English

The M\_{3}[D] construction and n-modularity

General Mathematics 2016-08-16 v1

Abstract

In 1968, E. T. Schmidt introduced the M\_3[D] construction, an extension of the five-element nondistributive lattice M\_3 by a bounded distributive lattice D, defined as the lattice of all triples (x,y,z)D3(x, y, z) \in D^3 satisfying x\mmy=x\mmz=y\mmzx \mm y = x \mm z = y \mm z. The lattice M\_3[D] is a modular congruence-preserving extension of D. In this paper, we investigate this construction for an arbitrary lattice L. For every n > 0, we exhibit an identity Un such that U1 is modularity and Un+1 is properly weaker than Un. Let Mn denote the variety defined by Un, the variety of n-modular lattices. If L is n-modular, then M\_3[L] is a lattice, in fact, a congruence-preserving extension of L; we also prove that, in this case, IdM_3[L]M_3[IdL]IdM\_3[L] \cong M\_3[Id L]. We provide an example of a lattice L such that M\_3[L] is not a lattice. This example also provides a negative solution to a problem of R. W. Quackenbush: Is the tensor product ABA\otimes B of two lattices A and B with zero always a lattice. We complement this result by generalizing the M\_3[L] construction to an M\_4[L] construction. This yields, in particular, a bounded modular lattice L such that M_4LM\_4 \otimes L is not a lattice, thus providing a negative solution to Quackenbush's problem in the variety M of modular lattices. Finally, we sharpen a result of R. P. Dilworth: Every finite distributive lattice can be represented as the congruence lattice of a finite 3-modular lattice. We do this by verifying that a construction of G. Gr\"{a}tzer, H. Lakser, and E. T. Schmidt yields a 3-modular lattice.

Keywords

Cite

@article{arxiv.math/0501430,
  title  = {The M\_{3}[D] construction and n-modularity},
  author = {George Grätzer and Friedrich Wehrung},
  journal= {arXiv preprint arXiv:math/0501430},
  year   = {2016}
}