1 Introduction
Diesl [1] introduced the concept of nil-clean and strongly nil-clean rings and asked the question when a matrix ring is (strongly) nil-clean. As we have observed, it is difficult to characterize the arbitrary ring R such that
M
n
(
R
)
is nil-clean [2]. It is also known that the ring of all
2
×
2
-matrices over any commutative local ring is not strongly nil-clean [3]. On the other hand, the strong nil-cleanness of some generalizations of matrix rings has been considered. By [1], if R is a commutative ring with identity, then the formal block matrix ring
A
R
0
B
is strongly nil-clean if and only if
A
,
B
are strongly nil-clean. Moreover, the strong nil-cleanness of Morita contexts, formal matrix rings and generalized matrix rings has also been studied [2].
Let
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
be a completely 0-simple semigroup. Then the contacted semigroup ring
R
0
[
M
]
≅
M
(
R
[
G
]
;
I
,
Λ
;
P
)
is a Munn ring, which is isomorphic to the matrix ring
M
|
I
|
(
R
[
G
]
)
if such M is a Brandt semigroup. Thus, general contracted completely 0-simple semigroup rings can be viewed as a generalization of matrix rings. Motivated by this, we want to characterize the strong nil-cleanness of the contracted semigroup rings
R
0
[
M
]
in terms of the structure of M and the strong nil-cleanness of the group ring
R
[
G
]
. Noting that semigroup rings are also an extension of group rings, the strong nil-cleanness of certain kinds of group rings has been studied in [2,4,5].
However, for a finite completely 0-simple semigroup
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
, the contracted semigroup ring
R
0
[
M
]
contains an identity if and only if
|
I
|
=
|
Λ
|
and P is an invertible matrix over
G
0
, and if and only if
R
0
[
M
]
is isomorphic to the matrix ring
M
|
I
|
(
R
[
G
]
)
[6]. Note that the term “non-unital ring” or “general ring” refers to a ring that does not necessarily have an identity. It is known that Nicholson extended many of the results on the (strong) cleanness of rings with identity to non-unital rings [7], and that in [1,2], the (strong) nil-cleanness of non-unital rings has been studied.
The paper is organized as follows. In Section 2, some preliminaries are given. In Section 3, we show that the strong nil-cleanness of the contracted semigroup ring
R
0
[
M
]
of a completely 0-simple semigroup
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
can be characterized by
|
I
|
,
|
Λ
|
and the strong nil-cleanness of
R
[
G
]
. As an application, we determine when the contracted semigroup ring of a locally inverse semigroup with idempotents set locally finite is strongly nil-clean. In Section 4, we consider the strong nil-cleanness of certain classes of supplementary semilattice sums of rings, and the relationship between the strong nil-cleanness of contracted semigroup rings and semigroup rings.
Throughout this paper, a ring always means an associate non-unital (or general) ring, and we always assume that R is a ring with identity (not necessarily commutative).
2 Preliminaries
In this section, the notations and definitions on semigroups and semigroup rings which will be used in the sequel are provided, see [6,8,9].
Unless otherwise stated, a semigroup S is always assumed to have a zero element (denoted by
θ
or
θ
S
). Denote by
S
1
the semigroup obtained from S by adding an identity if S has no identity, otherwise, let
S
1
=
S
. Green’s equivalence relations play an important role in the theory of semigroups, which were introduced by Green (1951): for
a
,
b
∈
S
,
a
ℒ
b
⇔
S
1
a
=
S
1
b
,
a
ℛ
b
⇔
a
S
1
=
b
S
1
,
a
J
b
⇔
S
1
a
S
1
=
S
1
b
S
1
and
ℋ
=
ℒ
∩
ℛ
,
D
=
ℒ
∨
ℛ
.
A semigroup is said to be regular if every
ℒ
-class and every
ℛ
-class of it contains an idempotent. An inverse semigroup is a regular semigroup with commutative idempotents. Let
E
(
S
)
=
{
e
∈
S
|
e
2
=
e
}
be the set of idempotents of S. We call a regular semigroup S a locally inverse semigroup if eSe is an inverse subsemigroup of S for each
e
∈
E
(
S
)
. It is clear that an inverse semigroup is locally inverse. We say the idempotent set
E
(
S
)
of a locally inverse semigroup S is locally finite if
E
(
e
S
e
)
is finite for each
e
∈
E
(
S
)
.
We call a semigroup S a completely 0-simple semigroup if S is 0-simple and all its non-zero idempotents are primitive. Let G be a group, I and
Λ
be two non-empty sets and let
P
=
(
p
λ
i
)
be a
Λ
×
I
-matrix with entries in
G
0
(
=
G
∪
{
0
}
)
, and suppose that P is regular, in the sense that no row or column of P consists entirely of zeros. Let
M
=
(
I
×
G
×
Λ
)
∪
{
0
}
and define a multiplication on M by
(
i
,
x
,
λ
)
(
j
,
y
,
μ
)
=
(
i
,
x
p
λ
j
y
,
μ
)
,
if
p
λ
j
≠
0
,
0
,
otherwise
,
and
(
i
,
x
,
λ
)
0
=
0
(
i
,
x
,
λ
)
=
0
.
Then M is a completely 0-simple semigroup, denoted by
ℳ
0
(
G
;
I
,
Λ
;
P
)
. Note that the zero element of a completely 0-simple semigroup is denoted by 0 instead of
θ
. Conversely, every completely 0-simple semigroup is isomorphic to one constructed in this way.
In particular, if P is with entries in G, then the set
(
I
×
G
×
Λ
)
forms a subsemigroup of
ℳ
0
(
G
;
I
,
Λ
;
P
)
, we denote this subsemigroup by
ℳ
(
G
;
I
,
Λ
;
P
)
, and call it a completely simple semigroup.
