21 (number)

Last updated
20 21 22
Cardinal twenty-one
Ordinal 21st
(twenty-first)
Factorization 3 × 7
Divisors 1, 3, 7, 21
Greek numeral ΚΑ´
Roman numeral XXI
Binary 101012
Ternary 2103
Senary 336
Octal 258
Duodecimal 1912
Hexadecimal 1516

21 (twenty-one) is the natural number following 20 and preceding 22.

Contents

The current century is the 21st century AD, under the Gregorian calendar.

Mathematics

Twenty-one is the fifth distinct semiprime, [1] and the second of the form where is a higher prime. [2] It is a repdigit in quaternary (1114).

Properties

As a biprime with proper divisors 1, 3 and 7, twenty-one has a prime aliquot sum of 11 within an aliquot sequence containing only one composite number (21, 11, 1, 0); it is the second composite number with an aliquot sum of 11, following 18. 21 is the first member of the second cluster of consecutive discrete semiprimes (21, 22), where the next such cluster is (33, 34, 35). There are 21 prime numbers with 2 digits. There are A total of 21 prime numbers between 100 and 200.

21 is the first Blum integer, since it is a semiprime with both its prime factors being Gaussian primes. [3]

While 21 is the sixth triangular number, [4] it is also the sum of the divisors of the first five positive integers:

21 is also the first non-trivial octagonal number. [5] It is the fifth Motzkin number, [6] and the seventeenth Padovan number (preceded by the terms 9, 12, and 16, where it is the sum of the first two of these). [7]

In decimal, the number of two-digit prime numbers is twenty-one (a base in which 21 is the fourteenth Harshad number). [8] [9] It is the smallest non-trivial example in base ten of a Fibonacci number (where 21 is the 8th member, as the sum of the preceding terms in the sequence 8 and 13) whose digits (2, 1) are Fibonacci numbers and whose digit sum is also a Fibonacci number (3). [10] It is also the largest positive integer in decimal such that for any positive integers where , at least one of and is a terminating decimal; see proof below:

Proof

For any coprime to and , the condition above holds when one of and only has factors and (for a representation in base ten).

Let denote the quantity of the numbers smaller than that only have factor and and that are coprime to , we instantly have .

We can easily see that for sufficiently large ,

However, where as approaches infinity; thus fails to hold for sufficiently large .

In fact, for every , we have

and

So fails to hold when (actually, when ).

Just check a few numbers to see that the complete sequence of numbers having this property is

21 is the smallest natural number that is not close to a power of two , where the range of nearness is

Squaring the square

The minimum number of squares needed to square the square (using different edge-lengths) is 21. Squaring the Square (minimum).png
The minimum number of squares needed to square the square (using different edge-lengths) is 21.

Twenty-one is the smallest number of differently sized squares needed to square the square . [11]

The lengths of sides of these squares are which generate a sum of 427 when excluding a square of side length ; [a] this sum represents the largest square-free integer over a quadratic field of class number two, where 163 is the largest such (Heegner) number of class one. [12] 427 number is also the first number to hold a sum-of-divisors in equivalence with the third perfect number and thirty-first triangular number (496), [13] [14] [15] where it is also the fiftieth number to return in the Mertens function. [16]

Quadratic matrices in Z

While the twenty-first prime number 73 is the largest member of Bhargava's definite quadratic 17–integer matrix representative of all prime numbers, [17]

the twenty-first composite number 33 is the largest member of a like definite quadratic 7–integer matrix [18]

representative of all odd numbers. [19] [b]

In science

Age 21

In sports

In other fields

Building called "21" in Zlin, Czech Republic Zlin3.jpg
Building called "21" in Zlín, Czech Republic
Detail of the building entrance 21-Batuv mrakodrap.jpg
Detail of the building entrance

21 is:

Notes

  1. This square of side length 7 is adjacent to both the "central square" with side length of 9, and the smallest square of side length 2.
  2. On the other hand, the largest member of an integer quadratic matrix representative of all numbers is 15, where the aliquot sum of 33 is 15, the second such number to have this sum after 16 (A001065); see also, 15 and 290 theorems. In this sequence, the sum of all members is

Related Research Articles

10 (ten) is the even natural number following 9 and preceding 11. Ten is the base of the decimal numeral system, the most common system of denoting numbers in both spoken and written language.

