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			{{Short description\|Subset of a ring that forms a ring itself}}
	{{No footnotes\|date=November 2018}}

	{{Ring theory sidebar}}		{{Ring theory sidebar}}

	In ], a '''subring''' of ''R'' is a ] of ~~a ]~~ that is itself a ring when ]s of addition and multiplication on ''R'' are restricted to the subset, and ~~which~~ shares the same ] as ''R''. ~~For~~ ~~those who define rings without requiring the existence of a multiplicative identity~~, a ~~subring~~ ~~of ''R'' is just a subset~~ of ~~''R'' that is~~ a ring ~~for the operations of ''~~R'' ~~(this does imply it contains the additive identity of ''R''). The latter gives a strictly weaker condition, even for~~ rings that do have a multiplicative identity, so that for instance all ]s become subrings (and they may have a multiplicative identity that differs from the one of ''R''). With definition requiring a multiplicative identity (which is used in this article), the only ideal of ''R'' that is a subring of ''R'' is ''R'' itself.		In ], a '''subring''' of a ] {{mvar\|R}} is a ] of {{mvar\|R}} that is itself a ring when ]s of addition and multiplication on ''R'' are restricted to the subset, and that shares the same ] as {{mvar\|R}}.<ref group=lower-alpha>In general, not all subsets of a ring {{mvar\|R}} are rings.</ref>

	==Definition==		== Definition ==
	A subring of a ring {{~~nowrap~~\|(''R'', +, ∗, 0, 1)}} is a subset ''S'' of ''R'' that preserves the structure of the ring, i.e. a ring {{~~nowrap~~\|(''S'', +, ∗, 0, 1)}} with {{~~nowrap~~\|''S'' ⊆ ''R''}}. Equivalently, it is both a ] of {{~~nowrap~~\|(''R'', +, 0)}} and a ] of {{~~nowrap~~\|(''R'', ∗, 1)}}.		A subring of a ring {{math\|(''R'', +, , 0, 1)}} is a subset {{mvar\|S}} of {{mvar\|R}} that preserves the structure of the ring, i.e. a ring {{math\|(''S'', +, , 0, 1)}} with {{math\|''S'' ⊆ ''R''}}. Equivalently, it is both a ] of {{math\|(''R'', +, 0)}} and a ] of {{math\|(''R'', *, 1)}}.

			Equivalently, {{mvar\|S}} is a subring ] it contains the multiplicative identity of {{mvar\|R}}, and is ] under multiplication and subtraction. This is sometimes known as the ''subring test''.<ref name="Dummit & Foote">{{cite book \|last1=Dummit \|first1=David Steven \|last2=Foote \|first2=Richard Martin \|title=Abstract algebra \|date=2004 \|publisher=John Wiley & Sons \|location=Hoboken, NJ \|isbn=0-471-43334-9 \|edition=Third \|url=https://archive.org/details/abstractalgebra0000dumm_k3c6 \|page=228}}</ref>
	==Examples==
⚫	~~The ring~~ <math>\mathbb{Z}</math> and its quotients <math>\mathbb{Z}/n\mathbb{Z}</math> have no subrings (with multiplicative identity) other than the full ring.

			=== Variations ===
⚫	Every ring has a unique smallest subring, isomorphic to some ring <math>\mathbb{Z}/n\mathbb{Z}</math> with ''n'' a nonnegative integer (see ]). The integers <math>\mathbb{Z}</math> correspond to {{nowrap\|1=''n'' = 0}} in this statement, since <math>\mathbb{Z}</math> is isomorphic to <math>\mathbb{Z}/0\mathbb{Z}</math>.
			Some mathematicians define rings without requiring the existence of a multiplicative identity (see ''{{slink\|Ring (mathematics)\|History}}''). In this case, a subring of {{mvar\|R}} is a subset of {{mvar\|R}} that is a ring for the operations of {{mvar\|R}} (this does imply it contains the additive identity of {{mvar\|R}}). This alternate definition gives a strictly weaker condition, even for rings that do have a multiplicative identity, in that all ]s become subrings, and they may have a multiplicative identity that differs from the one of {{mvar\|R}}. With the definition requiring a multiplicative identity, which is used in the rest of this article, the only ideal of {{mvar\|R}} that is a subring of {{mvar\|R}} is {{mvar\|R}} itself.