Lemma 2.1
[8, Theorem 3.4.1] Let
M
1
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
and
M
2
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
be two completely 0-simple semigroups. Then
M
1
≅
M
2
if and only if there exist a
Λ
×
Λ
diagonal matrix X over
G
0
and an
I
×
I
diagonal matrix Y over
G
0
such that
P
=
X
Q
Y
.
By Lemma 2.1, for a completely 0-simple semigroup
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
, we can always assume the sandwich matrix P satisfies
p
11
=
e
, where
1
∈
I
∩
Λ
, and where e is the identity of G.
We introduce the concept of semigroup rings. Let S be a semigroup. The semigroup ring
R
[
S
]
of S is defined to be the ring consisting of all finite formal sums
∑
r
i
s
i
, where
r
i
∈
R
and
s
i
∈
S
, with the obvious definition of addition and with multiplication induced by the given multiplication in R and S according to the rule
∑
r
i
s
i
∑
l
j
t
j
=
∑
(
r
i
l
j
)
s
i
t
j
,
where
r
i
,
l
j
∈
R
and
s
i
,
t
j
∈
S
. Define
γ
∑
r
i
s
i
to be
∑
(
γ
r
i
)
s
i
, where
γ
,
r
i
∈
R
and
s
i
∈
S
, and if
1
R
is the identity of R, then
1
R
s
=
s
for all
s
∈
S
. If I is a subset of S, let
R
[
I
]
denote the set of all finite R-linear combinations of elements of I. We call the factor ring R[S]/Rθ the contracted semigroup ring of S over R, denoted by
R
0
[
S
]
. Note that if
S
0
is the semigroup resulting from the adjunction of a zero element
θ
to S (whether or not S has a zero to begin with), then
R
0
[
S
0
]
≅
R
[
S
]
. Thus, any semigroup ring can be regarded as a contracted semigroup ring.
Let S be a semigroup and
∑
r
i
s
i
∈
R
0
[
S
]
, where
r
i
∈
R
and
s
i
∈
S
. Define the support set of
∑
r
i
s
i
to be the subset
supp
∑
r
i
s
i
=
{
s
i
∈
S
|
r
i
≠
0
}
of S.
Recall the definition of a Munn ring. Let T be a ring, I,
Λ
be two non-empty sets. It will be necessary to describe a
I
×
Λ
-matrix over T in terms of its entries. In this case, we use such notations as
X
=
a
i
λ
,
X
=
a
11
a
12
a
21
a
22
,
X
=
[
a
1
,
a
2
,
…
,
a
n
,
…
]
.
We use
[
a
]
i
λ
to represent a
I
×
Λ
-matrix with only one non-zero entry a in the position
(
i
,
λ
)
. Let
X
=
[
a
i
λ
]
be a
I
×
Λ
-matrix over T. We say that the matrix X is bounded if
a
i
λ
=
0
for all but finitely many
(
i
,
λ
)
. Let P be a fixed
Λ
×
I
matrix over T (possibly not bounded) with the property that every row and every column of P contain an unit of T, and let
M
(
T
;
I
,
Λ
;
P
)
be the set of all bounded
I
×
Λ
matrices over T. Then
M
(
T
;
I
,
Λ
;
P
)
becomes a ring over R with the usual matrix addition and the multiplication
∘
defined by:
X
∘
Y
=
X
P
Y
, which is the usual matrix multiplication. We call
M
(
T
;
I
,
Λ
;
P
)
a Munn ring over T with the sandwich matrix P, or briefly a Munn ring [9,10]. Let
S
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
be a completely 0-simple semigroup over a group G. By [6, Lemma 5.17],
R
0
[
S
]
≅
M
(
R
[
G
]
;
I
,
Λ
;
P
)
is a Munn ring.
An element a in a ring U is said to be left quasi-regular if there exists
u
∈
U
such that
u
+
a
+
u
a
=
0
. A left ideal I of U is said to be left quasi-regular if every element of I is left quasi-regular. The Jacobson radical
J
(
U
)
of U is defined to be the left quasi-regular left ideal which contains every left quasi-regular left ideal of U [11]. We provide a method for determining whether an element of U belongs to
J
(
U
)
or not.
Lemma 2.2
[11, Lemma 2.15(ii)] Let U be a ring and
a
∈
U
. Then
a
∈
J
(
U
)
if and only if Ua is a left quasi-regular left ideal of U.
Note that the aforementioned definitions and results on Jacobson radicals are valid with “left” replaced by “right.”
3 Strong nil-cleanness of completely 0-simple semigroup rings
The first part of this section presents some elementary definitions and results on strongly nil-clean rings. The remainder of this section is concerned with the strong nil-cleanness of the contracted semigroup rings of both completely 0-simple semigroups and locally inverse semigroups.
Let U be a ring. Following Diesl [1], an element
u
∈
U
is said to be nil-clean if there is an idempotent
e
∈
U
and a nilpotent
b
∈
U
such that
u
=
e
+
b
. The element u is further said to be strongly nil-clean if such an idempotent and a nilpotent can be chosen to satisfy the equality
b
e
=
e
b
. The ring U is called a nil-clean (respectively, strongly nil-clean) ring if each element in it is nil-clean (respectively, strongly nil-clean).
We establish a basic result which will be used later.
Lemma 3.1
[1, Proposition 2.9] A left (resp., right) ideal of a strongly nil-clean ring is also strongly nil-clean.
The following lemma provides a very useful characterization of strongly nil-clean rings, in terms of Jacobson radicals. A ring is said to be boolean if every element of the ring is an idempotent.
