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Đặc trưng của vành Artin thông qua tính tốt và tính nửa Hopfian
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Nội dung Text: Đặc trưng của vành Artin thông qua tính tốt và tính nửa Hopfian
CHARACTERIZATIONS OF ARTINIAN RINGS BY THE GOODNESS AND<br />
SEMI-HOPFIANESS<br />
Tran Nguyen An∗<br />
Thai Nguyen University of Education<br />
<br />
Tãm t¾t<br />
Bµi b¸o ®a ra hai ®Æc trng míi cña vµnh Artin th«ng qua tÝnh tèt vµ tÝnh nöa Hopfian.<br />
<br />
Tõ kho¸:<br />
<br />
1<br />
<br />
Vµnh vµ m«®un Artin, m«®un nguyªn s¬, m«®un tèt, m«®un nöa Hopfian.<br />
<br />
Introduction<br />
<br />
(ii) Every non-zero R−module is good.<br />
<br />
Throughout of this paper, let R be a commutative ring. This paper is concerned with the notions of good modules and semi-Hopfian modules: Let M be an R−module and N a proper<br />
submodule of M . We say that N is primary<br />
if the multiplication by x on M/N is nilpotent<br />
for all x ∈ R. In this case, the set of all nilpotent elements is a prime ideal of R, say p, and<br />
N is called p−primary. An R−module M is<br />
called good if there is a composition<br />
0=<br />
<br />
n<br />
\<br />
<br />
Ni<br />
<br />
i=1<br />
<br />
of zero-submodule of M into primary submodules Ni . An R−module M is called semiHopfian if for all x ∈ R, the multiplication by<br />
x on M is an isomorphism provided it is surjective.<br />
Two well known characterizations of Artinian<br />
rings (see [Mat]) are as follows: R is Artinian<br />
if and only if R is Noetherian and dim R = 0, if<br />
and only if R is of finite length. Recently, there<br />
are some characterizations of Artinian rings via<br />
goodness and semi-Hopfianess.<br />
Theorem. (See [KA], Theorem 1.1). For any<br />
commutative Noetherian ring R, the following<br />
statement are equivalent.<br />
(i) R is Artinian.<br />
0<br />
<br />
(iii) Every non-zero R−module is semiHopfian.<br />
The purpose of this paper is to extend the<br />
above characterizations via the goodness and<br />
semi-Hopfianess for only Artinian R−modules.<br />
The following theorem is the main result of this<br />
paper.<br />
Theorem 1.1. Let R be a commutative<br />
Noetherian ring. Then the following statements are equivalent:<br />
(i) R is Artinian.<br />
(ii) Every non-zero Artinian R−module is<br />
good.<br />
(iii) Every non-zero Artinian R−module is<br />
semi-Hopfian.<br />
<br />
2<br />
<br />
Proof of Theorem 1.1<br />
<br />
To prove Theorem 1.1, we recall first some<br />
facts of Artinian modules. The notion of secondary representation is in some sense dual to<br />
the known concept of primary decomposition.<br />
Here we recall this by using the terminology<br />
of I. G. Macdonal [Mac]: An R−module M is<br />
called secondary if the multiplication by x on<br />
M is surjective or nilpotent. In this case, the<br />
set of all nilpotent elements is a prime ideal of<br />
<br />
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<br />
R, say p, and we said M is p−secondary. An<br />
R−module M is called representable if it has a<br />
minimal secondary representation, i.e. M has<br />
a representation<br />
M = M1 + M2 + · · · + M n<br />
where Mi is pi −secondary for i = 1, · · · , n with<br />
pi 6= pj for all i 6= j and all the secondary components Mi are not redundant. In this case,<br />
the set {p1 , · · · , pn } does not depend on the<br />
choice of minimal secondary representation of<br />
M . There for we denote it by Att M and called<br />
the set of attached prime ideals of M .<br />
We also need the following special properties<br />
of Artinian modules (see [Sh2, K1, K2] over<br />
commutative rings.<br />
Remark 2.1. Let M be an Artinian<br />
R−module. Then the Supp M is a finite<br />
set of maximal ideals of R, T<br />
says Supp M =<br />
mi . Then we<br />
{m1 , · · · , mk }. Let J(M ) =<br />
<br />
Lemma 2.3. (See [Mac]). Every Artinian<br />
modules is representable.<br />
We have known in [SV] that if E is an injective R−module then E has the unique decomposation into a direct sum of indecomposable<br />
injective modules<br />
M<br />
E=<br />
E(R/p)Ip<br />
p∈Occ E<br />
<br />
where Occ E is a subset of Spec R of all<br />
prime ideal p appearing in the decomposition,<br />
E(R/p) is injective hull of R/p, and Ip is the<br />
cardinian of some set with respect to p.<br />
Keep the above notations. Then we have the<br />
following result.<br />
Lemma 2.4. (See [Sh1]). Every injective<br />
modules E is representable. Moreover, if<br />
M<br />
E=<br />
E(R/p)Ip<br />
p∈Occ E<br />
<br />
i=1,...,k<br />
