Abstract Generated abstract
The paper studies binary additive representations involving primes, principally integers of the form n = p1 + p2^p3, where p1 and p3 are prime and p2 is a fixed prime. Using estimates based on the Brun-Schnirelmann sieve and an identity of Romanov, it derives an asymptotic formula for the number of representable integers up to 2N under natural bounds on the summands. The main result shows that almost all such representations are unique, in the sense that the number represented in exactly one way is asymptotic to the total number represented. A related theorem extends the argument to representations n = p + a^m with fixed a and exponents m running over kth powers, k at least 2.
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MATHEMATICS
A. F. LAVRIK
ADDITION OF A PRIME NUMBER TO A PRIME POWER OF A GIVEN PRIME
(Presented by Academician I. M. Vinogradov on 19 XII 1957)
§ 1. In the present paper we consider certain additive problems of binary type with prime numbers. In particular, we solve the question of the number of integers \(n\), not exceeding a given bound, for which the equation
\[ n=p_1+p_2^{p_3} \tag{1} \]
is soluble in primes \(p_1, p_2, p_3\), where \(p_2\) is fixed.
Theorem 1. “Almost” all numbers of the sequence \(p_1+p_2^{p_3}\), where \(p_1, p_2\) independently run through prime numbers and \(p_2\) is a fixed prime, are distinct.
In other words, the number of integers representable in the form (1) in more than one way has a smaller order of growth in comparison with the number of integers representable in the form (1), but in only one way.
A more precise fact is supplied by the following theorem.
Theorem 2. Let \(Q(p_2,N)\) be the number of all integers \(n\leqslant 2N\) representable in the form (1) with \(p_1\leqslant N\), \(p_2^{p_3}\leqslant N\); let \(F(p_2,N)\) be the number of those among them which are representable in only one way. The symbol \(\sim\) denotes the sign of asymptotic equality.
Then we have:
\[ Q(p_2,N)=\frac{N}{\ln p_2\cdot \ln\ln N} +O\left(\frac{N\ln\ln\ln N}{\ln p_2\cdot \ln^2\ln N}\right), \]
\[ F(p_2,N)\sim Q(p_2,N). \tag{2} \]
Let us note here that the sequence \(p_1+p_2^{p_3}\) differs essentially from the sequence \(p_1+p_2^m\), \(m=1,2,\ldots\), studied in papers \((^1,^3,^4)\), and for this latter sequence, generally speaking, theorems analogous to Theorems 1 and 2 do not hold.
§ 2. We outline the proof of Theorem 2. Denoting by \(R(n,p_2)\) the number of solutions of equation (1), we estimate the quantities \(Q(p_2,N)\) and \(F(p_2,N)\) from below. We have
\[ Q(p_2,N)\geqslant F(p_2,N) =\sum_{n\leqslant 2N} R(n,p_2) -\sum_{\substack{n\leqslant 2N\\ R(n,p_2)\geqslant 2}} R(n,p_2) \geqslant \]
\[ \geqslant \sum_{n\leqslant 2N} R(n,p_2) -\sum_{n\leqslant 2N} R(n,p_2)\{R(n,p_2)-1\}. \tag{3} \]
Let \(S(n)\) be equal to the number of solutions of the equation \(n=p_i-p_j\) in prime numbers \(p_i,p_j\), under the condition \(p_i\leqslant N\), \(p_j\leqslant N\), and let us use identity (2) of the paper of N. P. Romanov \((^1)\). This identity in the present case can be
can be written in the form
\[ \sum_{n\leqslant 2N} R^2(n,p_2) = \sum_{n\leqslant 2n} R(n,p_2) +2\sum_{1<n=p_2^{q_1}-p_2^{q_2}\leqslant N} S(n), \tag{4} \]
where \(q_1,q_2\) run through the prime numbers.
From (3) and (4) it now follows that
\[ Q(p_2,N)\geqslant F(p_2,N)\geqslant \sum_{n\leqslant 2N} R(n,p_2) - 2\sum_{1<n=p_2^{q_1}-p_2^{q_2}\leqslant N} S(n). \tag{5} \]
In what follows let \(c,c_1,c_2,\ldots\) denote certain absolute constants.
We turn to estimates of the sums entering into inequality (5). According to the well-known theorem of Viggo Brun—Schnirelmann \((^2)\),
\[ S(n)<c\,\frac{N}{\ln^2 N}\,f(n), \qquad f(n)=\prod_{p\mid n}\left(1+\frac1p\right), \tag{6} \]
where \(p\) runs through the prime divisors of \(n\).