Lemma 3.2
[2] A ring U is strongly nil-clean iff
U
/
J
(
U
)
is boolean and
J
(
U
)
is nil.
By Lemma 3.2, it will be helpful to know the Jacobson radicals of contracted completely 0-simple semigroup rings.
Lemma 3.3
[12] Let
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
be a completely 0-simple semigroup. Then
J
(
R
0
[
M
]
)
=
X
∈
R
0
[
M
]
|
P
X
P
∈
(
J
(
R
[
G
]
)
)
Λ
×
Λ
.
Noting that for a completely 0-simple semigroup
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
, if we denote the identity of G by e, then
e
M
e
≅
G
, and thus
e
R
0
[
M
]
e
≅
R
[
G
]
, whence
R
[
G
]
is a corner ring of
R
0
[
M
]
. Diesl proved the inheritance of the strong nil-cleanness by corner subrings of a strong nil-cleanly ring with identity from the ring with identity. This remains true for non-unital rings by applying similar argument in the proof of [1, Proposition 3.25].
Lemma 3.4
Let U be a ring and f be any idempotent in U. If U is strongly nil-clean, then the ring fUf is also strongly nil-clean.
Proof
Since Uf is a left ideal of U and fUf is a right ideal of Uf, we apply Lemma 3.1 to obtain first that Uf is a strongly nil-clean ring, and then that fUf is a strongly nil-clean ring. The lemma is proved.□
Later, Lemma 3.4 is used to give a necessary condition for a contracted completely 0-simple semigroup ring to be strongly nil-clean.
Lemma 3.5
Let M be a completely 0-simple semigroup with exactly two
ℛ
-classes and exactly two
ℒ
-classes. Then its contracted semigroup ring
R
0
[
M
]
is not strongly nil-clean.
Proof
By hypothesis, the completely 0-simple semigroup M is of the form
ℳ
0
(
G
;
2
,
2
;
P
)
, where G is a group,
2
=
{
1
,
2
}
and P is a
2
×
2
-matrix over
G
0
. Since M is a regular semigroup, by Lemma 2.1, the sandwich matrix P must be one of the matrices in the set
Δ
,
N
1
,
N
1
′
,
N
2
,
N
2
′
,
N
3
, up to isomorphic, where
Δ
=
e
0
0
e
,
N
1
=
e
e
e
0
,
N
1
′
=
e
0
e
e
,
N
2
=
e
e
0
e
,
N
2
′
=
0
e
e
e
,
N
3
=
e
e
e
g
,
and where e is the identity of the group G and
g
∈
G
. We claim that the contracted semigroup ring
R
0
[
M
]
is not strongly nil-clean, no matter which of the above normalized matrix P is chosen. There are five cases to be considered. For convenience, let
ℱ
denote the set consisting of all the fields of characteristic 2.
Case 1.
P
=
Δ
. Then
R
0
[
M
]
≅
M
(
R
[
G
]
;
2
,
2
;
P
)
≅
M
2
(
R
[
G
]
)
, and thus
R
0
[
M
]
is not strongly nil-clean, see [3].
Case 2.
P
=
N
1
,
P
=
N
1
′
,
P
=
N
2
or
P
=
N
2
′
. It is clear that P is an invertible matrix, and thus the map
R
0
[
M
]
→
M
2
(
R
[
G
]
)
defined by
A
↦
A
P
is an isomorphism of rings. Then, by Case 1,
R
0
[
M
]
is not strongly nil-clean.
Case 3.
P
=
N
3
with
g
≠
e
, and
R
∉
ℱ
. Noting that each element in the Munn ring
R
0
[
M
]
=
M
(
R
[
G
]
;
2
,
2
;
P
)
is of the form
a
b
c
d
, where
a
,
b
,
c
,
d
∈
R
[
G
]
. By Lemma 3.3, it is easy to verify that
(3.1)
J
(
R
0
[
M
]
)
=
a
b
c
d
∈
R
0
[
M
]
|
a
+
b
+
c
+
d
,
a
+
c
+
(
b
+
d
)
g
∈
J
(
R
[
G
]
)
.
By contrary, suppose that
R
0
[
M
]
is strongly nil-clean. This, together with Lemma 3.2, yields that
R
0
[
M
]
/
J
(
R
0
[
M
]
)
is boolean. Let c be an arbitrary element of
R
[
G
]
, define
N
=
0
0
0
c
∈
R
0
[
M
]
. Then
N
∘
N
+
J
(
R
0
[
M
]
)
=
(
N
+
J
(
R
0
[
M
]
)
)
2
=
N
+
J
(
R
0
[
M
]
)
, which is equivalent to say that
N
∘
N
−
N
∈
J
(
R
0
[
M
]
)
. Note that
N
∘
N
=
N
N
3
N
=
0
0
0
c
g
c
, hence
N
∘
N
−
N
=
0
0
0
c
g
c
−
c
. It follows that
(
c
g
c
−
c
)
g
∈
J
(
R
[
G
]
)
by (3.1). Next, we show that
J
(
R
[
G
]
)
is nil. For this, note that the group ring
R
[
G
]
≅
e
0
0
0
R
0
[
M
]
e
0
0
0
is a corner subring of
R
0
[
M
]
. Since
R
0
[
M
]
is strongly nil-clean by assumption,
R
[
G
]
is strongly nil-clean by Lemma 3.4. Then it follows from Lemma 3.2 that
J
(
R
[
G
]
)
is nil. Since g is an invertible element in G, we deduce that
(
c
g
−
e
)
c
is a nilpotent element. Since c is arbitrary, we can take
c
=
−
g
−
1
, it follows that
−
2
g
−
1
∈
R
[
G
]
is nilpotent. This, together with the fact
R
∉
ℱ
, implies that the element
g
−
1
∈
G
is nilpotent, that is,
(
g
−
1
)
m
=
0
for some positive integer m, which is a contradiction. Consequently,
R
0
[
M
]
is not strongly nil-clean, as required.
