PAUL E. BLAND
Received 27 June 2001 and in revised form 14 July 2005
Letτ be a hereditary torsion theory on ModR and suppose thatQτ: ModR→ModR is the localization functor. It is shown that for allR-modulesM, every higher derivation defined onMcan be extended uniquely to a higher derivation defined onQτ(M) if and only ifτis a higher differential torsion theory. It is also shown that ifτis a TTF theory andCτ:M→Mis the colocalization functor, then a higher derivation defined onMcan be lifted uniquely to a higher derivation defined onCτ(M).
1. Introduction
Rim has shown in [16] that under certain conditions a higher antiderivationd:M→M can be extended to a higher antiderivation dτ:Qτ(M)→Qτ(M), where Qτ: ModR→ ModR is the localization functor [10] at a hereditary torsion theoryτon ModR. By se- lecting the involution on the ring in the definition of a higher antiderivation to be the identity mapping onR, a higher antiderivationd:M→Mbecomes a higher derivation as defined by Ribenboim in [15]. Thus Rim’s results, which generalize the results of Golan [9], show that a higher derivationd:M→M can be extended to a higher derivation dτ:Qτ(M)→Qτ(M) whenever the conditions of his proposition are met. Uniqueness of extensions of higher (anti-) derivations and the necessary and sufficient conditions for the existence of these extensions were not addressed. The purpose of this paper is to intro- duce higher differential torsion theories and to show that a higher derivationd:M→M can always be extended uniquely toQτ(M), the module of quotients ofM, if and only if τis a higher differential torsion theory on ModR. We also show that a higher derivation d:M→M can be lifted uniquely to the module of coquotientsCτ(M) ofM at a TTF theory on ModR.
Throughout this paperRwill be an associative ring with identity 1, ModRwill denote the category of unitary rightR-modules and all modules and module homomorphisms will be in ModR.
Copyright©2005 Hindawi Publishing Corporation
International Journal of Mathematics and Mathematical Sciences 2005:15 (2005) 2373–2387 DOI:10.1155/IJMMS.2005.2373
2. Differential torsion theory
A torsion theoryτon ModRis a pair (T, F) of classes ofR-modules such that the following conditions hold.
(1) T∩F=0.
(2) IfM→N→0 is an exact sequence in ModRandM∈T, thenN∈T.
(3) If 0→M→Nis an exact sequence in ModRandN∈F, thenM∈F.
(4) For eachR-moduleM, there is a short exact sequence 0→T→M→F→0 in ModRwithT∈T andF∈F.
It follows that the class T is closed under factor modules, direct sums, and extensions, and that F is closed under submodules, direct products, and extensions. A class C ofR- modules is said to beclosed under extensionsif whenever 0→M1→M→M2→0 is a short exact sequence in ModR andM1andM2are in C, thenM is in C. Modules in T will be calledτ-torsionand those in F are calledτ-torsion-free. EachR-moduleMhas a largest and necessarily uniqueτ-torsion submodule given bytτ(M)=
N∈SN, where S is the set ofτ-torsion submodules ofM. A torsion theory will be calledhereditaryif T is closed under submodules and it will be calledcohereditaryif F is closed under factor modules.
Standard results and terminology on torsion theory can be found in [4,10] while general information on rings and modules can be found in [2]. Finally, ifN is a submodule of anR-moduleM, then for anyx∈M, (N:x) will denote the right ideal of Rgiven by {a∈R|xa∈N}and (0 :x) is the right ideal{a∈R|xa=0}.
A nonempty collectionᏲof right ideals ofRis said to be a (Gabriel)filter[8] if the following two conditions hold.
(1) IfK∈Ᏺ, then (K:a)∈Ᏺfor eacha∈R.
(2) IfI is a right ideal ofRandK∈Ᏺis such that (I:a)∈Ᏺfor eacha∈K, then I∈Ᏺ.
It can be shown that each filter of right ideals ofRalso satisfies the following three conditions.
(3) IfJ∈ᏲandKis a right ideal ofRsuch thatJ⊆K, thenK∈Ᏺ. (4) IfJ,K∈Ᏺ, thenJ∩K∈Ᏺ.
(5) IfJ,K∈Ᏺ, thenJK∈Ᏺ.