	==~~Subring~~ ~~test~~==		== Examples ==
	The ~~'''subring test''' is a~~ ] that states that for any ring ~~''R'',~~ ~~a ] ~~''S'' of ''R''~~ is a subring if ~~and~~ ~~only if it is~~ ] ~~under~~ ~~multiplication~~ and ~~subtraction,~~ ~~and~~ ~~contains~~ ~~the~~ ~~multiplicative~~ ~~identity~~ of ~~''R''.~~~~		* The ] <math>\Z</math> is a subring of both the ] of ]s and the ] <math>\Z</math>.<ref name="Dummit & Foote" />

		⚫	* <math>\mathbb{Z}</math> and its quotients <math>\mathbb{Z}/n\mathbb{Z}</math> have no subrings (with multiplicative identity) other than the full ring.<ref name="Dummit & Foote" />
	As an example, the ring '''Z''' of ]s is a subring of the ] of ]s and also a subring of the ring of ]s '''Z'''.

		⚫	* Every ring has a unique smallest subring, isomorphic to some ring <math>\mathbb{Z}/n\mathbb{Z}</math> with ''n'' a nonnegative integer (see '']''). The integers <math>\mathbb{Z}</math> correspond to {{nowrap\|1=''n'' = 0}} in this statement, since <math>\mathbb{Z}</math> is isomorphic to <math>\mathbb{Z}/0\mathbb{Z}</math>.<ref>{{cite book \|last1=Lang \|first1=Serge \|title=Algebra \|date=2002 \|location=New York \|isbn=978-0387953854 \|edition=3 \|url=https://archive.org/details/algebra-serge-lang \|pages=89–90}}{{dead link\|date=August 2024}}</ref>
⚫	==Ring ~~extensions~~==
	{{distinguish\|text=], a ring-theoretic analog of a group extension}}

			* The ] {{mvar\|R}} is a subring of {{mvar\|R}}, and {{mvar\|R}} is an ] over its center.
	If ''S'' is a subring of a ring ''R'', then equivalently ''R'' is said to be a '''ring extension''' of ''S'', written as ''R''/''S'' in similar notation to that for ]s.

			* The ring of ]s has subrings isomorphic to the rings of ] and ]s, and to the ].{{cn\|date=August 2024}} Since these rings are also ] represented by ], the subrings can be identified as ]s.
⚫	==Subring generated by a set==

		⚫	== Subring generated by a set ==
	Let ''R'' be a ring. Any intersection of subrings of ''R'' is again a subring of ''R''. Therefore, if ''X'' is any subset of ''R'', the intersection of all subrings of ''R'' containing ''X'' is a subring ''S'' of ''R''. ''S'' is the smallest subring of ''R'' containing ''X''. ("Smallest" means that if ''T'' is any other subring of ''R'' containing ''X'', then ''S'' is contained in ''T''.) ''S'' is said to be the subring of ''R'' ''']''' by ''X''. If ''S'' = ''R,'' we may say that the ring ''R'' is ''generated'' by ''X''.
			{{see also\|Generator (mathematics)}}

			A special kind of subring of a ring {{mvar\|R}} is the subring '''generated by''' a subset {{mvar\|X}}, which is defined as the intersection of all subrings of {{mvar\|R}} containing {{mvar\|X}}.<ref name="lovett">{{cite book \|last=Lovett \|first=Stephen \|date=2015 \|title=Abstract Algebra: Structures and Applications \|chapter=Rings \|pages=216–217 \|publisher=CRC Press \|publication-place=Boca Raton \|isbn=9781482248913}}</ref> The subring generated by {{mvar\|X}} is also the set of all ]s with integer coefficients of elements of {{mvar\|X}}, including the additive identity ("empty combination") and multiplicative identity ("empty product").{{cn\|date=August 2024}}
	==Relation to ideals==
	Proper ]s are subrings (without unity) that are closed under both left and right multiplication by elements of ''R''.