On the basis of estimate (6) we obtain
\[ \sum_{1<n=p_2^{q_1}-p_2^{q_2}\leqslant N} S(n) < c\,\frac{N}{\ln^2 N} \sum_{q_2<q_1\leqslant \ln N/\ln p_2} f\!\left(p_2^{q_1}-p_2^{q_2}\right) = \tag{7} \]
\[ = c\,\frac{N}{\ln^2 N}\,f(p_2) \sum_{q_2<q_1\leqslant \ln N/\ln p_2} f\!\left(p_2^{q_1-q_2}-1\right) \leqslant \frac32\,c\,\frac{N}{\ln^2 N} \sum_{q_2<q_1\leqslant \ln N/\ln p_2} f\!\left(p_2^{q_1-q_2}-1\right). \]
Next put \(h=q_1-q_2\), where \(q_2<q_1\) are prime numbers and
\[ q_2,q_1\leqslant \ln N/\ln p_2. \tag{8} \]
Then for every \(h\) satisfying \(1\leqslant h\leqslant \ln N/\ln p_2\), again applying the result of Viggo Brun’s “sieve”—estimate (6), we find that the number of solutions of equation (8) does not exceed
\[ c\,\frac{\ln N}{\ln p_2\cdot \ln^2 \frac{\ln N}{\ln p_2}} \left\{ \max_{h\leqslant \ln N/\ln p_2} \prod_{p\mid h}\left(1+\frac1p\right) \right\} < c_2\, \frac{\ln N\cdot \ln\ln\ln N}{\ln p_2\cdot \ln^2 \frac{\ln N}{\ln p_2}}. \]
Therefore from (7) we obtain
\[ \sum_{1<n=p_2^{q_1}-p_2^{q_2}\leqslant N} S(n) < c_0\, \frac{N\ln\ln\ln N}{\ln N\cdot \ln p_2\cdot \ln^2 \frac{\ln N}{\ln p_2}} \sum_{1\leqslant h\leqslant \ln N/\ln p_2} f(p_2^h-1). \tag{9} \]
To estimate the last sum we introduce the notation: \(\delta(k,p_2)\) is the exponent to which the number \(p_2\) belongs modulo \(k\), \(\mu(k)\) is the Möbius function, \(\varphi(k)\) is Euler’s function, \(l=\delta(d,p_2)\).
We now get
\[ \sum_{1\leqslant h\leqslant \ln N/\ln p_2} f(p_2^h-1) < c_4\sum_{1\leqslant k\leqslant N}\frac{\mu^2(k)}{k} \sum_{\substack{1\leqslant h\leqslant \ln N/\ln p_2\\ p_2^h\equiv 1\pmod{k}}}1 < c_5\,\frac{\ln N}{\ln p_2} \sum_{1\leqslant k\leqslant N} \frac{\mu^2(k)}{k\,\delta(k,p_2)}. \]
The series on the right, as N. P. Romanov \((^1)\) proved, converges. Moreover, if one puts
\[ \sigma(l,p_2)= \sum_{\substack{p_2^l\equiv 1\pmod d,\; l\mid \varphi(d)}} \frac{\mu^2(d)}{d}, \]
then the following inequalities hold:
\[ \sum_{1\le k\le N}\frac{\mu^2(k)}{k\delta(k,p_2)} < c_6\sum_{l=1}^{\infty}\frac{\sigma(l,p_2)}{l} < c_7\ln^2\ln 2p_2. \]
The proof of the last of these inequalities is rather complicated and can be obtained by the method of paper \((^1)\).
Thus we find:
\[ \sum_{1\le h\le \ln N/\ln p_2} f\left(p_2^h-1\right) < c_8\frac{\ln N\cdot \ln^2\ln 2p_2}{\ln p_2}. \]
Combining this estimate with inequality (9), we obtain
\[ \sum_{1<n-p_2^{q_1}-p_2^{q_2}\le N} S(n) < c_9 \frac{N\ln\ln\ln N\cdot \ln^2\ln 2p_2} {\ln^2\frac{\ln N}{\ln p_2}\cdot \ln^2 p_2}. \tag{10} \]
To estimate the first sum in (5), introduce the notation: \(\pi(x)\) is the number of primes \(\le x\), and \(P(x)\) is the number of numbers \(p_2^{p_3}\le x\).
Applying the prime number theorem, we shall have
\[ \sum_{n\le 2N} R(n,p_2) = \pi(N)P(N) = \frac{N}{\ln p_2\cdot \ln\frac{\ln N}{\ln p_2}} + O\left(\frac{N}{\ln p_2\cdot \ln N}\right). \tag{11} \]
Collecting the estimates (5), (10), and (11), we obtain
\[ F(p_2,N) \ge \frac{N}{\ln p_2\cdot \ln\frac{\ln N}{\ln p_2}} + O\left( \frac{N\ln\ln\ln N} {\ln p_2\cdot \ln^2\frac{\ln N}{\ln p_2}} \right). \tag{12} \]
On the other hand, obviously we have
\[ F(p_2,N)\le Q(p_2,N)\le \sum_{n\le 2N} R(n,p_2), \tag{13} \]
so that from (10)—(13) we finally obtain formula (2). Theorem 2 is thereby proved.
§ 3. Similar considerations also make it possible to obtain the following nontrivial generalization of the results of paper \((^4)\).
Theorem 3. Let \(J_k(a,N)\) be the number of numbers \(n\le 2N\) representable in the form
\[ n=p+a^m, \tag{14} \]
where \(p\) is prime; \(a\ge 2\) is a given integer; \(m=1^k,2^k,\ldots;\ k\ge 2\) is an arbitrary fixed integer; \(p\le N;\ a^m\le N\). Let \(G_k(a,N)\) be the number of those numbers which are representable in the form (14) in only one way. Then we have:
\[ G_k(a,N)\sim J_k(a,N), \]
\[ J_k(a,N)= \frac{N}{(\ln N)^{1-1/k}\ln^{1/k} a} + O\left( \frac{N}{\ln^{1-\varepsilon}N\cdot \ln^{1/k}a} \right), \]
where \(\varepsilon>0\) is an arbitrarily small constant.
Tashkent State Pedagogical Institute
named after Nizami
Received
16 XII 1957
CITED LITERATURE
\(^1\) N. P. Romanov, Uspekhi Mat. Nauk, vol. 7, 47 (1940).
\(^2\) L. G. Shnirelman, Uspekhi Mat. Nauk, vol. 7, 7 (1940).
\(^3\) E. Landau, Acta Arithmet., 1, 43 (1935).
\(^4\) A. F. Lavrik, Dokl. Akad. Nauk SSSR, 115, No. 3, 445 (1957).