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## Semilattices

Abbreviation: **Slat**

### Definition

A ** semilattice** is a structure $\mathbf{S}=\langle S,\cdot
\rangle $, where $\cdot $ is an infix binary operation, called the

**, such that**

*semilattice operation*$\cdot $ is associative: $(xy)z=x(yz)$

$\cdot $ is commutative: $xy=yx$

$\cdot $ is idempotent: $xx=x$

Remark: This definition shows that semilattices form a variety.

### Definition

A ** join-semilattice** is a structure $\mathbf{S}=\langle S,\vee
\rangle $, where $\vee $ is an infix binary operation, called the $\emph{join}$, such that

$\leq $ is a partial order, where $x\leq y\Longleftrightarrow x\vee y=y$

$x\vee y$ is the least upper bound of $\{x,y\}$.

### Definition

A ** meet-semilattice** is a structure $\mathbf{S}=\langle S,\wedge
\rangle $, where $\wedge $ is an infix binary operation, called the $\emph{meet}$, such that

$\leq $ is a partial order, where $x\leq y\Longleftrightarrow x\wedge y=x$

$x\wedge y$ is the greatest lower bound of $\{x,y\}$.

##### Morphisms

Let $\mathbf{S}$ and $\mathbf{T}$ be semilattices. A morphism from $\mathbf{S}$ to $\mathbf{T}$ is a function $h:Sarrow T$ that is a homomorphism:

$h(xy)=h(x)h(y)$

### Examples

Example 1: $\langle \mathcal{P}_\omega(X)-\{\emptyset\},\cup\rangle $, the set of finite nonempty subsets of a set $X$, with union, is the free join-semilattice with singleton subsets of $X$ as generators.

### Basic results

### Properties

Classtype | variety |
---|---|

Equational theory | decidable in polynomial time |

Quasiequational theory | decidable |

First-order theory | undecidable |

Locally finite | yes |

Residual size | 2 |

Congruence distributive | no |

Congruence modular | no |

Congruence meet-semidistributive | yes |

Congruence n-permutable | no |

Congruence regular | no |

Congruence uniform | no |

Congruence extension property | |

Definable principal congruences | |

Equationally def. pr. cong. | |

Amalgamation property | yes |

Strong amalgamation property | yes |

Epimorphisms are surjective | yes |

\end{table}

### Finite members

$\begin{array}{lr} f(1)= &1\\ f(2)= &1\\ f(3)= &2\\ f(4)= &5\\ f(5)= &15\\ f(6)= &53\\ f(7)= &222\\ f(8)= &1078\\ f(9)= &5994\\ f(10)= &37622\\ f(11)= &262776\\ f(12)= &2018305\\ f(13)= &16873364\\ f(14)= &152233518\\ f(15)= &1471613387\\ f(16)= &15150569446\\ f(17)= &165269824761\\ \end{array}$

These results follow from the paper below and the observation that semilattices with $n$ elements are in 1-1 correspondence to lattices with $n+1$ elements.

Jobst Heitzig,J\”urgen Reinhold,** Counting finite lattices**,
Algebra Universalis,

**48**2002,43–53MRreview

### Subclasses

### Superclasses

### References

Trace: » semilattices