Ifτis a hereditary torsion theory on ModR, thenᏲτ= {K|Kis a right ideal ofRand R/K∈T}is a filter. An elementxof anR-moduleM is said to be aτ-torsion elementof Mif there is aK∈Ᏺτsuch thatxK=0. The set of allτ-torsion elements ofMis theτ- torsion submoduletτ(M) ofMmentioned earlier. Moreover, anR-moduleMisτ-torsion iftτ(M)=Mandτ-torsion-free iftτ(M)=0. Conversely, ifᏲis a filter of right ideals of Randt(M)= {x∈M|xK=0 for someK∈Ᏺ}, thenτ=(T, F) is a hereditary torsion theory on ModR, where T= {M|t(M)=M}and F= {M|t(M)=0}. It follows that there is a one-to-one correspondence between hereditary torsion theories on ModRand filters of right ideals ofR.
An additive mappingδ:R→Rsuch thatδ(ab)=δ(a)b+aδ(b) for alla,b∈Ris said to be aderivation onRand, given a derivationδ onR, an additive mappingd:M→M such thatd(xa)=d(x)a+xδ(a) is aderivation onM. Important to our discussion is the concept of a differential torsion theory, introduced in [5]. Ifδis a derivation onRand Ᏺis a filter of right ideals ofR, thenᏲis called adifferential filter(with respect toδ) if
for eachK∈Ᏺthere is anI∈Ᏺsuch thatδ(I)⊆K. Ifτis a hereditary torsion theory on ModR and the corresponding filterᏲτ is a differential filter, thenτ is said to be a differential torsion theory.
Remark 2.1. IfᏲis a differential filter andK∈Ᏺ, then there is anI∈Ᏺsuch thatδ(I)⊆ K. The right idealI can actually be chosen so thatI⊆K. Indeed, ifI∈Ᏺis such that δ(I)⊆KandI=I∩K, thenI∈Ᏺ,I⊆K, andδ(I)⊆K.
The following example shows that differential torsion theories do indeed exist. We will see additional examples later.
Example 2.2. If S is a multiplicatively closed set of elements of R that is a right denominator set[12], thenSsatisfies the following conditions.
(1) If (a,s)∈R×S, then there is a (b,t)∈R×Ssuch thatat=sb.
(2) Ifsa=0 withs∈Sanda∈R, thenat=0 for somet∈S.
Ifδ is a derivation on R, then the setᏲ= {K|Kis a right ideal ofRandK∩S= ∅}
is a filter of right ideals ofR. IfK∈Ᏺ, lets∈K∩S. Since (δ(s),s)∈R×S, there is a (b,t)∈R×Ssuch thatδ(s)t=sb. Nowδ(st)=δ(s)t+sδ(t)=sb+sδ(t)∈sR⊆K, so if a∈R, thenδ(sta)=δ(st)a+stδ(a)∈K. Henceδ(stR)⊆K. ThereforeᏲis a differential filter, so the torsion theory determined byᏲis a differential torsion theory.
The following lemma gives two conditions that characterize differential filters.
Lemma2.3. Letτbe a hereditary torsion theory onModRwith corresponding filterᏲτ. Then the following are equivalent for a derivationδonR.
(1)Ᏺτis a differential filter.
(2)For everyR-moduleM, ifx∈tτ(M), then there is anI∈Ᏺτsuch thatδ(I)⊆(0 :x).
(3)For everyR-moduleM, ifd:M→Mis a derivation onM, thend(tτ(M))⊆tτ(M).
Proof. (1)⇒(3). If x∈tτ(M), then there is aK∈Ᏺτ such thatxK=0 and anI∈Ᏺτ
such thatδ(I)⊆K. Thus ifa∈I∩K∈Ᏺτ, then we see that 0=d(xa)=d(x)a+xδ(a)= d(x)a. Henced(x)(I∩K)=0, sod(x)∈tτ(M).
(3)⇒(2). Ifx∈tτ(M) anda∈R, thend(x) andd(xa) are intτ(M). Thus (0 :d(x))∩ (0 :d(xa))∈ Ᏺτ. Therefore I =(0 :d(x))∩(0 :d(xa))∈Ᏺτ. If a∈I, then d(x)a= d(xa)=0, so 0=d(xa)=d(x)a+xδ(a)=xδ(a). Thusδ(a)∈(0 :x) and we haveδ(I)⊆ (0 :x).
