In mathematics, a band (also called idempotent semigroup) is a semigroup in which every element is idempotent (in other words equal to its own square). Bands were first studied and named by .
The lattice of varieties of bands was described independently in the early 1970s by Biryukov, Fennemore and Gerhard. Semilattices, left-zero bands, right-zero bands, rectangular bands, normal bands, left-regular bands, right-regular bands and regular bands are specific subclasses of bands that lie near the bottom of this lattice and which are of particular interest; they are briefly described below.
A class of bands forms a variety if it is closed under formation of subsemigroups, homomorphic images and direct product. Each variety of bands can be defined by a single defining identity.
Semilattices are exactly commutative bands; that is, they are the bands satisfying the equation
Bands induce a preorder that may be defined as
x\leqy
xy=x
A left-zero band is a band satisfying the equation
whence its Cayley table has constant rows.
Symmetrically, a right-zero band is one satisfying
so that the Cayley table has constant columns.
A rectangular band is a band that satisfies
In any semigroup the first identity is sufficient to characterize a Nowhere commutative semigroup.
Nowhere commutative semigroup implies the first identity.
(aa)a=a(aa)
Thus in any Nowhere commutative semigroup
x(xyx)=(xx)yx=xyx=xy(xx)=(xyx)x
So
x
xyx
xyx=x
In a any semigroup the first identity implies idempotence since
a=aaa
aa=aaaa=a(aa)a=a
nowhere commutative since a band
xy=yx\implies(xy)(yx)=(yx)(xy)
xy=yx\impliesx=xyx=x(yy)x=(xy)(yx)=(yx)(xy)=y(xx)y=yxy=y
In any semigroup the first identity also implies the second because .
The idempotents of a rectangular semigroup form a sub band that is a rectangular band but a rectangular semigroup may have elements that are not idempotent. In a band the second identity obviously implies the first but that requires idempotence. There exist semigroups that satisfy the second identity but are not bands and do not satisfy the first.
There is a complete classification of rectangular bands. Given arbitrary sets and one can define a magma operation on by setting
(i,j) ⋅ (k,\ell)=(i,\ell)
This operation is associative because for any three pairs,, we have
((ix,jx) ⋅ (iy,jy)) ⋅ (iz,jz)=(ix,jy) ⋅ (iz,jz)=(ix,jz)=(ix,jx) ⋅ (iz,jz)
(ix,jx) ⋅ ((iy,jy) ⋅ (iz,jz))=(ix,jx) ⋅ (iy,jz)=(ix,jz)=(ix,jx) ⋅ (iz,jz)
and
are together equivalent to the second characteristic identity above.The two together also imply associativity . Any magma that satisfies these two rectangular identities and idempotence is therefore a rectangular band. So any magma that satisfies both the characteristic identities (four separate magma identities) is a band and therefore a rectangular band.
The magma operation defined above is a rectangular band because for any pair we have so every element is idempotent and the first characteristic identity follows from the second together with idempotence.
But a magma that satisfies only the identities for the first characteristic and idempotence need not be associative so the second characteristic only follows from the first in a semigroup.
Any rectangular band is isomorphic to one of the above form (either
S
e\inS
s\mapsto(se,es)
S\congSe x eS
In categorical language, one can say that the category of nonempty rectangular bands is equivalent to
Set\ne x Set\ne
Set\ne
Rectangular bands are also the -algebras, where is the monad on Set with,,
ηX
X\toX x X
\muX((x11,x12),(x21,x22))=(x11,x22)
A normal band is a band satisfying
We can also say a normal band is a band satisfying
This is the same equation used to define medial magmas, so a normal band may also be called a medial band, and normal bands are examples of medial magmas.[1]
A left-regular band is a band satisfying
If we take a semigroup and define if, we obtain a partial ordering if and only if this semigroup is a left-regular band. Left-regular bands thus show up naturally in the study of posets.
A right-regular band is a band satisfying
Any right-regular band becomes a left-regular band using the opposite product. Indeed, every variety of bands has an 'opposite' version; this gives rise to the reflection symmetry in the figure below.
A regular band is a band satisfying
When partially ordered by inclusion, varieties of bands naturally form a lattice, in which the meet of two varieties is their intersection and the join of two varieties is the smallest variety that contains both of them. The complete structure of this lattice is known; in particular, it is countable, complete, and distributive.[2] The sublattice consisting of the 13 varieties of regular bands is shown in the figure. The varieties of left-zero bands, semilattices, and right-zero bands are the three atoms (non-trivial minimal elements) of this lattice.
Each variety of bands shown in the figure is defined by just one identity. This is not a coincidence: in fact, every variety of bands can be defined by a single identity.[2]