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Number Theory: A Very Short Introduction

Page 12

by Robin Wilson


  By Fermat’s last theorem, discussed in Chapter 5, the equation has no non-zero solutions when . So this equation can have solutions only when at least one of the integers a, b, and c is 0: for example, and .

  Can every number be written as the sum of six cubes?

  In our discussion of Waring’s problem at the end of Chapter 5, we saw that 23, for example, requires at least nine cubes. However, as we remarked, every number from some point onwards can be written as the sum of seven cubes. It is not yet known whether ‘seven’ can be reduced to ‘six’.

  Perfect numbers

  In Chapter 3 we discussed perfect numbers, where a number n is perfect if the sum of all its proper factors (those different from n) is equal to n. The first four perfect numbers, known since the time of the Greeks, are 6, 28, 496, and 8128. The next two questions were discussed in Chapter 3.

  What is the next perfect number after 8128?

  After 8128 there is a large gap, and the next perfect number does not occur until 33,550,336.

  Is there a formula for producing perfect numbers?

  As we showed in Chapter 3, every number of the form , where is prime, is a perfect number, and all even perfect numbers can be written in this form—for example,

  It is not yet known whether there are any odd perfect numbers.

  Prime numbers

  Prime numbers were discussed in Chapters 3 and 7. The next two questions were discussed at the beginning of Chapter 7, in the section on Two famous conjectures.

  Does the list of twin primes go on for ever?

  Twin primes are pairs of primes that differ by 2, and many examples are known. The twin prime conjecture is that there are infinitely many pairs of twin primes. It is generally believed to be true, but this has never been proved. Some related results are presented in Chapter 7.

  Can every even number be written as the sum of two primes?

  Another famous unanswered question is Goldbach’s conjecture, which asks whether every even number greater than 2 can be written as the sum of two primes. It is known to be true for all even numbers up to 400 trillion, but has not yet been proved in general.

  In Chapter 7 we also saw how to construct strings of consecutive composite numbers of any desired length.

  Is there a string of 1000 consecutive composite numbers?

  As we saw in the section on The distribution of primes, an example of such a string of composite numbers is

  In Chapter 5 we reduced the problem of deciding which numbers can be written as the sum of two squares to the corresponding problem for primes.

  Which prime numbers can be written as the sum of two squares?

  As we saw in the section on Sums of squares, every prime number of the form can be written in exactly one way as the sum of two squares, as can the prime 2 . However, no numbers of the form (and primes of this form, in particular) can be written as the sum of two squares.

  The next two questions were discussed in Chapter 3 in connection with Mersenne and Fermat primes.

  Is the number always prime when n is prime, and always composite when n is composite?

  In our discussion of Mersenne primes, we saw that must be composite when n is composite. However, need not be prime when n is prime: for example, .

  Are all numbers of the form , where n is a power of 2, prime?

  In our discussion of Fermat primes, we saw that the first five ‘Fermat numbers’, , , , , and , are all prime. No other examples have ever been found.

  The last two questions were discussed in Chapter 7, in the section on Primes in arithmetic progressions.

  Are there infinitely many primes of the form ? or of the form ?

  The answer to these questions is ‘yes’, and both can be proved by adapting Euclid’s proof that there are infinitely many primes. In the former case we also used the fact that −1 is a square (mod p) for any prime p of the form . These results can also be deduced directly from Dirichlet’s more general theorem on primes in arithmetic progressions, which states that there are infinitely many prime numbers of the form , where n is an integer, as long as .

  Are there infinitely many primes with final digit 9?

  Again, by Dirichlet’s theorem, there are infinitely many prime numbers of the form —that is, primes with final digit 9.

  We have now reached the end of our story. Number theory continues to be an exciting part of modern mathematics, with many startling new developments over recent years. However, there are many parts of the subject that we have been unable to explore within these pages, and we hope that you will wish to continue your interest in the subject by referring to the items in our list of further reading.

  Further reading

  The following texts, some classic and others much newer, provide useful introductions to the various areas of number theory introduced in this book.

  George E. Andrews, Number Theory, new edn, Dover Publications, 2000.

  David M. Burton, Elementary Number Theory, 7th edn, McGraw-Hill, 1980.

  H. Davenport, The Higher Arithmetic, 8th edn, Cambridge University Press, 2008.

  Underwood Dudley, Elementary Number Theory, 2nd edn, Dover Publications, 2008.

  Emil Grosswald, Topics from the Theory of Numbers, 2nd edn, Birkhäuser, 1984.

  G. H. Hardy and E. M. Wright, An Introduction to the Theory of Numbers, 6th edn (ed. D. R. Heath-Brown and J. H. Silverman), Oxford University Press, 2008.

  Gareth A. Jones and J. Mary Jones, Elementary Number Theory, Springer, 1998.

  Oystein Ore, Invitation to Number Theory, 2nd edn (revised and updated by John J. Watkins and Robin Wilson), Mathematical Association of America, 2017.