(2)⇒(1). IfK∈Ᏺτ, then we need to find anI∈Ᏺτsuch thatδ(I)⊆K. SinceR/K is τ-torsion, 1 +K∈tτ(R/K), so by (2) there is anI∈Ᏺτ such thatδ(I)⊆(0 : 1 +K)=K.
3. Higher differential torsion theory
Letnbe a nonnegative integer. Then a family of additive mappingδ= {δi:R→R}ni=0, denoted byδ:R→R, is said to be ahigher derivation(onR) of ordernprovided that
δi(ab)=δi(a)δ0(b) +δi−1(a)δ1(b) +···+δ0(a)δi(b)
=δi(a)b+δi−1(a)δ1(b) +···+aδi(b) (3.1)
for alla,b∈Randi=0, 1,...,n, where it is understood thatδ0is the identity mapping on R. Ifδ:R→Ris a higher derivation of order 1, thenδ1(ab)=δ1(a)b+aδ1(b) for alla,b∈ R, so a higher derivation onRof order 1 gives a derivation onR. Given a higher derivation δ:R→Rof order n, a family of additive mappings d= {di:M→M}ni=0, denoted by d:M→M, is ahigher derivation(onM) of ordernif forx∈Manda∈R
di(xa)=di(x)δ0(a) +di−1(x)δ1(a) +···+d0(x)δi(a)
=di(x)a+di−1(x)δ1(a) +···+xδi(a) (3.2) fori=0, 1,...,nwith the understanding thatd0will always be the identity mapping onM.
A higher derivationd:M→Mof order 1 givesd1(xa)=d1(x)a+xδ1(a), sodproduces a derivation onM. To simplify terminology, a higher derivation of ordernwill be referred to simply as a derivation of ordern.
Remark 3.1. Ifδ:R→Randd:M→Mare derivations of ordernand 0≤k≤n, then ¯δ= {δi:R→R}ki=0and ¯d= {di:M→M}ki=0are derivations of orderk, where ¯dis taken with respect to ¯δ. This will subsequently be described by saying thatdproduces derivations of orderkfork=0, 1,...,n.
LetᏲbe the filter of right ideals ofRand suppose thatδ:R→Ris derivation of order n. IfᏲis such that for eachK∈Ᏺthere is anI∈Ᏺsuch thatδi(I)⊆Kfori=0, 1,...,n, then we will say thatᏲis adifferential filter of ordern. In this setting, the corresponding hereditary torsion theoryτis called adifferential torsion theory of ordern. We now fix the derivationδ:R→Rof ordernand assume, unless stated otherwise, that every derivation d:M→Mof ordern, every differential filterᏲof ordern, and every differential torsion theoryτof ordernis taken with respect toδ. Because ofRemark 3.1every differential filter (differential torsion theory) of ordernproduces a differential filter (differential tor- sion theory) of orderkfork=0, 1,...,n.
In the previous section an example of a differential torsion theory was given. Differ- ential torsion theories of ordern can also be shown to exist. In each of the following examplesδ is a derivation onR of ordern. In particular, we also see that each of the following is also a differential torsion theory.
Example 3.2. LetRbe a commutative ring and suppose thatᏲis a filter of ideals ofR. If I∈Ᏺ, thenI2∈Ᏺ, and it follows thatδ0(I2)=I2⊆I. So suppose thatδi(I2)⊆Ifor alli with 0≤i < n. Ifa,b∈I, then
δn(ab)=δn(a)b+δn−1(a)δ1(b) +···+δ1(a)δn−1(b) +aδn(b) (3.3) which is easily seen to be inI. Sinceδnis additive, we have thatδn(I2)⊆I. ThereforeᏲτ
is a differential filter of ordern, so the corresponding hereditary torsion theory on ModR
is a differential torsion theory of ordern. Thus for a commutative ring every hereditary torsion theory on ModRis a differential torsion theory of ordern.
Example 3.3. Jans has shown in [11] that ifτ=(T, F) is a hereditary torsion on ModR such that T is closed under direct products, then there is an idempotent idealI∈Ᏺτsuch
thatI⊆Kfor eachK∈Ᏺτ. Using the same procedure as in the previous example, we can show thatδi(I)⊆Kfori=0, 1,...,n. Thusτis a differential torsion theory of ordern.