Case 4.
P
=
N
3
and
g
=
e
, and
R
∉
ℱ
. By Case 3, if
J
(
R
[
G
]
)
is not nil, then
R
0
[
M
]
is not strong nil-clean. Suppose now that
J
(
R
[
G
]
)
is nil. We claim that
R
0
[
M
]
is not strongly nil-clean. By Lemma 3.2, it is sufficient to prove that
R
0
[
M
]
/
J
(
R
0
[
M
]
)
is not boolean. Noting that, by Lemma 3.3, we have
(3.2)
J
(
R
0
[
M
]
)
=
a
b
c
d
∈
R
0
[
M
]
|
a
+
b
+
c
+
d
∈
J
(
R
[
G
]
)
.
Let
c
,
d
be two arbitrary elements of
R
[
G
]
. Define
N
=
0
0
c
d
∈
R
0
[
M
]
. Then
N
∘
N
=
N
N
3
N
=
0
0
(
c
+
d
)
c
(
c
+
d
)
d
,
thus
N
∘
N
−
N
=
0
0
(
c
+
d
)
c
−
c
(
c
+
d
)
d
−
d
.
By contrary, assume that
N
∘
N
−
N
∈
J
(
R
0
[
M
]
)
. It follows that
(
c
+
d
)
(
c
+
d
−
e
)
∈
J
(
R
[
G
]
)
. If we take
c
+
d
=
−
e
, then
2
e
=
(
c
+
d
)
(
c
+
d
−
e
)
∈
J
(
R
[
G
]
)
. Since
J
(
R
[
G
]
)
is nil, there exists a positive integer n such that
2
n
e
=
0
, which is a contradiction, because
R
∉
ℱ
. Therefore,
R
0
[
M
]
is not strongly nil-clean.
Case 5.
P
=
N
3
and
R
∈
ℱ
. By contrary, suppose that
R
0
[
M
]
is a strongly nil-clean ring. By similar arguments to the above, we infer that
J
(
R
[
G
]
)
is nil, and
R
0
[
M
]
/
J
(
R
0
[
M
]
)
is boolean. It is easy to check that
N
2
∘
N
2
−
N
2
=
0
e
+
g
e
e
+
g
. Since
char
R
=
2
, we have that
e
+
g
+
(
e
+
g
)
+
e
=
e
, which does not belong to
J
(
R
[
G
]
)
. This, together with (3.2), implies that
N
2
+
J
(
R
0
[
M
]
)
is not an idempotent in
R
0
[
M
]
/
J
(
R
0
[
M
]
)
. This is a contradiction, because
R
0
[
M
]
/
J
(
R
0
[
M
]
)
is boolean. Therefore,
R
0
[
M
]
is not strongly nil-clean.
Consequently, in either case, the contracted semigroup ring
R
0
[
M
]
is not strongly nil-clean, as required.□
If
M
=
ℳ
0
(
G
;
2
,
2
;
Δ
)
is a Brandt semigroup, where
Δ
is the identity matrix over
G
0
, by Lemma 3.5,
R
0
[
M
]
≅
M
2
(
R
[
G
]
)
is not strongly nil-clean. This may be thought of as an extension of the result in [3].
By applying Lemmas 3.1 and 3.5, a necessary condition for a contracted completely 0-simple semigroup ring to be strongly nil-clean is obtained.
Proposition 3.6
Let
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
be a completely 0-simple semigroup. If
R
0
[
M
]
is strongly nil-clean, then either
|
I
|
=
1
or
|
Λ
|
=
1
.
Proof
Suppose that
R
0
[
M
]
is strongly nil-clean. Noting that
|
I
|
≥
1
and
|
Λ
|
≥
1
. Then in order to show either
|
I
|
=
1
or
|
Λ
|
=
1
, assume on the contrary that
|
I
|
≥
2
and
|
Λ
|
≥
2
. It would then follow that the
Λ
×
I
-matrix P may be written in the block form
P
1
P
2
P
3
P
4
, where
P
1
is a
2
×
2
-matrix over
G
0
. Define a subset
A
=
(
a
i
λ
)
∈
R
0
[
M
]
|
a
i
λ
=
0
for
all
i
≠
1
,
2
of
R
0
[
M
]
. It is clear that A is closed under multiplication. Moreover, let
(
a
i
λ
)
∈
A
and
(
b
j
μ
)
∈
R
0
[
M
]
, then the entry in the
(
i
,
μ
)
-position of the product
(
a
i
λ
)
∘
(
b
j
μ
)
is
∑
λ
∈
Λ
,
j
∈
I
a
i
λ
p
λ
j
b
j
μ
. Note that
∑
λ
∈
Λ
,
j
∈
I
a
i
λ
p
λ
j
b
j
μ
=
0
for all
i
∉
{
1
,
2
}
because
a
i
λ
=
0
for all such i. It follows that
(
a
i
λ
)
∘
(
b
j
μ
)
∈
A
, whence A is a right ideal of
R
0
[
M
]
. Since
R
0
[
M
]
is strongly nil-clean, A is strongly nil-clean by Lemma 3.1. Moreover, A is isomorphic to the Munn ring
M
R
[
G
]
;
2
,
Λ
;
P
1
P
2
. Then a similar argument shows that the Munn ring
U
=
M
(
R
[
G
]
;
2
,
2
;
P
1
)
is isomorphic to a left ideal of A, and hence U is strongly nil-clean by Lemma 3.1 again. This is a contradiction, because
U
≅
R
0
[
ℳ
0
(
G
;
2
,
2
;
P
1
)
]
is not strongly nil-clean by Lemma 3.5. Therefore, we must have either
|
I
|
=
1
or
|
Λ
|
=
1
.□
The interesting case occurs when a completely 0-simple semigroup
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
contains a unique
ℒ
-class (or, a unique
ℛ
-class).
