In ring theory, a branch of mathematics, the zero ring[1][2][3][4][5] or trivial ring is the unique ring (up to isomorphism) consisting of one element. (Less commonly, the term "zero ring" is used to refer to any rng of square zero, i.e., a rng in which xy = 0 for all x and y. This article refers to the one-element ring.)

In the category of rings, the zero ring is the terminal object, whereas the ring of integers Z is the initial object.

Definition edit

The zero ring, denoted {0} or simply 0, consists of the one-element set {0} with the operations + and · defined such that 0 + 0 = 0 and 0 · 0 = 0.

Properties edit

  • The zero ring is the unique ring in which the additive identity 0 and multiplicative identity 1 coincide.[1][6] (Proof: If 1 = 0 in a ring R, then for all r in R, we have r = 1r = 0r = 0. The proof of the last equality is found here.)
  • The zero ring is commutative.
  • The element 0 in the zero ring is a unit, serving as its own multiplicative inverse.
  • The unit group of the zero ring is the trivial group {0}.
  • The element 0 in the zero ring is not a zero divisor.
  • The only ideal in the zero ring is the zero ideal {0}, which is also the unit ideal, equal to the whole ring. This ideal is neither maximal nor prime.
  • The zero ring is generally excluded from fields, while occasionally called as the trivial field. Excluding it agrees with the fact that its zero ideal is not maximal. (When mathematicians speak of the "field with one element", they are referring to a non-existent object, and their intention is to define the category that would be the category of schemes over this object if it existed.)
  • The zero ring is generally excluded from integral domains.[7] Whether the zero ring is considered to be a domain at all is a matter of convention, but there are two advantages to considering it not to be a domain. First, this agrees with the definition that a domain is a ring in which 0 is the only zero divisor (in particular, 0 is required to be a zero divisor, which fails in the zero ring). Second, this way, for a positive integer n, the ring Z/nZ is a domain if and only if n is prime, but 1 is not prime.
  • For each ring A, there is a unique ring homomorphism from A to the zero ring. Thus the zero ring is a terminal object in the category of rings.[8]
  • If A is a nonzero ring, then there is no ring homomorphism from the zero ring to A. In particular, the zero ring is not a subring of any nonzero ring.[8]
  • The zero ring is the unique ring of characteristic 1.
  • The only module for the zero ring is the zero module. It is free of rank א for any cardinal number א.
  • The zero ring is not a local ring. It is, however, a semilocal ring.
  • The zero ring is Artinian and (therefore) Noetherian.
  • The spectrum of the zero ring is the empty scheme.[8]
  • The Krull dimension of the zero ring is −∞.
  • The zero ring is semisimple but not simple.
  • The zero ring is not a central simple algebra over any field.
  • The total quotient ring of the zero ring is itself.

Constructions edit

Citations edit

  1. ^ a b Artin 1991, p. 347
  2. ^ Atiyah & Macdonald 1969, p. 1
  3. ^ Bosch 2012, p. 10
  4. ^ Bourbaki, p. 101
  5. ^ Lam 2003, p. 1
  6. ^ Lang 2002, p. 83
  7. ^ Lam 2003, p. 3
  8. ^ a b c Hartshorne 1977, p. 80

References edit

  • Artin, Michael (1991), Algebra, Prentice-Hall
  • Atiyah, M. F.; Macdonald, I. G. (1969), Introduction to commutative algebra, Addison-Wesley
  • Bosch, Siegfried (2012), Algebraic geometry and commutative algebra, Springer
  • Bourbaki, N., Algebra I, Chapters 1–3
  • Hartshorne, Robin (1977), Algebraic geometry, Springer
  • Lam, T. Y. (2003), Exercises in classical ring theory, Springer
  • Lang, Serge (2002), Algebra (3rd ed.), Springer