Cross-connections in Clifford Semigroups

P.A. Azeef Muhammed Centre for Research in Mathematics and Data Science, Western Sydney University, Penrith, NSW 2751, Australia. and C.S. Preenu Department of Mathematics, University College, Thiruvananthapuram, Kerala 695034, India.

Abstract.

An inverse Clifford semigroup (often referred to as just a Clifford semigroup) is a semilattice of groups. It is an inverse semigroup and in fact, one of the earliest studied classes of semigroups [6]. In this short note, we discuss various structural aspects of a Clifford semigroup from a cross-connection perspective. In particular, given a Clifford semigroup $S$ , we show that the semigroup $T\mathbb{L}(S)$ of normal cones is isomorphic to the original semigroup $S$ , even when $S$ is not a monoid. Hence, we see that cross-connection description degenerates in Clifford semigroups. Further, we specialise the discussion to provide the description of the cross-connection structure in an arbitrary semilattice, also.

1. Introduction

Grillet introduced cross-connections as a pair of functions to describe the interrelationship between the posets of principal left and right ideals of a regular semigroup. This construction involved building two intermediary semigroups and further identifying a fundamental image of the semigroup as a subdirect product, using the cross-connection functions. But isomorphic posets give rise to isomorphic cross-connections. So, Nambooripad replaced posets with certain small categories to overcome this limitation. Hence, using the categorical theory of cross-connections, Nambooripad constructed arbitrary semigroups from their ideal structure.

Starting from a regular semigroup $S$ , Nambooripad identified two small categories: $\mathbb{L}(S)$ and $\mathbb{R}(S)$ which abstract the principal left and right ideal structures of the semigroup, respectively. He showed that these categories are interconnected using a pair of functors. It can be seen that the object maps of these functors coincides with Grillet’s cross-connection functions and so Nambooripad called his functors also cross-connections. Further, Nambooripad showed that this correspondence can be extended to an explicit category equivalence between the category of regular semigroups and the category of cross-connections. Hence the ideal structure of a regular semigroup can be completely captured using these ‘cross-connected’ categories.

Being a rather technical construction, it is instructive to work out the simplifications that arise in various special classes of semigroups. There has been several works in this direction [4, 2, 10, 3, 5, 1] and in this short article, we propose to outline how the construction simplifies in a couple of very natural classes of regular semigroups: namely Clifford semigroups and semilattices. As the reader may see, this exercise also provides some useful illustrations to several cross-connection related subtleties.

In fact, Clifford semigroups are one of the first classes of inverse semigroups whose structure was studied. It was originally defined [6] as a union of groups in which idempotents commute. It may be noted that some authors refer to general union of groups also as Clifford semigroups but we shall follow [8] and refer to a semilattice of groups as a Clifford semigroup. The following characterizations of Clifford semigroups will be useful in the sequel.

Theorem 1.1.

[8, Theorem 4.2.1][7, Theorem 1.3.11] Let $S$ be a semigroup. Then the following statements are equivalent.

(1)

$S$ is a Clifford semigroup;
(2)

$S$ is a semilattice of groups;
(3)

$S$ is a strong semilattice of groups;
(4)

$S$ is regular and the idempotents of $S$ are central;
(5)

Every $\mathrel{\mathscr{D}}$ class of $S$ has a unique idempotent.

In Nambooripad’s cross-connection description, starting from a regular semigroup $S$ , two small categories of principal left and right ideals (denoted by $\mathbb{L}(S)$ and $\mathbb{R}(S)$ , respectively in the sequel) are defined. Then their inter-relationship is abstracted as a pair of functors called cross-connections. Conversely, given an abstractly defined pair of cross-connected categories (with some special properties), one can construct a regular semigroup. This correspondence between regular semigroups and cross-connections is proved to be a category equivalence.

The construction of the regular semigroup from the category happens in several layers and the crucial object here is the intermediary regular semigroup $T\mathbb{L}(S)$ of normal cones from the given category $\mathbb{L}(S)$ . We shall see that when the semigroup $S$ is Clifford, then the semigroup $T\mathbb{L}(S)$ is isomorphic to $S$ . It is known that this is not true in general [5] even for an inverse semigroup $S$ . This in turn, highly degenerates the cross-connection structure in Clifford semigroups. This is discussed in the next section. In the last section, we specialise our discussion to an arbitrary semilattice and describe the cross-connections therein.

As mentioned above, since the article can be seen as a part of a continuing project of studying the various classes of regular semigroups within the cross-connection framework, we refer the reader to [5, 10, 1] for the preliminary notions and formal definitions in Nambooripad’s cross-connection theory. We also refer the reader to [9] for the original treatise on cross-connections.