  James J. Tattersall, Elementary Number Theory in Nine Chapters, 2nd edn, Cambridge University Press, 2005.

  Martin H. Weissman, An Illustrated Theory of Numbers, American Mathematical Society, 2017.

  More historical information can be found in:

  Leonard Eugene Dickson, History of the Theory of Numbers, Vols. I, II, III, Dover Publications, 2005.

  O. Ore, Number Theory and its History, Dover Publications, 1988.

  John J. Watkins: Number Theory: A Historical Approach, Princeton University Press, 2014.

  Popular books on the Riemann hypothesis, Fermat’s last theorem, and the twin prime conjecture are:

  John Derbyshire, Prime Obsession: Bernhard Riemann and the Greatest Unsolved Problem in Mathematics, Plume Books, 2004.

  Marcus du Sautoy, The Music of the Primes: Why an Unsolved Problem in Mathematics Matters, Harper/Perennial, 2004.

  Vicky Neale, Closing the Gap: The Quest to Understand Prime Numbers, Oxford University Press, 2017.

  Karl Sabbagh, Dr Riemann’s Zeros, Atlantic Books, 2003.

  Simon Singh, Fermat’s Last Theorem, Fourth Estate, 1998.

  More advanced books on specific topics include:

  Tom M. Apostol, Introduction to Analytic Number Theory, 5th printing, Springer, 1998.

  H. M. Edwards, Riemann’s Zeta Function, Dover Publications, 2003.

  Barry Mazur and William Stein, Prime Numbers and the Riemann Hypothesis, Cambridge University Press, 2016.

  Paulo Ribenboim, The Little Book of Bigger Primes, 2nd edn, Springer, 2010.

  Ian Stewart and David Tall, Algebraic Number Theory and Fermat’s Last Theorem, 3rd edn, A. K. Peters / CRC Press, 2001.

  An English translation of Gauss’s classic book of 1801 is:

  Carl Friedrich Gauss, Disquisitiones Arithmeticae (trans. Arthur A. Clarke), Yale University Press, 1965.

