where x = \sqrt{log n log log n}, and c₁, c₂ are absolute constants (say 8, {1 \over 2 5}
Define for any m

The author proves that all but O(ne^-c₃x) of the primitive abundant numbers m \leq n satisfy: (1) q_m < e ^{1/₈ x}, (2) the greates prime factor of m is > e^x. It is then shown that these primitive abundant numbers satisfy also (a) s_m has a divisor D_m between ¹/₂ e ^{1/₂ x} and ¹/₂ e ^{1/₈ x}, (b) 2 \leq \sigma (m)/m < 2+2^{e^{-x}}. [\sigma (m) = sum of divisors of m]. Now, as in the previous paper, it follows that the numbers s_m/D_m are all different and \leq 2n e^{- 1/₈ x}. This gives the upper bound for N(n).
To obtain the lower bound, the author considers numbers of the form 2^lp₁...p_k, where p₁,...p_k are any k different primes between (k-1)2^l+1 and k2^l+1, and

These numbers are all primitive abundant, and an application of the prime-number theorem shews that there areat least ne^-8x of them.
Reviewer:  Davenport (Cambridge)
Classif.:  * 11A25 Arithmetic functions, etc.
                   11N25 Distribution of integers with specified multiplicative constraints
Index Words:  number theory

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