2. Normal categories and cross-connections in Clifford semigroups

Recall from [9] that given a regular semigroup $S$ , the normal category $\mathbb{L}(S)$ of principal left ideals are defined as follows. The object set

v\mathbb{L}(S):=~{}~{}\{Se:e\in E(S)\}

and the morphisms in $\mathbb{L}(S)$ are partial right translations. In fact, the set of all morphisms between two objects $Se$ and $Sf$ may be characterised as the set $\{\rho(e,u,f):u\in eSf\}$ , where the map $\rho(e,u,f)$ sends $x\in Se$ to $xu\in Sf$ .

First, we proceed to discuss some special properties of the category $\mathbb{L}(S)$ when $S$ is a Clifford semigroup. This will lead us to the characterisation of the semigroup $T\mathbb{L}(S)$ of all normal cones in $S$ .

Proposition 2.1.

Let $S$ be a Clifford semigroup. Two objects in $\mathbb{L}(S)$ are isomorphic if and only if they are identical.

Proof.

Clearly, identical objects are always isomorphic. Conversely, suppose $Se$ and $Sf$ are two isomorphic objects in $\mathbb{L}(S)$ . Then by [9, Proposition III.13(c)], we have $e\mathrel{\mathscr{D}}f$ . Recall that in a Clifford semigroup, the Green’s relations $\mathscr{L}$ , $\mathscr{R}$ and $\mathrel{\mathscr{D}}$ are identical. Therefore $e\mathscr{L}f$ and hence $Se=Sf$ . ∎

Given the normal category $\mathbb{L}(S)$ of principal left ideals of a regular semigroup $S$ , it is known that two morphisms are equal, i.e. $\rho(e,u,f)=\rho(g,v,h)$ if and only if $e\mathrel{\mathscr{L}}g$ , $f\mathrel{\mathscr{L}}h$ , and $v=gu$ . Also, given two morphisms $\rho(e,u,f)$ and $\rho(g,v,h)$ , they are composable if and only $Sf=Sg$ so that $\rho(e,u,f)\rho(g,v,h)=\rho(e,uv,h)$ . Now, we see that the equality of morphisms simplify when $S$ is a Clifford semigroup.

Proposition 2.2.

Let $S$ be a Clifford semigroup, then $\rho(e,u,f)=\rho(g,v,h)$ in the category $\mathbb{L}(S)$ if and only if $e=g$ , $u=v$ and $f=h$ .

Proof.

Suppose that two morphisms $\rho(e,u,f)=\rho(g,v,h)$ are equal. Recall that by [9, Lemma II.12], this implies that $Se=Sg$ , $Sf=Sh$ and $v=gu$ . That is, the elements $e$ and $g$ are two $\mathscr{L}$ related idempotents. But since $\mathscr{L}$ and $\mathscr{H}$ are identical in a Clifford semigroup $S$ and since a $\mathscr{H}$ -class can contain at most one idempotent, we have $e=g$ . Similarly we get $f=h$ . So, the sets $eSf=gSh$ are equal and also $v=gu=eu=u$ . ∎

Now, we proceed to characterise the building blocks of the cross-connection construction, namely the normal cones in the category $\mathbb{L}(S)$ . An ‘order-respecting’ collection of morphisms in a normal category is defined as a normal cone.

Definition 2.1.

Let $\mathbb{L}(S)$ be the normal category of principal left ideals in a regular semigroup $S$ and $Sd\in v\mathbb{L}(S)$ . A normal cone with apex $Sd$ is a function $\gamma\colon v\mathbb{L}(S)\to\mathbb{L}(S)$ such that:

(1)

for each $Se\in v\mathbb{L}(S)$ , one has $\gamma(Se)\in\mathbb{L}(S)(Se,Sd)$ ;
(2)

$\iota(Sf,Sg)\gamma(Sg)=\gamma(Sf)$ whenever $Sf\subseteq Sg$ ;
(3)

$\gamma(Sm)$ is an isomorphism for some $Sm\in v\mathbb{L}(S)$ .

Now, for each $a\in S$ , we can define a function $\rho^{a}\colon v\mathbb{L}(S)\to\mathbb{L}(S)$ as follows:

(1)

\rho^{a}(Se):=\rho(e,ea,f)\text{ where }f\mathrel{\mathscr{L}}a.

It is easy to verify that the map $\rho^{a}$ is a well-defined normal cone with apex $Sf$ in the sense of Definition 2.1, see [9, Lemma III.15].