			Any intersection of subrings of {{mvar\|R}} is itself a subring of {{mvar\|R}}; therefore, the subring generated by {{mvar\|X}} (denoted here as {{mvar\|S}}) is indeed a subring of {{mvar\|R}}. This subring {{mvar\|S}} is the smallest subring of {{mvar\|R}} containing {{mvar\|X}}; that is, if {{mvar\|T}} is any other subring of {{mvar\|R}} containing {{mvar\|X}}, then {{math\|''S'' ⊆ ''T''}}.
	If one omits the requirement that rings have a unity element, then subrings need only be non-empty and otherwise conform to the ring structure, and ideals become subrings. Ideals may or may not have their own multiplicative identity (distinct from the identity of the ring):
	*The ideal ''I'' = {(''z'',0) \| ''z'' in '''Z'''} of the ring '''Z''' × '''Z''' = {(''x'',''y'') \| ''x'',''y'' in '''Z'''} with componentwise addition and multiplication has the identity (1,0), which is different from the identity (1,1) of the ring. So ''I'' is a ring with unity, and a "subring-without-unity", but not a "subring-with-unity" of '''Z''' × '''Z'''.
	*The proper ideals of '''Z''' have no multiplicative identity.

			Since {{mvar\|R}} itself is a subring of {{mvar\|R}}, if {{mvar\|R}} is generated by {{mvar\|X}}, it is said that the ring {{mvar\|R}} is ''generated by'' {{mvar\|X}}.
	If ''I'' is a ] of a commutative ring ''R'', then the intersection of ''I'' with any subring ''S'' of ''R'' remains prime in ''S''. In this case one says that ''I'' '''lies over''' ''I'' ∩ ''S''. The situation is more complicated when ''R'' is not commutative.

		⚫	== Ring extension ==
	==Profile by commutative subrings==
			Subrings generalize some aspects of ]. If {{mvar\|S}} is a subring of a ring {{mvar\|R}}, then equivalently {{mvar\|R}} is said to be a '''ring extension'''<ref group=lower-alpha>Not to be confused with the ring-theoretic analog of a ].</ref> of {{mvar\|S}}.
	A ring may be profiled{{clarify\|what "profile" means here?\|date=June 2016}} by the variety of ] subrings that it hosts:
	*The ] ring '''H''' contains only the ] as a planar subring
	*The ] ring contains three types of commutative planar subrings: the ] plane, the ] plane, as well as the ordinary complex plane
	*The ] also contains 3-dimensional commutative subrings generated by the ] and a ] ε of order 3 (εεε = 0 ≠ εε). For instance, the ] can be realized as the join of the ] of two of these nilpotent-generated subrings of 3 × 3 matrices.

	==~~See~~ ~~also~~==		=== Adjoining ===
			If {{mvar\|A}} is a ring and {{mvar\|T}} is a subring of {{mvar\|A}} generated by {{math\|''R'' ∪ ''S''}}, where {{mvar\|R}} is a subring, then {{mvar\|T}} is a ring extension and is said to be {{mvar\|S}} ''adjoined to'' {{mvar\|R}}, denoted {{math\|''R''}}. Individual elements can also be adjoined to a subring, denoted {{math\|''R''}}.<ref>{{cite book \|last=Gouvêa \|first=Fernando Q. \|author-link=Fernando Q. Gouvêa \|date=2012 \|title=A Guide to Groups, Rings, and Fields \|chapter=Rings and Modules \|page=145 \|publisher=Mathematical Association of America \|publication-place=Washington, DC \|isbn=9780883853559}}</ref><ref name="lovett" />

			For example, the ring of ] <math>\Z</math> is a subring of <math>\C</math> generated by <math>\Z \cup \{i\}</math>, and thus is the adjunction of the ] {{mvar\|i}} to <math>\Z</math>.<ref name="lovett" />

			=== Prime subring ===
			The intersection of all subrings of a ring {{mvar\|R}} is a subring that may be called the ''prime subring'' of {{mvar\|R}} by analogy with ]s.

			The prime subring of a ring {{mvar\|R}} is a subring of the center of {{mvar\|R}}, which is ] either to the ring <math>\Z</math> of the ] or to the ring of the ], where {{mvar\|n}} is the smallest positive integer such that the sum of {{mvar\|n}} copies of {{math\|1}} equals {{math\|0}}.