Example 3.4. IfRis left perfect, then Alin and Armendariz [1] and Dlab [7] have indepen- dently proved that ifτ=(T, F) is a hereditary torsion theory on ModR, then T is closed under direct products. Thus, we see from the previous example that ifRis left perfect, then every hereditary torsion theory on ModRis a differential torsion theory of ordern.
With the definitions of a differential filter of ordernand a differential torsion the- ory of ordernin place, one might expect thatLemma 2.3can be generalized to higher differential filters. The following lemma shows that this is indeed the case.
Lemma3.5. Ifτis a hereditary torsion theory onModRwith corresponding filterᏲτ, then the following are equivalent for an integern≥0.
(1)Ᏺτis a differential filter of ordern.
(2)For everyR-moduleMand each derivationd:M→Mof ordern, ifx∈tτ(M), then there is anI∈Ᏺτsuch thatδi(I)⊆(0 :dn−i(x))fori=0, 1,...,n.
(3)For everyR-moduleM, ifd:M→M is a derivation of ordern, thendi(tτ(M))⊆ tτ(M)fori=0, 1,...,n.
Proof. (1)⇒(3). If n=0, then it is trivial that (1)⇒(3), so suppose (1)⇒(3) for every integerk, 0≤k < n. Now letᏲτbe a differential filter of ordernand suppose thatd:M→ M is a derivation of ordern. In view ofRemark 3.1,dproduces a derivation{di:M→ M}ni=−01onMof ordern−1 and it follows thatᏲτis a differential filter of ordern−1. So ifx∈tτ(M), then the induction hypothesis shows thatd1(x),...,dn−1(x)∈tτ(M). Hence each of
(0 :x),0 :d1(x),0 :d2(x),...,0 :dn−1(x) (3.4) is inᏲτ. SinceᏲτis a filter,K= ∩ni=−01(0 :di(x))∈Ᏺτ, so sinceᏲτis a differential filter of ordern, there is anI∈Ᏺτsuch thatδi(I)⊆Kfori=0, 1,...,n. Ifa∈I, then
dn(xa)=dn−1(x)δ1(a)= ··· =d1(x)δn−1(a)=xδn(a)=0, (3.5) so
dn(xa)=dn(x)a+dn−1(x)δ1(a) +···+d1(x)δn−1(a) +xδn(a) (3.6) givesdn(x)a=0. Therefore,dn(x)I=0, which indicates thatdn(x)∈tτ(M) and we have (3).
(3)⇒(2). Ifn=0, then (3)⇒(2) is trivial since we can letI=(0 :x). Now suppose that (3)⇒(2) for every integerk, 0≤k < n, and let (3) hold for n. Ifd:M→M is a derivation of ordernandx∈tτ(M), then since (3) holds forn, we havedi(x)∈tτ(M) for i=0, 1,...,n. Since{di:M→M}ni=−01is a derivation onM of ordern−1, the induction hypothesis givesI∈Ᏺτsuch thatδi(I)⊆(0 :dn−1−i(x)) fori=0, 1,...,n−1. Ifa∈I= I∩(0 :dn(x))∈Ᏺτ, then
dn(xa)=dn(x)a=dn−1(x)δ1(a)=dn−2(x)δ2(a)= ··· =d1(x)δn−1(a)=0, (3.7)
so
dn(xa)=dn(x)a+dn−1(x)δ1(a) +···+d1(x)δn−1(a) +xδn(a) (3.8) becomes
xδn(a)=0. (3.9)
Henceδn(I)⊆(0 :x), soδi(I)⊆(0 :dn−i(x)) fori=0, 1,...,n.
(2)⇒(1). It is obvious that (2)⇒(1) whenn=0, so suppose that (2)⇒(1) for every inte- gerksuch that 0≤k < n. IfK∈Ᏺτ, thenR/Kisτ-torsion, so letd= {di:R/K→R/K}ki=0, be a derivation onR/Kof orderkfork=0, 1,...,n. Since (2) holds fork=0, 1,...,n−1, for each suchkand eachx+K∈R/Kthere is anIk,x∈Ᏺτsuch thatδi(Ik,x)⊆(0 :dk−i(x+ K)) fori=0, 1,...,k. In particular, for eachx+K∈R/K, we haveδk(Ik,x)⊆(0 :x+K) for k=0, 1,...,n−1. Ifa∈Ix=[∩nk=−10Ik,x]∩(0 :dn(x+K))∈Ᏺτ, then
0=dn
(x+K)a=dn(x+K)a+dn−1(x+K)δ1(a) +···+ (x+K)δn(a)=(x+K)δn(a).