Lemma 3.7
Let
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
be a completely 0-simple semigroup. If
|
I
|
=
1
or
|
Λ
|
=
1
, then
R
0
[
M
]
is strongly nil-clean if and only if
R
[
G
]
is strongly nil-clean.
Proof
It is sufficient to consider the case of
|
Λ
|
=
1
, since the case of
|
I
|
=
1
is dual. Assume that
|
Λ
|
=
1
. Before moving on, we explore the structure of M and determine
J
(
R
0
[
M
]
)
. For this, since M is a completely 0-simple semigroup, S is regular, whence every
ℛ
-class of M contains at least one idempotent. Since M has only one
ℒ
-class, it follows that each
ℛ
-class of M is a maximal group in M, and hence the
1
×
I
-matrix P must be of the form
[
e
,
e
,
…
,
e
,
…
]
whose entries are all equal to e, where e is the identity of the group G. Denote
N
∗
by the set
{
1
,
2
,
…
}
consisting of all positive integers. Let
x
=
x
1
,
x
2
,
…
,
x
n
,
0
,
…
T
∈
R
0
[
M
]
with
x
1
,
x
2
,
…
,
x
n
∈
R
[
G
]
and whose other entries are all equal to 0, where
n
∈
N
∗
. Then it is easy to check that
P
x
P
=
∑
i
=
1
n
x
i
e
,
e
,
…
,
e
,
…
. Thus, by Lemma 3.3,
(3.3)
J
(
R
0
[
M
]
)
=
x
=
x
1
,
x
2
,
…
,
x
n
,
0
,
…
T
∈
R
0
[
M
]
|
∑
i
=
1
n
x
i
∈
R
[
G
]
.
Now we suppose that
R
[
G
]
is strongly nil-clean. By Lemma 3.2,
R
[
G
]
/
J
(
R
[
G
]
)
is boolean and
J
(
R
[
G
]
)
is nil. We want to show that
R
0
[
M
]
is strongly nil-clean. It suffices to prove that
J
(
R
0
[
M
]
)
is nil and
R
0
[
M
]
/
J
(
R
0
[
M
]
)
is boolean, by Lemma 3.2 again. For this, let
x
=
x
1
,
x
2
,
…
,
x
n
,
0
,
…
T
∈
J
(
R
0
[
M
]
)
, where
x
1
,
x
2
,
…
,
x
n
∈
R
[
G
]
and
n
∈
N
∗
. By (3.3),
∑
i
=
1
n
x
i
∈
J
(
R
[
G
]
)
, and because
J
(
R
[
G
]
)
is nil, it follows that
∑
i
=
1
n
x
i
is a nilpotent element.
Note that, for any element
y
=
y
1
,
y
2
,
…
,
y
t
,
0
,
…
T
∈
R
0
[
M
]
, where
y
1
,
y
2
,
…
,
y
t
∈
R
[
G
]
and
t
∈
N
∗
, we have
y
∘
y
=
y
P
y
=
y
∑
i
=
1
t
y
i
, and thus for any integer
k
≥
2
,
y
k
=
y
k
−
2
∘
y
∘
y
=
y
k
−
2
∘
y
∑
i
=
1
t
y
i
=
…
=
y
⋅
∑
i
=
1
t
y
i
k
−
1
.
Therefore, x is a nilpotent element when
x
∈
J
(
R
0
[
M
]
)
, which yields that
J
(
R
0
[
M
]
)
is nil.
On the other hand, for any
z
=
z
1
,
z
2
,
…
,
z
m
,
0
,
…
T
∈
R
0
[
M
]
\
J
(
R
0
[
M
]
)
, where
z
1
,
…
,
z
m
∈
R
[
G
]
and
m
∈
N
∗
, we have
∑
j
=
1
m
z
j
∉
J
(
R
[
G
]
)
, whence
∑
j
=
1
m
z
j
∈
R
[
G
]
\
J
(
R
[
G
]
)
. Note that
z
2
−
z
=
z
1
∑
j
=
1
m
z
j
−
z
1
,
…
,
z
m
∑
j
=
1
m
z
j
−
z
m
,
0
,
…
T
=
z
1
∑
j
=
1
m
z
j
−
e
,
…
,
z
m
∑
j
=
1
m
z
j
−
e
,
0
,
…
T
=
[
z
1
,
…
,
z
m
,
0
,
…
]
T
∑
j
=
1
m
z
j
−
e
,
where e is the identity of G. Note also that
∑
i
=
1
m
z
i
∑
j
=
1
m
z
j
−
e
=
∑
j
=
1
m
z
j
2
−
∑
j
=
1
m
z
j
∈
J
(
R
[
G
]
)
, because
∑
j
=
1
m
z
j
∈
R
[
G
]
\
J
(
R
[
G
]
)
and
R
[
G
]
/
J
(
R
[
G
]
)
is boolean. Then, by (3.3),
z
2
−
z
∈
J
(
R
0
[
M
]
)
. It follows that
R
0
[
M
]
/
J
(
R
0
[
M
]
)
is boolean.
Conversely, suppose that
R
0
[
M
]
is strongly nil-clean. We claim that
R
[
G
]
is strongly nil-clean. Indeed, let f denote the element
[
e
,
0
,
…
,
0
,
…
]
T
in
R
0
[
M
]
, where e is the identity of G. Then f is an idempotent, and moreover
f
∘
R
0
[
M
]
∘
f
≅
R
[
G
]
. This, together with Lemma 3.4, implies that
R
[
G
]
is strongly nil-clean.□
We have obtained all the preliminaries needed to prove the following principal theorem in this section.
