sending them a preliminary draft. The authors also would like to thank the referee for the very careful reading of the manuscript. During the preparation of this paper, the first author was supported by the NSF Grant DMS 1301608 and the second author by the ARC Grant DP130100237. The second author would also to thank CIRM, Luminy, for support and hospitality during his work on this project.

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