(3.10) Henceδk(Ix)⊆(0 :x+K) fork=0, 1,...,n. Ifx=1, this givesδk(I1)⊆(0 : 1 +K)=Kfor eachk, soᏲτis a differential filter of ordern.
4. Higher derivations and modules of quotients
If τ is a torsion theory on ModR, then an R-module Qτ(M) together with an R- homomorphismϕ:M→Qτ(M) is said to be alocalizationofMatτprovided that kerϕ and cokerϕareτ-torsion andQτ(M) isτ-injective andτ-torsion-free. AnR-moduleMis said to beτ-injectiveif HomR(−,M)=0 preserves short exact sequences 0→N1→N→ N2→0, whereN2is aτ-torsion module. The moduleQτ(M), called themodule of quo- tientsofM, is unique up to isomorphism whenever it can be shown to exist. Ohtake [14]
has shown that a localizationϕ:M→Qτ(M) exists for everyR-moduleMif and only if the torsion theory is hereditary. It is well known that ifτis hereditary, then we can set Qτ(M)=Eτ(M/tτ(M)), whereEτ(M/tτ(M)) is theτ-injective envelopeofM/tτ(M) [4,10].
Ifη:M→M/tτ(M) is the natural surjection andµ:M/tτ(M)→Qτ(M) is the canonical injection, thenϕ=µη.
Ifd:M→Mis a derivation of ordern, then we say thatdcan be extended to a deriva- tiondτ:Qτ(M)→Qτ(M) of ordernif the diagram
M ϕ
di
Qτ(M)
dτi
M ϕ Qτ(M)
(4.1)
is commutative fori=0, 1,...,n. We can now show that a derivationd:M→M of or- dernhas a unique extension to a derivationdτ:Qτ(M)→Qτ(M) of ordernfor every R-moduleM if and only ifτis a differential torsion theory of ordern. This result is es- tablished by the following lemma and proposition.
Lemma4.1. Let τbe a differential torsion theory of ordernonModR. If a derivationd: M→Mof orderncan be extended to a derivationdτ:Qτ(M)→Qτ(M)of ordern, thendτ is unique.
Proof. LetᏲτbe the differential filter of orderncorresponding toτand suppose thatdτ and ¯dτare derivations of ordernthat extenddtoQτ(M). Then fork, 0≤k≤n,dτ, ¯dτ, anddproduce derivationsd∗τ, ¯d∗τ, andd∗of orderkandd∗τand ¯d∗τliftd∗. SinceᏲτis a differential filter of orderk, ifx∈Qτ(M), then byLemma 3.5there areI,I∈Ᏺτsuch thatδi(I)⊆(0 :dτk−i(x)) andδi(I)⊆(0 : ¯dk−i(x)) fori=0, 1,...,k. Ifa∈K=I∩I∈Ᏺτ, then for eachkwe see that
0=
dτk−d¯τk(xa)
=dkτ(x)a+dkτ−1(x)δ1(a) +···+xδk(a)
−d¯kτ(x)a−d¯τk−1(x)δ1(a)− ··· −xδk(a)
=
dτk(x)−d¯τk(x)a+dτk−1(x)−d¯kτ−1(x)δ1(a) +···+dτ1(x)−d¯1τ(x)δi−1(a) + [x−x]δk(a)
=
dτk(x)−d¯k(x)a.
(4.2)
Hence, [dτk(x)−d¯τk(x)]K=0, so dkτ(x)−d¯kτ(x)∈tτ(Qτ(M))=0. Thereforedkτ=d¯τk for
k=0, 1,...,nand sodτ=d¯τ.
We can now establish the main result of this section.
Proposition4.2. Letτbe a hereditary torsion theory onModR. Then for everyR-module M, each derivation d:M→M of ordern can be extended uniquely to a derivationdτ: Qτ(M)→Qτ(M)of ordernif and only ifτis a differential torsion theory of ordern.