Theorem 3.8
Let
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
be a completely 0-simple semigroup. Then
R
0
[
M
]
is strongly nil-clean if and only if
R
[
G
]
is strongly nil-clean, and either
|
I
|
=
1
or
|
Λ
|
=
1
.
Proof
Note that if
R
0
[
M
]
is strongly nil-clean, then
|
I
|
=
1
or
|
Λ
|
=
1
by Lemma 3.6. Then the result follows immediately from Lemma 3.7.□
Note that for a completely 0-simple semigroup
M
=
ℳ
0
(
G
;
I
,
Λ
;
P
)
, if
R
0
[
M
]
is strongly nil-clean, it follows from the proof of Theorem 3.8 that all entries of P must be non-zero, and hence M must be of the form
ℳ
(
G
;
I
,
Λ
;
P
)
∪
{
0
}
.
In the following, we provide two corollaries of Theorem 3.8.
Corollary 3.9
Let
M
=
ℳ
(
G
;
I
,
Λ
;
P
)
be a completely simple semigroup. Then
R
[
M
]
is strongly nil-clean if and only if
R
[
G
]
is strongly nil-clean, and either
|
I
|
=
1
or
|
Λ
|
=
1
.
Proof
Note that the set
M
0
≔
ℳ
(
G
;
I
,
Λ
;
P
)
∪
{
0
}
forms a completely 0-simple semigroup with
R
0
[
M
0
]
≅
R
[
M
]
. The result then follows from Theorem 3.8.□
Corollary 3.10
Let S be a locally inverse semigroup with idempotent set locally finite and finitely many
D
-classes. Then
R
0
[
S
]
is strongly nil-clean if and only if the following two conditions hold.
Each
D
-class D of S has either a unique
ℛ
-class or a unique
ℒ
-class;
For each maximal subgroup G of S,
R
[
G
]
is strongly nil-clean.
Proof
By [13, Theorem 5.1],
R
0
[
S
]
is a finite direct product of the contracted completely 0-simple semigroup rings
R
0
D
α
¯
0
, where
α
runs over the set
(
S
/
D
)
∗
consisting all non-zero elements in
S
/
D
. Then by [1, Proposition 3.13],
R
0
[
S
]
is strongly nil-clean if and only if
R
0
D
α
¯
0
is strongly nil-clean for each
α
∈
(
S
/
D
)
∗
. Furthermore, for each
α
∈
(
S
/
D
)
∗
, the maximal subgroup of
D
α
¯
0
is isomorphic to the maximal subgroup in
D
α
, and the number of
ℒ
-classes (resp.,
ℛ
-classes) in
D
α
¯
0
is equal to the number of
ℒ
-classes (resp.,
ℛ
-classes) in
D
α
, see [13]. The result then follows from Theorem 3.8.□
4 Strong nil-cleanness and strong semilattice of semigroups
We recall the definition of strong semilattice of semigroups. Let Y be a semilattice with natural partial order
≤
and
S
α
be a family of semigroups indexed by Y. We say a semigroup S is a strong semilattice of semigroups
S
α
(
α
∈
Y
)
if S is the disjoint union of the semigroups
S
α
, and for all
α
>
β
in Y there exists a homomorphism
φ
α
,
β
:
S
α
→
S
β
satisfying the following conditions:
φ
α
,
α
is the identity map of
S
α
;
If
α
>
β
>
γ
, then
φ
β
,
γ
φ
α
,
β
=
φ
α
,
γ
;
If
a
∈
S
α
and
b
∈
S
β
, then the multiplication in S is given by
a
b
=
φ
α
,
α
β
(
a
)
φ
β
,
α
β
(
b
)
.
If this is the case, denote the semigroup S by
S
=
Y
;
S
α
,
φ
α
,
β
. Note that each
φ
α
,
β
can be R-linearly extended into a semigroup ring homomorphism from
R
S
α
to
R
S
β
. Note also that
R
[
S
]
is always a supplementary semilattice sum of subrings
R
S
α
(
α
∈
Y
).
For the rest of this section, we always assume that S is a strong semilattice Y of semigroups
S
α
(
α
∈
Y
), where Y is finite. The main aim of this section is to construct a relationship between the strong nil-cleanness of
R
0
[
S
]
and the strong nil-cleanness of
R
S
α
(
α
∈
Y
).
Let
β
be a fixed maximal element in Y, and then denote the set
S
\
S
β
by T. Thus, T is an ideal of S, whence
R
0
[
T
]
is an ideal of
R
0
[
S
]
. We introduce some preliminary results and definitions which are used to prove the main result of this section later.
Lemma 4.1
Every idempotent of
R
0
[
S
]
/
R
0
[
T
]
can be lifted to an idempotent of
R
0
[
S
]
.
Proof
Suppose that
x
1
+
x
2
+
R
0
[
T
]
∈
R
0
[
S
]
/
R
0
[
T
]
is an idempotent, where
x
1
∈
R
S
β
and
x
2
∈
R
0
[
T
]
. Then
x
1
2
−
x
1
+
x
1
x
2
+
x
2
x
1
+
x
2
2
−
x
2
∈
R
0
[
T
]
. Since
β
is maximal in Y and
R
S
β
is a subring of
R
0
[
S
]
, we infer that
s
u
p
p
x
1
2
−
x
1
∩
supp
x
1
x
2
+
x
2
x
1
+
x
2
2
−
x
2
=
∅
, which yields that
x
1
=
x
1
2
∈
R
S
β
is an idempotent. Since
x
1
+
x
2
+
R
0
[
T
]
=
x
1
+
R
0
[
T
]
, the result follows.□
Lemma 4.2
Let
x
=
x
1
+
x
2
∈
R
0
[
S
]
, where
x
1
∈
R
S
β
and
x
2
∈
R
0
[
T
]
. If
x
∈
J
(
R
0
[
S
]
)
, then
x
1
∈
J
R
S
β
.