In the sequel, the normal cone $\rho^{a}$ is called the principal cone determined by the element $a$ . In particular, observe that, for an idempotent $e\in E(S)$ , we have a principal cone $\rho^{e}$ such that $\rho^{e}(Se)=\rho(e,e,e)=1_{Se}$ . This leads us to the most crucial proposition of this article.

Proposition 2.3.

In a Clifford semigroup $S$ , every normal cone in $\mathbb{L}(S)$ is a principal cone.

Proof.

Suppose $\gamma$ is a normal cone in $\mathbb{L}(S)$ with vertex $Se$ so that $\gamma(Se)=\rho(e,u,e)$ for some $u\in S$ . Then for any $Sf\in v\mathbb{L}(S)$ , we shall show that $\gamma(Sf)=\rho(f,fu,e)=\rho^{u}$ for some $u\in S$ . To this end, first observe that since idempotents commute in $S$ , we have $Sef=Sfe\subseteq Se$ . So, by (2) of Definition 2.1, we have $\gamma(Sef)=\rho(ef,ef,e)\gamma(Se)$ . Then,

$\displaystyle\gamma(Sef)$	$\displaystyle=\rho(ef,ef,e)\gamma(Se)$	$\displaystyle\text{ since }Sef\subseteq Se$
	$\displaystyle=\rho(ef,ef,e)\rho(e,u,e)$
	$\displaystyle=\rho(ef,efu,e)$
	$\displaystyle=\rho(ef,fu,e)$	$\displaystyle\text{ since }u\in eSe\text{ and }ef=fe.$

Now for any $Sf\in v\mathbb{L}(S)$ , let $\gamma(Sf)=\rho(f,v,e)$ for some $v\in fSe$ . Then since $Sef\subseteq Sf$ also, we have

$\displaystyle\gamma(Sef)$	$\displaystyle=\rho(ef,ef,f)\gamma(Sf)$
	$\displaystyle=\rho(ef,ef,f)\rho(f,v,e)$
	$\displaystyle=\rho(ef,efv,e)$
	$\displaystyle=\rho(ef,ev,e)$	$\displaystyle\text{since }fv=v$
	$\displaystyle=\rho(ef,ve,e)$	$\displaystyle\text{since idempotents are central in }S$
	$\displaystyle=\rho(ef,v,e)$	$\displaystyle\text{ since }v\in fSe.$

Now, from the discussion above, we see that $\rho(ef,fu,e)=\rho(ef,v,e)$ . Then, using Proposition 2.2, this implies that $v=fu$ . Hence for all $Sf\in v\mathbb{L}(S)$ , we have $\gamma(Sf)=\rho(f,fu,e)$ and so $\gamma=\rho^{u}$ . ∎

In general, for an arbitrary regular semigroup $S$ , two distinct principal cones $\rho^{a}$ and $\rho^{b}$ may be equal in $\mathbb{L}(S)$ even when $a\neq b$ . But when $S$ is Clifford, we proceed to show that it is not the case.

Proposition 2.4.

Let $S$ be a Clifford semigroup. Given two principal cones $\rho^{a}$ and $\rho^{b}$ , we have $\rho^{a}=\rho^{b}$ if and only if $a=b$ .

Proof.

Clearly when $a=b$ , then $\rho^{a}=\rho^{b}$ . Conversely suppose $\rho^{a}=\rho^{b}$ . Then their vertices coincide and so, we have $Sa=Sb$ , then since $S$ is Clifford and Green’s relations coincide, we have $a\mathscr{H}b$ . Now let $e$ be the idempotent in $H_{a}=H_{b}$ , the Green’s $\mathscr{H}$ class containing $a$ and $b$ . Then $\rho^{a}(Se)=\rho(e,ea,e)=\rho(e,a,e)$ . Similarly we get $\rho^{b}(Se)=\rho(e,b,e)$ . Since the cones are equal, the corresponding morphism components at each vertex coincide. Hence using Proposition 2.2, we have $a=b$ . ∎

Recall from [9, Section III.1] that the set of all normal cones in a normal category forms a regular semigroup, under a natural binary operation. So, in particular, given the normal category $\mathbb{L}(S)$ , the set $T\mathbb{L}(S)$ of all normal cones in the category $\mathbb{L}(S)$ is a regular semigroup. Now, we proceed to characterise this semigroup when $S$ is Clifford.

Theorem 2.5.

Let $S$ be a Clifford semigroup. Then the semigroup $T\mathbb{L}(S)$ of all normal cones in $\mathbb{L}(S)$ is isomorphic to the semigroup $S$ .