<br />
have<br />
M=<br />
<br />
[<br />
<br />
(0 :M J(M )n ).<br />
<br />
is the decomposition of E into indecomposible<br />
injective E(R/p) then<br />
<br />
n>0<br />
<br />
In particular, if M 6= 0 then 0 :M J(M ) 6= 0.<br />
Lemma 2.2. Let m be a maximal ideal of a<br />
commutative Noetherian ring R. Then the injective hull E = E(R/m) of R/m is an Artinian<br />
R−module. Moreover we have Supp E = {m},<br />
and therefore 0 :E m 6= 0.<br />
Proof. It has shown by [SV] that E is an Artinian module. Let q be a prime ideal of R.<br />
Then we have an isomorphism of Rq −modules<br />
Eq ∼<br />
= E(Rp /mq ).<br />
Therefore it is easily seen that m ∈ Supp E.<br />
Let q 6= m we have E(Rq /mq ) = 0. It follows<br />
that Eq = 0, and hence q * Supp E. Therefore<br />
Supp E = {m}, and therefore 0 :E m 6= 0 by<br />
Lemma 2.1.<br />
The following results give two important<br />
classes of representable modules.<br />
<br />
Att E = {p ∈ Ass R : q ⊆ p<br />
<br />
for some<br />
<br />
p ∈ Occ E}.<br />
<br />
Now we can prove Theorem 1.1.<br />
Proof of Theorem 1.1. (i) ⇒ (ii). Since R<br />
is Artinian, it is followed by ([KA], Theorem 1.1, (i) ⇒ (ii)) that every non-zero<br />
R−module is good. Hence every non-zero Artinian R−module is good.<br />
(ii) ⇒ (iii) It is followed by the proof of ([KA],<br />
Theorem 1.1).<br />
(iii) ⇒ (i). Assume that R is not Artinian.<br />
Since R is Noetherian ring, we get by [Mat]<br />
that dim R > 0. Let dim R = d. Then there<br />
exists a prime chain of length d of R<br />
p0 ⊂ p1 ⊂ · · · ⊂ pd<br />
where pi 6= pi+1 for all i = 0, · · · , d. Note that<br />
pd is a maximal ideal of R, and p0 is minimal<br />
prime ideal of R. For simplicity, we set m = pd<br />
and p = p0 . Let E is the injective hull of R/m.<br />
<br />
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<br />
Then we have by Lemma 2.4 that E is representable and<br />
Att E = {q ∈ Ass R : q ⊆ m}.<br />
Since p is a minimal prime ideal of R, it is followed by [Mat] that p ∈ Ass R. Therefore we<br />
have p ∈ Att E. Let<br />
E = E1 + E2 + · · · + Et<br />
be a minimal secondary representation of E.<br />
Since p ∈ Att E, there exists index i ∈<br />
{1, · · · , t} such that Ei is p−secondary. Without any loss of generality we can assume that<br />
E1 is the p−secondary. Note that E is an Artinian R−module by Lemma 2.2. Therefore<br />
<br />
References<br />
[KA] Camran Divaani-Aazar and Amir Mafi,<br />
A new characterization of commutative Artinian rings, Vietnam J. Math. (to appear)<br />
[K1] D. Kirby, Artinian modules and Hilbert<br />
polynomials, Quart. J. Math. Oxford, 6<br />
(1973), 47-57.<br />
<br />
E1 is an Artinian R−module, and hence E1 is<br />
semi-Hopfian by hypothesis (ii). Since d > 0,<br />
we have p 6= m. Let x ∈ m\p. Since E1 is<br />
p−secondary, the multiplication by x on E1 is<br />
surjective. Therefore the multiplication by x<br />
on E1 is an isomorphism, and hence 0 :E1 x = 0<br />
(note that 0 :E1 x is the kernel of this multiplication). Since Supp E1 = {m} by Lemma 2.2,<br />
we have 0 :E1 m 6= 0. Therefore<br />
0 :E1 x ⊇ 0 :E1 m 6= 0.<br />
This gives a contradiction.<br />
tinian.<br />
<br />
Thus R is Ar-<br />
<br />
[Mat] H. Matsumura, Commutative ring theory, Cambridge University Press, Cambridge, 1986.<br />
[Sh1] R. Y. Sharp, Secondary representation<br />
for injective modules over commutative<br />
Noetherian rings, Proc. Edingburgh Math.<br />
20 (1976), 143-151.<br />
<br />
[K2] D. Kirby, Dimension and length of Artinian modules, Quart. J. Math. Oxford, 41<br />
(1990), 419-429.<br />
<br />
[Sh2] R. Y. Sharp, A method for the study<br />
of Artinian modules with an application to<br />
asymptotic behaviour, In Commutative Algebra (Math. Sciences reseach Inst. Publ.<br />
No 15, Springer-Verlag), (1989), 177-195.<br />
<br />
[Mac] I. G. Macdonal, Secondary representation of modules over a commutative ring,<br />
Sym. Math. 11 (1973), 23-43.<br />
<br />
[SV] D. W. Sharpe and P. Vamos, injective modules, University Press Cambridge,<br />
1972.<br />
<br />
SUMMARY<br />
CHARACTERIZATIONS OF ARTINIAN RINGS BY THE GOODNESS AND<br />
SEMI-HOPFIANESS<br />
Two characterizations of commutative Artinian rings by mean of the goodness and semi-Hopfianess<br />
are given.<br />
Tran Nguyen An<br />
Thai Nguyen University of Education<br />
Key words: Artinian rings and modules, primary modules, good modules, semi-hopfian modules.<br />
0<br />
<br />
*Tel: 0978557969, e-mail: antrannguyen@gmail.com<br />
<br />
150Số hóa bởi Trung tâm Học liệu – Đại học Thái Nguyên<br />
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