  Index

  A

  Adleman, L. 110

  algorithm 23

  al-Khwarizmi 24

  almost prime 113

  alternating sum 34

  Ancient Greeks 2, 10, 53

  arithmetic progression 124–5

  B

  Bachet de Méziriac, C. 89, 93–4

  Baker, A. 129

  Baker–Heegner–Stark theorem 129

  Bernoulli, J. 134<
br />
  birds problem 81–2, 144

  C

  calendars 63–6, 142

  canonical form 44

  card shuffling 1, 101–2, 144

  Carmichael, R. 99

  Carmichael number 100

  Carroll, Lewis 65

  Casting out nines 34–7, 62

  census-taker puzzle 17

  Chen Jingrun 113, 115

  Chinese Remainder Theorem 71

  cicada 20–1

  Clay Mathematics Institute 130, 144

  clock arithmetic 58–9, 63

  Cocks, C. 110

  Cole, F. N. 48

  combination 16, 21

  common divisor 20

  common multiple 19

  complex numbers 127–8, 137

  complex plane 137–40

  composite number 10–11, 38, 117, 148

  congruences 58ff

  congruent (mod n) 59

  convergence of series 133

  Conway, J. 65

  counting necklaces 100

  counting numbers 2

  cryptography 4, 110–11

  cubes 8–9, 29–30, 146–7

  D

  de la Vallée Poussin, C. 121–2

  decimal system 31

  Descartes, R. 51

  difference of squares 87–8

  digital root 35–6

  digital sum 33

  Diophantine equation 79, 144

  Diophantus 2, 79, 85, 89, 93

  Dirichlet, L. 96, 124–5, 130

  Dirichlet’s theorem 124–5, 149

  Disquisitiones Arithmeticae 2, 43, 58, 128

  distribution of primes 116–22, 149

  divides 14–16

  divisibility 31–4, 61–2, 145

  division rule 22

  divisor 9, 14–19

  divisor tests 30

  Dodgson, C. L. 65

  Dyson, F. 141

  E

  eggs problem 1, 49, 143

  Eratosthenes 38

  Erdős, P. 121

  Euclid 2–3, 9, 22, 41, 50, 54, 122–3, 150

  Euclid’s algorithm 22–7, 111

  Euclid’s Elements 2, 9, 54

  Euler, J. A. 91

  Euler, L. 2–3, 46–7, 51–3, 87, 89, 95, 97, 112, 134–7

  Euler product 136

  Euler’s phi-function 103–6

  Euler’s theorem 106–8, 110–11, 144

  even number 5, 126

  exponential function 120

  F

  factor 9, 14

  factorial number 117

  factorization 42–4

  factorizing large numbers 108–10

  Faro shuffling 101

  Fermat, P. 2–3, 12, 51–2, 86–7, 89, 93, 95, 97–8, 108–9, 142, 146

  Fermat number 13, 51, 53

  Fermat prime 51–3, 55–6, 143–4, 149

  Fermat’s ‘last theorem’ 2, 4, 92–6, 147

  Fermat’s ‘little theorem’ 97–103, 106–8, 144

  Fermat’s method, 108–9

  Fibonacci, L. 26, 81

  Fibonacci number 26

  four-square theorem 89, 91

  fundamental theorem of arithmetic 43–4

  G

  Gauss, C. F. 2–3, 55, 58, 65, 103, 128, 130, 139, 143

  Gaussian integers 128

  Germain, S. 95

  GIMPS 49

  Girard, A. 87

  Goldbach, C. 112

  Goldbach’s conjecture 112–14, 148

  Gowers, T. 115

  greatest common divisor 19–27, 44–5

  Green, B. 126

  Green–Tao theorem 126

  Gregorian calendar 64

  H

  Hadamard, J. 121

  Hardy, G. H. 90

  harmonic series 134

  Heegner, K. 128

  Helfgott, H. 113–14

  highest common factor 20

  Hilbert, D. 91, 126

  Humpty Dumpty 108

  I

  infinitely many primes 2, 41, 136, 150

  infinite series 132–134

  integer 4–6

  ISBN number 34

  J

  Jingrun Chen 113, 115

  Jones, J. 56

  K

  Kummer, E. 96

  L

  Lagrange, J. 2, 89

  Lagrange’s four-square theorem 89, 91

  Lamé, G. 96

  law of quadratic reciprocity 77

  least common multiple 17–19, 22, 44–5

  Legendre, A.-M. 2, 75, 86, 89, 95–6, 124, 146

  Legendre symbol 75

  Lehmer, D. H. 62

  Leibniz, G. 98

  linear congruences 66–72

  Lincoln, A. 36–7

  logarithm, 120

  Lucas, E. 47–8, 62

  Lucas–Lehmer test 62

  M

  Maynard, J. 116

  Mersenne, M. 12, 47–8, 87

  Mersenne number 47–8

  Mersenne prime 12, 46–50, 62–3, 149

  method of infinite descent 95

  Mills, W. H. 56

  Mills’ constant 56

  modular arithmetic 59

  modulo 59

  Montgomery, H. 141

  multiple 5, 14–19

  N

  natural logarithm 120

  necklaces 100

  negative integer 5

  number theory 2

  number 6

  O

  odd number 5

  P

  perfect cube 8

  perfect number 9–10, 49–51, 147

  perfect square 1, 6, 143

  phi function 103–6

  pirates puzzle 67, 70–1

  Platt, D. 113

  Polignac, A. de 114

  polygon 1, 53–6, 143–4

  Polymath project 115–6

  polynomial 56–7

  Pope Gregory XIII 64

  positive integer 5

  postage stamp 36, 49, 96

  prime number 2, 10–13, 38ff, 148–50

  prime number theorem 117–22

  primes in arithmetic progression 122–6, 149

  primitive triple 82–5, 146

  proof by contradiction 41

  public key cryptography 110–11

  Pythagorean theorem 7, 82

  Pythagorean triple 82, 143

  Pythagoreans 2, 6, 27

  Q

  quadratic reciprocity 77

  quadratic residue 74

  quadratic sieve method 108

  quotient 22

  R

  Ramanujan, S. 90

  reduction ad absurdum 41

  regular polygon 1, 53–6, 143–4

  regular prime 96

  remainder 22

  Riemann, B. 131–2, 138–40

  Riemann hypothesis 1, 130, 138–41, 144–5

  Riemann-zeta function 139–40

  Riese, Adam 36–7

  right-angled triangle 1, 7–8, 82–5, 143, 146

  Rivest, R. 110

  RSA encryption 110–11, 144

  S

  Sato, D. 56

  Selberg, A. 121–2

  self-replicating number 71–2

  Shamir, A. 110

  shuffling cards 1, 101–2, 144

  sieve of Eratosthenes 38–40, 113

  sieve methods 38–40, 110, 113, 115

  simultaneous congruences 69–72

  square-free number 128

  squares 1, 6–7, 27–9, 61, 72–8, 143, 145–6

  Stark, H. 128

  sum of primes 11, 148

  sum of squares 11–12, 85–90, 146, 148–9

  Sunzi 69–71, 143

  T

  Tao, T. 
115–16, 126

  Taylor, R. 96

  twin primes 11, 114, 148

  twin prime conjecture, 114–16, 148

  U

  unique factorization 43–4, 126–9

  V

  Vinogradov, I. M. 113

  W

  Wada, H. 56

  Waring, E. 91

  Waring’s problem 91–2, 147

  Wiens, D. 56

  Wiles, A. 4, 96

  Z

  Zagier, D. 117–18, 141

  zeros of zeta function 130, 139–41

  zeta function 134–41, 144

  Zhang, Y. 115

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  ‘An excellent introduction . . . presents mathematical and statistical findings in straightforward prose.’

  Financial Times

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  ‘Splendidly pellucid.’

  Steven Poole, The Guardian

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