Proof. Suppose thatd:M→M is a derivation of ordern. If τis a differential torsion theory of ordern, thenᏲτis a differential filter of ordern, so it follows fromLemma 3.5 that di(tτ(M))⊆tτ(M) fori=0, 1,...,n. Hencedcan be extended to a derivationdτ: Qτ(M)→Qτ(M) of ordernsince Rim proved in [16] that such an extension exists when di(tτ(M))⊆tτ(M) fori=0, 1,...,n. Uniqueness follows fromLemma 4.1.
Conversely, suppose that every derivation d:M→M of order n can be extended uniquely to a derivationdτ:Qτ(M)→Qτ(M) of ordern. From the commutative diagram
M ϕ
di
Qτ(M)
dτi
M ϕ Qτ(M)
(4.3)
we see thatϕdi=diτϕfori=0, 1,...,n. So ifx∈tτ(M)=kerϕ, thenϕdi(x)=0 for each i. This gives di(x)∈kerϕ=tτ(M) and so we havedi(tτ(M))⊆tτ(M) fori=0, 1,...,n.
Calling onLemma 3.5again, we see thatτis a differential torsion theory of ordern.
Corollary4.3 [5, Proposition 2.3]. Ifτis a hereditary torsion theory onModR, then for everyR-moduleM, each derivationd:M→M can be extended uniquely to a derivation
dτ:Qτ(M)→Qτ(M)if and only ifτ is a differential torsion theory. In particular, τ is a differential torsion theory, then the derivationδ:R→Rextends uniquely to a derivation δτ:Qτ(R)→Qτ(R)defined on the ring of the quotients ofR.
Proof. The first part of the corollary is clear if we considerd:M→M to be derivation of order 1. Now letM=Rand apply this result to the derivationδ:R→Rto prove the
second part of the corollary.
One consequence ofProposition 4.2is that for a hereditary torsion theoryτon ModR, the right ideals of the filterᏲτform a test set for determining if derivations onMof order ncan be extended uniquely to derivations onQτ(M) of ordern.
5. Higher derivations and modules of coquotients
We now show that a result similar toProposition 4.2holds for colocalizations of modules whenever they universally exist. Colocalizations have been investigated under various ap- proaches by several authors, for example, see [3,6,13].
AnR-moduleCτ(M) together with anR-linear mappingϕ:Cτ(M)→Mis said to be acolocalizationofM atτprovided that kerϕand cokerϕareτ-torsion-free andCτ(M) isτ-torsion andτ-projective. We callCτ(M) themodule of coquotientsofM. We point out thatτis not assumed to be hereditary. When this is the case, a nonzero submodule of aτ-torsion module can beτ-torsion-free, a condition that is only possible for the zero submodule whenτis hereditary.
AnR-moduleM isτ-projectiveif HomR(M,−) preserves short exact sequences 0→ N1→N→N2→0, whereN1is aτ-torsion-free module. Ohtake was also able to show in [14] that a torsion theoryτ is cohereditary if and only if everyR-moduleM has a colocalization atτ. Ifϕ:Cτ(M)→M is a colocalization ofM atτ, then there is anR- epimorphismπ:Cτ(M)→tτ(M) such that ifµ:tτ(M)→M is the canonical injection, thenϕ=µπ. Furthermore, a module of coquotients is unique up to isomorphism when- ever it can be shown to exist.
Ifd:M→Mis a derivation of ordern, then we say thatdcan be lifted to a derivation dτ:Cτ(M)→Cτ(M) of ordernif the diagram
Cτ(M) ϕ
dτi
M
di
Cτ(M) ϕ M
(5.1)
is commutative fori=0, 1,...,n. We will now show that such liftings are always possible at a TTF theoryτon ModR.
Whenτ=(T, F) is cohereditary, the class F ofτis both a torsion and a torsion-free class, and the class F generates a hereditary torsion theoryσ=(F, D) on ModR. The pair (τ,σ) is often referred to as a TTF theory. Jans has shown in [11] that there is a one- to-one correspondence between TTF theories and idempotent idealsI of R. If (τ,σ) is a TTF theory with corresponding idempotent idealI, then the filter determined byσ is
given byᏲσ= {K⊆R|K⊇I,Ka right ideal ofR}. In this setting,tτ(R)=Iandtτ(M)= MI for eachR-moduleM. We have seen inExample 3.3 thatσ is a higher differential torsion theory although this condition onσ is not a factor in lifting higher derivations d:M→Mto higher derivationsdτ:Cτ(M)→Cτ(M). Sato has shown in [17] that ifτis cohereditary, thenI⊗RI→π I→µ Ris a colocalization ofR, where the mapπ:I⊗RI→I is given byni=1(ai⊗bi)→n
i=1aibi. Furthermore,I⊗RI is a ring, possibly without an identity, and an (R,R)-bimodule. Sato also shows in [17] thatM⊗RI⊗RI→π MI→µ M is a colocalization ofMatτ, where the mapπ:M⊗RI⊗RI→MIis given byni−1(xi⊗ai⊗ bi)→n
i=1xiaibi. SinceI is an idempotent ideal,δi(I)⊆Ifori=0, 1,...,nand it follows that each derivationd:M→M of ordern is such thatdi(MI)⊆MI fori=0, 1,...,n.