			== See also ==
	* ]		* ]
	* ]		* ]
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	* ]		* ]

	==~~References~~==		== Notes ==
			{{notelist-la}}
⚫	* {{cite book \| ~~author~~= Iain T. ~~Adamson~~ \| title=Elementary rings and modules \| series=University Mathematical Texts \| publisher=Oliver and Boyd \| ~~year~~=1972 \| isbn=0-05-002192-3 \| pages=14–16 }}

	* Page 84 of {{Lang Algebra\|edition=3}}
			== References ==
⚫	* {{cite book \| ~~author~~=David ~~Sharpe~~ \| title=Rings and factorization \| url=https://archive.org/details/ringsfactorizati0000shar \| url-access=registration \| publisher=] \| ~~year~~=1987 \| isbn=0-521-33718-6 \| pages=}}
			{{reflist}}

			=== General references ===
		⚫	* {{cite book \|last1=Adamson \|first1=Iain T. \|title=Elementary rings and modules \| series=University Mathematical Texts \| publisher=Oliver and Boyd \|date=1972 \|isbn=0-05-002192-3 \|pages=14–16}}
		⚫	* {{cite book \|last1=Sharpe \|first1=David \|title=Rings and factorization \|url=https://archive.org/details/ringsfactorizati0000shar \| url-access=registration \| publisher=] \|date=1987 \|isbn=0-521-33718-6 \| pages=}}

	]		]

Latest revision as of 05:38, 16 December 2024

Subset of a ring that forms a ring itself

Algebraic structure → Ring theory Ring theory
Basic conceptsRings • Subrings • Ideal • Quotient ring • Fractional ideal • Total ring of fractions • Product of rings • Free product of associative algebras • Tensor product of algebras Ring homomorphisms • Kernel • Inner automorphism • Frobenius endomorphism Algebraic structures • Module • Associative algebra • Graded ring • Involutive ring • Category of rings • Initial ring $\mathbb {Z}$ • Terminal ring $0=\mathbb {Z} /1\mathbb {Z}$ Related structures • Field • Finite field • Non-associative ring • Lie ring • Jordan ring • Semiring • Semifield
Commutative algebraCommutative rings • Integral domain • Integrally closed domain • GCD domain • Unique factorization domain • Principal ideal domain • Euclidean domain • Field • Finite field • Polynomial ring • Formal power series ring Algebraic number theory • Algebraic number field • Integers modulo n • Ring of integers • p-adic integers $\mathbb {Z} _{p}$ • p-adic numbers $\mathbb {Q} _{p}$ • Prüfer p-ring $\mathbb {Z} (p^{\infty })$
Noncommutative algebraNoncommutative rings • Division ring • Semiprimitive ring • Simple ring • Commutator Noncommutative algebraic geometry Free algebra Clifford algebra • Geometric algebra Operator algebra
v t e

Algebraic structure → Ring theory
Ring theory

Basic conceptsRings

• Subrings

• Ideal

• Quotient ring

• Fractional ideal

• Total ring of fractions

• Product of rings

• Free product of associative algebras

• Tensor product of algebras

Ring homomorphisms

• Kernel

• Inner automorphism

• Frobenius endomorphism

Algebraic structures

• Module

• Associative algebra

• Graded ring

• Involutive ring

• Category of rings

• Initial ring

\mathbb {Z}

• Terminal ring

0=\mathbb {Z} /1\mathbb {Z}

Related structures

• Field

• Finite field

• Non-associative ring

• Lie ring

• Jordan ring

• Semiring

• Semifield

Commutative algebraCommutative rings

• Integral domain

• Integrally closed domain

• GCD domain

• Unique factorization domain

• Principal ideal domain

• Euclidean domain

• Field

• Finite field

• Polynomial ring

• Formal power series ring

Algebraic number theory

• Algebraic number field

• Integers modulo n

• Ring of integers

• p-adic integers

\mathbb {Z} _{p}

• p-adic numbers

\mathbb {Q} _{p}

• Prüfer p-ring

\mathbb {Z} (p^{\infty })

Noncommutative algebraNoncommutative rings

• Division ring

• Semiprimitive ring

• Simple ring

• Commutator

Noncommutative algebraic geometry

Free algebra

Clifford algebra

• Geometric algebra

Operator algebra

In mathematics, a subring of a ring R is a subset of R that is itself a ring when binary operations of addition and multiplication on R are restricted to the subset, and that shares the same multiplicative identity as R.