Proof
Suppose that
0
≠
x
=
x
1
+
x
2
∈
J
(
R
0
[
S
]
)
. We claim that
x
1
∈
J
R
S
β
. For this, let z be an arbitrary element in
R
S
β
, then by hypothesis, there exists an element
y
∈
R
0
[
S
]
such that
z
x
+
y
+
y
(
z
x
)
=
0
. Write
y
=
y
1
+
y
2
, where
y
1
∈
R
S
β
and
y
2
∈
R
0
[
T
]
. It follows from the maximality of
β
that
z
x
1
+
y
1
+
y
1
z
x
1
=
0
, whence
R
S
β
x
1
is a left quasi-regular left ideal of
R
S
β
. By Lemma 2.2,
x
1
∈
J
R
S
β
, as required.□
Let E be a semilattice and
α
,
γ
∈
E
. Then
γ
is said to be maximal under
α
[14] if
α
>
γ
and there is no
ν
∈
E
such that
α
>
ν
>
γ
. Denote by
α
ˆ
the set
{
γ
∈
E
:
γ
is
maximal
under
α
}
. Let
α
be a non-zero element in the finite semilattice Y. For each
a
∈
R
S
α
, by [14], define an element
(4.1)
a
∗
=
a
+
∑
α
i
1
,
…
,
α
i
t
⊆
α
ˆ
,
t
≥
1
(
−
1
)
t
φ
α
,
α
i
1
,
…
,
α
i
t
(
a
)
∈
R
0
[
S
]
,
where
α
i
1
,
…
,
α
i
t
runs over all non-empty subsets of
α
ˆ
. Noting that, in (4.1), each element
α
i
1
,
…
,
α
i
t
∈
Y
is strictly smaller than
α
, and thus the element
φ
α
,
α
i
1
,
…
,
α
i
t
(
a
)
∈
R
0
[
S
]
actually belongs to
∑
γ
<
α
R
[
S
γ
]
.
Lemma 4.3
[14] Let
α
be a non-zero element in Y. If A is an ideal of
R
S
α
, then
A
∗
=
{
a
∗
|
a
∈
A
}
is an ideal of
R
0
[
S
]
. Moreover, the map
A
→
A
∗
:
a
↦
a
∗
is a ring isomorphism from A to
A
∗
.
Note that Lemma 4.3 is true for the more general case when Y is taken to be a pseudofinite semilattice [14].
Lemma 4.4
J
(
R
[
S
β
]
)
+
R
0
[
T
]
⊆
J
(
R
0
[
S
]
)
+
R
0
[
T
]
.
Proof
If
J
(
R
0
[
S
]
)
=
0
, then
J
(
R
[
S
α
]
)
=
0
for each
α
∈
Y
, because
J
(
R
0
[
S
]
)
=
0
if and only if
J
(
R
[
S
α
]
)
=
0
for each
α
∈
Y
by [14, Theorem 2]. Hence, in this case,
J
(
R
[
S
β
]
)
+
R
0
[
T
]
⊆
J
(
R
0
[
S
]
)
+
R
0
[
T
]
holds true. If
J
(
R
0
[
S
]
)
≠
0
, then we claim that
J
(
R
[
S
β
]
)
+
R
0
[
T
]
⊆
J
(
R
0
[
S
]
)
+
R
0
[
T
]
. Indeed, for any element
0
≠
x
∈
J
(
R
[
S
β
]
)
, the element
x
∗
∈
R
0
[
S
]
defined by (4.1) is non-zero, and furthermore belongs to
J
(
R
[
S
β
]
)
∗
. Since
J
(
R
[
S
β
]
)
∗
is an ideal of
R
0
[
S
]
and is isomorphic to
J
(
R
[
S
β
]
)
by Lemma 4.3, we infer that
J
(
R
[
S
β
]
)
∗
is a left quasi-regular ideal of
R
0
[
S
]
. Because
J
(
R
0
[
S
]
)
contains any left quasi-regular left ideal of
R
0
[
S
]
,
J
(
R
[
S
β
]
)
∗
⊆
J
(
R
0
[
S
]
)
. It follows that
x
∗
∈
J
(
R
0
[
S
]
)
. Therefore, by the definition of
x
∗
again,
x
+
R
0
[
T
]
=
x
∗
+
R
0
[
T
]
∈
J
(
R
0
[
S
]
)
+
R
0
[
T
]
. Consequently, we have
J
(
R
[
S
β
]
)
+
R
0
[
T
]
⊆
J
(
R
0
[
S
]
)
+
R
0
[
T
]
.□
Lemma 4.5
J
(
R
0
[
S
]
/
R
0
[
T
]
)
=
(
J
(
R
0
[
S
]
)
+
R
0
[
T
]
)
/
R
0
[
T
]
.