Proof.

Recall from [9, Section III.3.2] that the map $\bar{\rho}\colon a\mapsto\rho^{a}$ from a regular semigroup $S$ to the semigroup $T\mathbb{L}(S)$ is a homomorphism. Now, when $S$ is Clifford, by 2.3, we have seen that every normal cone in $T\mathbb{L}(S)$ is principal and hence the map $\bar{\rho}$ is surjective. Also, by Proposition 2.4, we see that the map $\bar{\rho}$ is surjective. Hence the map $\bar{\rho}$ is an isomorphism from the Clifford semigroup $S$ to the semigroup $T\mathbb{L}(S)$ . ∎

The above theorem characterises the semigroup of $T\mathbb{L}(S)$ of all normal cones in $\mathbb{L}(S)$ ; this naturally leads us to the complete description of the cross-connection structure of the semigroup $S$ as follows.

Recall from [9, Section III.4] that given a normal category, it has an associated dual category whose objects are certain set-valued functors and morphisms are natural transformations. Now we proceed to characterise the normal dual $N^{*}\mathbb{L}(S)$ of the normal category $\mathbb{L}(S)$ of principal left ideals of a Clifford semigroup $S$ .

Theorem 2.6.

Let $S$ be a Clifford semigroup. Then the normal dual $N^{*}\mathbb{L}(S)$ of the normal category $\mathbb{L}(S)$ of principal left ideals in $S$ is isomorphic to the normal category $\mathbb{R}(S)$ of principal right ideals in $S$ .

Proof.

It is known that [9, Theorem III.25] the normal dual $N^{*}\mathbb{L}(S)$ of the normal category $\mathbb{L}(S)$ is isomorphic to the normal category $\mathbb{R}(T\mathbb{L}(S))$ of principal right ideals of the regular semigroup $T\mathbb{L}(S)$ . When $S$ is a Clifford semigroup, by Theorem 2.5, we see that the semigroup $T\mathbb{L}(S)$ is isomorphic to $S$ and hence $N^{*}\mathbb{L}(S)$ is isomorphic to $\mathbb{R}(S)$ as normal categories. ∎

Dually, we can easily prove the following results:

Theorem 2.7.

Let $S$ be a Clifford semigroup. The semigroup $T\mathbb{R}(S)$ of all normal cones in the category $\mathbb{R}(S)$ of all principal right ideals in $S$ is anti-isomorphic to the semigroup $S$ . The normal dual $N^{*}\mathbb{R}(S)$ of the normal category $\mathbb{R}(S)$ is isomorphic to the normal category $\mathbb{L}(S)$ .

Recall from [9, Theorem IV.1] that the cross-connection of a regular semigroup $S$ is defined as a quadruplet $(\mathbb{L}(S),\mathbb{R}(S),\Gamma,\Delta)$ such that $\Gamma\colon\mathbb{R}(S)\to N^{*}\mathbb{L}(S)$ and $\Delta\colon\mathbb{L}(S)\to N^{*}\mathbb{R}(S)$ are functors satisfying certain properties. Now, using Theorems 2.6 and 2.7, we see that both the functors $\Gamma$ and $\Delta$ are in fact isomorphisms. And hence the cross-connection structure degenerates to isomorphisms of the associated normal categories in a Clifford semigroup $S$ .

3. Cross-connections of a semilattice

Clearly, a semilattice is a Clifford semigroup. So, we specialise our discussion to a semilattice using the results in the previous section. The following theorem follows from Theorem 2.5.

Theorem 3.1.

Let $S$ be a semilattice. Then the semigroup $T\mathbb{L}(S)$ of all normal cones in $\mathbb{L}(S)$ is isomorphic to the semilattice $S$ .

Theorems 2.6 and 2.7 when applied to a semilattice can be unified as follows:

Theorem 3.2.

Let $S$ be a semilattice. Then the normal dual $N^{*}\mathbb{L}(S)$ of the normal category $\mathbb{L}(S)$ of principal left ideals in $S$ is isomorphic to the normal category $\mathbb{R}(S)$ of principal right ideals in $S$ . The normal dual $N^{*}\mathbb{R}(S)$ of the normal category $\mathbb{R}(S)$ is isomorphic to the normal category $\mathbb{L}(S)$ .

Hence, we see that both the cross-connections functors $\Gamma$ and $\Delta$ are isomorphisms, when we have a semilattice also. So, the cross-connection structure degenerates to isomorphisms of the associated normal categories in a semilattice, too.

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