Definition

A subring of a ring (R, +, *, 0, 1) is a subset S of R that preserves the structure of the ring, i.e. a ring (S, +, *, 0, 1) with S ⊆ R. Equivalently, it is both a subgroup of (R, +, 0) and a submonoid of (R, *, 1).

Equivalently, S is a subring if and only if it contains the multiplicative identity of R, and is closed under multiplication and subtraction. This is sometimes known as the subring test.

Variations

Some mathematicians define rings without requiring the existence of a multiplicative identity (see Ring (mathematics) § History). In this case, a subring of R is a subset of R that is a ring for the operations of R (this does imply it contains the additive identity of R). This alternate definition gives a strictly weaker condition, even for rings that do have a multiplicative identity, in that all ideals become subrings, and they may have a multiplicative identity that differs from the one of R. With the definition requiring a multiplicative identity, which is used in the rest of this article, the only ideal of R that is a subring of R is R itself.

Examples

The ring of integers $\mathbb {Z}$ is a subring of both the field of real numbers and the polynomial ring $\mathbb {Z}$ .

$\mathbb {Z}$ and its quotients $\mathbb {Z} /n\mathbb {Z}$ have no subrings (with multiplicative identity) other than the full ring.

Every ring has a unique smallest subring, isomorphic to some ring $\mathbb {Z} /n\mathbb {Z}$ with n a nonnegative integer (see Characteristic). The integers $\mathbb {Z}$ correspond to n = 0 in this statement, since $\mathbb {Z}$ is isomorphic to $\mathbb {Z} /0\mathbb {Z}$ .

The center of a ring R is a subring of R, and R is an associative algebra over its center.

The ring of split-quaternions has subrings isomorphic to the rings of dual numbers and split-complex numbers, and to the complex number field. Since these rings are also real algebras represented by square matrices, the subrings can be identified as subalgebras.

Subring generated by a set

Ring extension

Subrings generalize some aspects of field extensions. If S is a subring of a ring R, then equivalently R is said to be a ring extension of S.

Adjoining

If A is a ring and T is a subring of A generated by R ∪ S, where R is a subring, then T is a ring extension and is said to be S adjoined to R, denoted R. Individual elements can also be adjoined to a subring, denoted R.

For example, the ring of Gaussian integers $\mathbb {Z}$ is a subring of $\mathbb {C}$ generated by $\mathbb {Z} \cup \{i\}$ , and thus is the adjunction of the imaginary unit i to $\mathbb {Z}$ .

Prime subring

The intersection of all subrings of a ring R is a subring that may be called the prime subring of R by analogy with prime fields.

The prime subring of a ring R is a subring of the center of R, which is isomorphic either to the ring $\mathbb {Z}$ of the integers or to the ring of the integers modulo n, where n is the smallest positive integer such that the sum of n copies of 1 equals 0.

Notes

In general, not all subsets of a ring R are rings.
Not to be confused with the ring-theoretic analog of a group extension.

References

^ Dummit, David Steven; Foote, Richard Martin (2004). Abstract algebra (Third ed.). Hoboken, NJ: John Wiley & Sons. p. 228. ISBN 0-471-43334-9.
Lang, Serge (2002). Algebra (3 ed.). New York. pp. 89–90. ISBN 978-0387953854.{{cite book}}: CS1 maint: location missing publisher (link)
^ Lovett, Stephen (2015). "Rings". Abstract Algebra: Structures and Applications. Boca Raton: CRC Press. pp. 216–217. ISBN 9781482248913.
Gouvêa, Fernando Q. (2012). "Rings and Modules". A Guide to Groups, Rings, and Fields. Washington, DC: Mathematical Association of America. p. 145. ISBN 9780883853559.

General references

Adamson, Iain T. (1972). Elementary rings and modules. University Mathematical Texts. Oliver and Boyd. pp. 14–16. ISBN 0-05-002192-3.
Sharpe, David (1987). Rings and factorization. Cambridge University Press. pp. 15–17. ISBN 0-521-33718-6.

Category:

Ring theory