Proof
First, we show that
J
(
R
0
[
S
]
/
R
0
[
T
]
)
⊆
(
J
(
R
0
[
S
]
)
+
R
0
[
T
]
)
/
R
0
[
T
]
. For this, let
x
+
R
0
[
T
]
∈
J
(
R
0
[
S
]
/
R
0
[
T
]
)
with
x
∈
R
[
S
β
]
. Then for each
y
∈
R
[
S
β
]
,
y
x
+
R
0
[
T
]
is a left quasi-regular element of
R
0
[
S
]
/
R
0
[
T
]
. This, together with the maximality of
β
, implies that
R
[
S
β
]
x
is a left quasi-regular left ideal of
R
[
S
β
]
, whence
x
∈
J
(
R
[
S
β
]
)
. By Lemma 4.4, we infer that
x
∈
J
(
R
0
[
S
]
)
+
R
0
[
T
]
, and hence
x
+
R
0
[
T
]
∈
(
J
(
R
0
[
S
]
)
+
R
0
[
T
]
)
/
R
0
[
T
]
, as required. Next, we prove that
(
J
(
R
0
[
S
]
)
+
R
0
[
T
]
)
/
R
0
[
T
]
⊆
J
(
R
0
[
S
]
/
R
0
[
T
]
)
. Assume that
x
+
R
0
[
T
]
∈
(
J
(
R
0
[
S
]
)
+
R
0
[
T
]
)
/
R
0
[
T
]
, where
x
∈
J
(
R
0
[
S
]
)
. Then x is a left quasi-regular element in
R
0
[
S
]
, which is equivalent to say that
R
0
[
S
]
x
is a left quasi-regular left ideal of
R
0
[
S
]
, whence
(
R
0
[
S
]
/
R
0
[
T
]
)
(
x
+
R
0
[
T
]
)
is also a left quasi-regular left ideal of
R
0
[
S
]
/
R
0
[
T
]
. This implies that
x
+
R
0
[
T
]
∈
J
(
R
0
[
S
]
/
R
0
[
T
]
)
, as required.□
The following result provides us an equivalent characterization for a non-unital ring to be strongly nil-clean, which plays an important role in the below proof.
Lemma 4.6
[2] Let A be a non-unital ring and U be an ideal of A. Then A is strongly nil-clean if and only if the following three conditions hold:
U and A/U are strongly nil-clean;
Every idempotent of A/U can be lifted to an idempotent of A;
J
(
A
/
U
)
=
(
U
+
J
(
A
)
)
/
U
.
We are now ready to prove the main result of this section concerning the strong nil-cleanness of the contracted semigroup ring
R
0
[
S
]
.
Theorem 4.7
Let S be a strong semilattice Y of semigroups
S
α
(
α
∈
Y
)
, where Y is finite. Then
R
0
[
S
]
is strongly nil-clean if and only if
R
0
S
θ
Y
is strong nil-clean and
R
S
α
is strongly nil-clean for each
θ
Y
≠
α
∈
Y
.
Proof
We prove the result by induction on the cardinality of the set Y. If
Y
=
{
θ
Y
}
, this is trivial. If
|
Y
|
≥
2
, then let
β
be a maximal element in Y and define
Y
′
be the subset
Y
\
{
β
}
of Y. By induction, the result holds for
T
=
∪
α
∈
Y
\
{
β
}
S
α
, which means that
R
0
[
T
]
is strongly nil-clean if and only if
R
S
α
is strongly nil-clean for each
α
∉
{
θ
Y
,
β
}
and
R
0
S
θ
Y
is strongly nil-clean. Thus, in order to show that the result holds for S, it is sufficient to prove that
R
0
[
S
]
is strongly nil-clean if and only if both
R
S
β
=
R
0
[
S
]
/
R
0
[
T
]
and
R
0
[
T
]
are strongly nil-clean. Note that Lemma 4.6(ii) and (iii) holds true if we replace A, U and A/U by
R
0
[
S
]
,
R
0
[
T
]
and
R
0
[
S
]
/
R
0
[
T
]
≅
R
S
β
, respectively, by Lemmas 4.1 and 4.5. Then the result is obtained immediately by Lemma 4.6.□
A similar argument in the proof of Theorem 4.7 provides us a characterization of the strong nil-cleanness of the semigroup ring
R
[
S
]
.
Corollary 4.8
Let S be a strong semilattice Y of semigroups
S
α
(
α
∈
Y
)
, where Y is finite. Then
R
[
S
]
is strongly nil-clean if and only if
R
[
S
α
]
is strongly nil-clean for each
α
∈
Y
.
We end this paper with a brief discussion of the relationship between the strong nil-cleanness of semigroup rings and the strong nil-cleanness of contracted semigroup rings. Let N be a semigroup. Since
R
0
[
N
]
=
R
[
N
]
/
R
θ
, we get that
R
0
[
N
]
is strongly nil-clean whenever
R
[
N
]
is strongly nil-clean by Lemma 4.6. However, if
R
0
[
N
]
is strongly nil-clean, it does not follow that
R
[
N
]
is strongly nil-clean. The following example illustrates this fact.
Example 4.1
Let K be a field and
N
=
{
a
,
θ
}
be a semigroup with multiplication given by
a
2
=
a
θ
=
θ
a
=
θ
2
=
θ
.
Note that each non-zero element of
R
0
[
N
]
is of the form ka, where
0
≠
k
∈
K
. Then in
R
0
[
N
]
,
(
k
a
)
2
=
k
2
a
2
=
0
. Hence,
R
0
[
N
]
is nil, whence
R
0
[
N
]
is strongly nil-clean.
It is clear that the set
{
k
a
−
k
θ
|
k
∈
K
}
(resp.,
{
θ
}
) collects all nilpotent elements (resp., idempotents) in
R
[
N
]
. We claim that
R
[
N
]
is not strongly nil-clean. For this, it suffices to show that the element
2
a
∈
R
[
N
]
is not strongly nil-clean. By contrary, suppose that
2
a
=
θ
+
(
k
a
−
k
θ
)
for some
k
∈
K
, then k must be equal to
1
K
, whence
2
a
=
a
, which is a contradiction.
