5040 (number)

5039 5040 5041
Cardinal five thousand forty
Ordinal 5040th
(five thousand and fortieth)
Factorization 24× 32× 5 × 7
Divisors 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12, 14, 15, 16, 18, 20, 21, 24, 28, 30, 35, 36, 40, 42, 45, 48, 56, 60, 63, 70, 72, 80, 84, 90, 105, 112, 120, 126, 140, 144, 168, 180, 210, 240, 252, 280, 315, 336, 360, 420, 504, 560, 630, 720, 840, 1008, 1260, 1680, 2520, 5040
Roman numeral VXL
Binary 10011101100002
Ternary 202202003
Quaternary 10323004
Quinary 1301305
Senary 352006
Octal 116608
Duodecimal 2B0012
Hexadecimal 13B016
Vigesimal CC020
Base 36 3W036

5040 is a factorial (7!), a superior highly composite number, a colossally abundant number, and the number of permutations of 4 items out of 10 choices (10 × 9 × 8 × 7 = 5040).

Philosophy

Plato mentions in his Laws that 5040 is a convenient number to use for dividing many things (including both the citizens and the land of a state) into lesser parts. He remarks that this number can be divided by all the (natural) numbers from 1 to 12 with the single exception of 11 (however, it is not the smallest number to have this property; 2520 is). He rectifies this "defect" by suggesting that two families could be subtracted from the citizen body to produce the number 5038, which is divisible by 11. Plato also took notice of the fact that 5040 can be divided by 12 twice over. Indeed, Plato's repeated insistence on the use of 5040 for various state purposes is so evident that it is written, "Plato, writing under Pythagorean influences, seems really to have supposed that the well-being of the city depended almost as much on the number 5040 as on justice and moderation."[1]

Jean-Pierre Kahane has suggested that Plato's use of the number 5040 marks the first appearance of the concept of a highly composite number.[2]

Number theoretical

If \sigma(n) is the divisor function and \gamma is the Euler–Mascheroni constant, then 5040 is the largest of the known numbers (sequence A067698 in OEIS) for which this inequality holds:

\sigma(n) \geq e^\gamma n\log \log n .

This is somewhat unusual, since in the limit we have:

\limsup_{n\rightarrow\infty}\frac{\sigma(n)}{n\ \log \log n}=e^\gamma.

Guy Robin showed in 1984 that the inequality fails for all larger numbers if and only if the Riemann hypothesis is true.

Interesting notes

Notes

  1. Laws, by Plato at Project Gutenberg; retrieved 7 July 2009
  2. Kahane, Jean-Pierre (February 2015), "Bernoulli convolutions and self-similar measures after Erdős: A personal hors d'øeuvre", Bulletin of the American Mathematical Society 62 (2): 136–140.
  3. City of Revelation: On the Proportions and Symbolic Numbers of the Cosmic Temple, by John Michell (ISBN 0-345-23607-6), p. 61.

External links

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