Hence,drestricted toMIproduces a derivationd:MI→MIof ordernthat will also be denoted byd.
We now need the following lemma.
Lemma5.1. IfIis an idempotent ideal ofRandd:M→Mis a derivation of ordern, then the mapρi:M×I×I→M⊗RI⊗RIgiven by
ρi(x,a,b)=i
j=0
di−j(x)⊗ j
k=0
δj−k(a)⊗δk(b)
(5.2) isR-balanced fori=0, 1,...,n. That is,ρiis additive in each variable and such thatρi(xr,a,b)
=ρi(x,ra,b)andρi(x,ar,b)=ρi(x,a,rb)for(x,a,b)∈M×I×Iandr∈R.
Proof. We showρi(xr,a,b)=ρi(x,ra,b). The proof thatρi(x,ar,b)=ρi(x,a,rb) is similar and so is omitted. Expandingij=0di−j(xr)⊗[kj=0δj−k(a)⊗δk(b)] by the first summa- tion, we have
di(xr)⊗ 0
k=0
δ0−k(a)⊗δk(b)
+di−1(xr)⊗ 1
k=0
δ1−k(a)⊗δk(b)
+di−2(xr)⊗ 2
k=0
δ2−k(a)⊗δk(b)
+···+xr⊗ i
k=0
δi−k(a)⊗δk(b)
.
(5.3)
Using (5.3) and the definition ofdi−jforj=0, 1,...,n, we get i
s=0
di−s(x)δs(r)
⊗ 0
k=0
δ0−k(a)⊗δk(b)
+ i−1
s=0
di−1−s(x)δs(r)
⊗ 1
k=0
δ1−k(a)⊗δk(b)
+ i−2
s=0
di−2−s(x)δs(r)
⊗ 2
k=0
δ2−k(a)⊗δk(b)
+···+xr⊗ i
k=0
δi−k(a)⊗δk(b)
(5.4)
which, by shifting subscripts, can be written as i
s=0
di−s(x)δs(r)
⊗ 0
k=0
δ0−k(a)⊗δk(b)
+ i
s=1
di−s(x)δs−1(r)
⊗ 1
k=0
δ1−k(a)⊗δk(b)
+ i
s=2
di−s(x)δs−2(r)
⊗ 2
k=0
δ2−k(a)⊗δk(b)
+···+xr⊗ i
k=0
δi−k(a)⊗δk(b)
.
(5.5)
Using properties of tensor products, (5.5) becomes i
s=0
di−s(x)
⊗ 0
k=0
δs(r)δ0−k(a)⊗δk(b)
+ i
s=1
di−s(x)
⊗ 1
k=0
δs−1(r)δ1−k(a)⊗δk(b)
+ i
s=2
di−s(x)
⊗ 2
k=0
δs−2(r)δ2−k(a)⊗δk(b)
+···+x⊗ i
k=0
rδi−k(a)⊗δk(b)
.
(5.6)
We now use (5.6) to compute the (i−t)th term, where 0≤t≤i. Each summand [is=udi−s(x)]⊗[uk=0δs−u(r)δu−k(a)⊗δk(b)] in (5.6) contains an (i−t)th term until t > u. These terms are
di−t(x)⊗ 0
k=0
δt(r)δ0−k(a)⊗δk(b)
+di−t(x)⊗ 1
k=0
δt−1(r)δ1−k(a)⊗δk(b)
+di−t(x)⊗ 2
k=0
δt−2(r)δ2−k(a)⊗δk(b)
+···+di−t(x)⊗ t
k=0
rδt−k(a)⊗δk(b)
.
(5.7)