15 (fifteen) is the natural number following 14 and preceding 16.

20 (twenty) is the natural number following 19 and preceding 21.

33 (thirty-three) is the natural number following 32 and preceding 34.

45 (forty-five) is the natural number following 44 and preceding 46.

70 (seventy) is the natural number following 69 and preceding 71.

90 (ninety) is the natural number following 89 and preceding 91.

29 (twenty-nine) is the natural number following 28 and preceding 30. It is a prime number.

28 (twenty-eight) is the natural number following 27 and preceding 29.

34 (thirty-four) is the natural number following 33 and preceding 35.

46 (forty-six) is the natural number following 45 and preceding 47.

58 (fifty-eight) is the natural number following 57 and preceding 59.

91 (ninety-one) is the natural number following 90 and preceding 92.

1000 or one thousand is the natural number following 999 and preceding 1001. In most English-speaking countries, it can be written with or without a comma or sometimes a period separating the thousands digit: 1,000.

300 is the natural number following 299 and preceding 301.

4000 is the natural number following 3999 and preceding 4001. It is a decagonal number.

135 is the natural number following 134 and preceding 136.

216 is the natural number following 215 and preceding 217. It is a cube, and is often called Plato's number, although it is not certain that this is the number intended by Plato.

177 is the natural number following 176 and preceding 178.

888 is the natural number following 887 and preceding 889.

References

  1. Sloane, N. J. A. (ed.). "SequenceA001358". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation.
  2. Sloane, N. J. A. (ed.). "SequenceA001748". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation.
  3. "Sloane's A016105 : Blum integers". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation. Retrieved 2016-05-31.
  4. "Sloane's A000217 : Triangular numbers". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation. Retrieved 2016-05-31.
  5. "Sloane's A000567 : Octagonal numbers". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation. Retrieved 2016-05-31.
  6. "Sloane's A001006 : Motzkin numbers". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation. Retrieved 2016-05-31.
  7. "Sloane's A000931 : Padovan sequence". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation. Retrieved 2016-05-31.
  8. "Sloane's A005349 : Niven (or Harshad) numbers". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation. Retrieved 2016-05-31.
  9. Sloane, N. J. A. (ed.). "SequenceA006879(Number of primes with n digits.)". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation.
  10. "Sloane's A000045 : Fibonacci numbers". The On-Line Encyclopedia of Integer Sequences. OEIS Foundation. Retrieved 2016-05-31.
  11. C. J. Bouwkamp, and A. J. W. Duijvestijn, "Catalogue of Simple Perfect Squared Squares of Orders 21 Through 25." Eindhoven University of Technology, Nov. 1992.
  12. Sloane, N. J. A. (ed.). "SequenceA005847(Imaginary quadratic fields with class number 2 (a finite sequence).)". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation. Retrieved 2024-03-19.
  13. Sloane, N. J. A. (ed.). "SequenceA000203(The sum of the divisors of n. Also called sigma_1(n).)". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation. Retrieved 2024-03-19.
  14. Sloane, N. J. A. (ed.). "SequenceA000396(Perfect numbers k: k is equal to the sum of the proper divisors of k.)". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation. Retrieved 2024-03-19.
  15. Sloane, N. J. A. (ed.). "SequenceA000217(Triangular numbers: a(n) binomial(n+1,2))". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation. Retrieved 2024-03-19.
  16. Sloane, N. J. A. (ed.). "SequenceA028442(Numbers k such that Mertens's function M(k) (A002321) is zero.)". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation. Retrieved 2024-03-19.
  17. Sloane, N. J. A. (ed.). "SequenceA154363(Numbers from Bhargava's prime-universality criterion theorem)". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation. Retrieved 2023-10-13.
  18. Sloane, N. J. A. (ed.). "SequenceA116582(Numbers from Bhargava's 33 theorem.)". The On-Line Encyclopedia of Integer Sequences . OEIS Foundation. Retrieved 2023-10-09.
  19. Cohen, Henri (2007). "Consequences of the Hasse–Minkowski Theorem". Number Theory Volume I: Tools and Diophantine Equations. Graduate Texts in Mathematics. Vol. 239 (1st ed.). Springer. pp. 312–314. doi:10.1007/978-0-387-49923-9. ISBN   978-0-387-49922-2. OCLC   493636622. Zbl   1119.11001.