Congruence lattice problem: Difference between revisions

 

==Preliminaries==

 

'''Lemma.'''

 

 

'''Theorem (Birkhoff and Frink 1948).'''

This says that α ∧ (β ∨ γ) = (α ∧ β) ∨ (α ∧ γ), for any congruences α, β, and γ of a given lattice. The analogue of this result fails, for instance, for modules, as <math>A\cap(B+C)\neq(A\cap B)+(A\cap C)</math>, as a rule, for [[Module (mathematics)|submodules]] ''A'', ''B'', ''C'' of a given [[Module (mathematics)|module]].

 

 

'''Theorem (Dilworth ≈1940, Grätzer and Schmidt 1962).'''

Every finite distributive lattice is isomorphic to the congruence lattice of some finite lattice.

 

 

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The problem CLP has been one of the most intriguing and longest-standing open problems of lattice theory. Some related results of universal algebra are the following.

 

Every algebraic lattice is isomorphic to the congruence lattice of some algebra.

 

The lattice Sub ''V'' of all subspaces of a [[vector space]] ''V'' is certainly an algebraic lattice. As the next result shows, these algebraic lattices are difficult to represent.

 

Let ''V'' be an infinite-dimensional vector space over an [[uncountable]] [[Field (mathematics)|field]] ''F''. Then Con ''A'' isomorphic to Sub ''V'' implies that ''A'' has at least card ''F'' operations, for any algebra ''A''.

 

 

==Semilattice formulation of CLP==

 

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'''Theorem.'''

 

==Schmidt's approach via distributive join-homomorphisms==

We say that a (∨,0)-semilattice satisfies ''Schmidt's Condition'', if it is isomorphic to the quotient of a [[generalized Boolean semilattice]] ''B'' under some [[Distributive homomorphism|distributive join-congruence]] of ''B''. One of the deepest results about representability of (∨,0)-semilattices is the following.

 

Any (∨,0)-semilattice satisfying Schmidt's Condition is representable.

 

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Partial positive answers are the following.

 

Every distributive ''lattice'' with zero satisfies Schmidt's Condition; thus it is representable.

 

This result has been improved further as follows, ''via'' a very long and technical proof, using forcing and Boolean-valued models.

 

Every [[direct limit]] of a countable sequence of distributive ''lattices'' with zero and (∨,0)-homomorphisms is representable.

 

 

'''Theorem (Huhn 1985).''' Every distributive (∨,0)-semilattice of cardinality at most ℵ₁ satisfies Schmidt's Condition. Thus it is representable.

 

 

'''Theorem (Dobbertin 1986).'''

 

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==Pudlák's approach; lifting diagrams of (∨,0)-semilattices==

 

'''Theorem (Ershov 1977, Pudlák 1985).'''

Every distributive (∨,0)-semilattice is the directed union of its finite distributive (∨,0)-subsemilattices.

 

This means that every finite subset in a distributive (∨,0)-semilattice ''S'' is contained in some finite ''distributive'' (∨,0)-subsemilattice of ''S''. Now we are trying to represent a given distributive (∨,0)-semilattice ''S'' as Con_c ''L'', for some lattice ''L''. Writing ''S'' as a directed union <math>S=\bigcup(S_i\mid i\in I)</math> of finite distributive (∨,0)-subsemilattices, we are ''hoping'' to represent each ''S_i'' as the congruence lattice of a lattice ''L_i'' with lattice homomorphisms ''f_i^j : L_i→ L_j'', for ''i ≤ j'' in ''I'', such that the diagram <math>\mathcal{S}</math> of all ''S_i'' with all inclusion maps ''S_i→S_j'', for ''i ≤ j'' in ''I'', is [[Equivalence of categories|naturally equivalent]] to <math>(\mathrm{Con_c}\,L_i,\mathrm{Con_c}\,f_i^j\mid i\leq j\text{ in }I)</math>, we say that the diagram <math>(L_i,f_i^j\mid i\leq j\text{ in }I)</math> lifts <math>\mathcal{S}</math> (with respect to the Con_c functor). If this can be done, then, as we have seen that the Con_c functor preserves direct limits, the direct limit <math>L=\varinjlim_{i\in I}L_i</math> satisfies <math>{\rm Con_c}\,L\cong S</math>.

While the problem whether this could be done in general remained open for about 20 years, Pudlák could prove it for distributive ''lattices'' with zero, thus extending one of Schmidt's results by providing a ''functorial'' solution.

 

There exists a direct limits preserving functor Φ, from the category of all distributive lattices with zero and 0-lattice embeddings to the category of all lattices with zero and 0-lattice embeddings, such that Con_cΦ is [[Equivalence of categories|naturally equivalent]] to the identity. Furthermore, Φ(''S'') is a finite [[Lattice (order)|atomistic lattice]], for any finite distributive (∨,0)-semilattice ''S''.

 

 

 

'''Theorem (Tůma and Wehrung 2006).'''

There exists a [[Diagram (category theory)|diagram]] ''D'' of finite Boolean (∨,0)-semilattices and (∨,0,1)-embeddings, indexed by a finite partially ordered set, that cannot be lifted, with respect to the Con_c functor, by any diagram of lattices and lattice homomorphisms.

 

In particular, this implies immediately that CLP has no ''functorial'' solution.

 

 

'''Theorem (Bulman-Fleming and McDowell 1978).'''

Every distributive (∨,0)-semilattice is a direct limit of finite [[Boolean algebra (structure)|Boolean]] (∨,0)-semilattices and (∨,0)-homomorphisms.

 

It should be observed that while the transition homomorphisms used in the Ershov-Pudlák Theorem are (∨,0)-embeddings, the transition homomorphisms used in the result above are not necessarily one-to-one, for example when one tries to represent the three-element chain. Practically this does not cause much trouble, and makes it possible to prove the following results.

Every distributive (∨,0)-semilattice of cardinality at most ℵ₁ is isomorphic to

 

 

 

 

 

 

==Congruence lattices of lattices and nonstable K-theory of von Neumann regular rings==

 

The following result was observed by Wehrung, building on earlier works mainly by Jónsson and Goodearl.

 

Let ''R'' be a von Neumann regular ring. Then the (∨,0)-semilattices Id_c ''R'' and Con_c ''L(R)'' are both isomorphic to the [[maximal semilattice quotient]] of ''V(R)''.

 

 

There exists a distributive (∨,0,1)-semilattice of cardinality ℵ₁ that is not isomorphic to Con_c ''L'', for any modular lattice ''L'' every finitely generated sublattice of which has finite length.

 

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The abovementioned Problem 1 (Schmidt), Problem 2 (Dobbertin), and Problem 3 (Goodearl) were solved simultaneously in the negative in 1998.

 

'''Theorem (Wehrung 1998).'''

There exists a [[Refinement monoid|dimension vector space]] ''G'' over the rationals with [[Monoid|order-unit]] whose positive cone ''G''⁺ is not isomorphic to ''V(R)'', for any von Neumann regular ring ''R'', and is not [[Refinement monoid|measurable]] in Dobbertin's sense. Furthermore, the [[maximal semilattice quotient]] of ''G''⁺ does not satisfy Schmidt's Condition. Furthermore, ''G'' can be taken of any given cardinality greater than or equal to ℵ₂.

 

It follows from the previously mentioned works of Schmidt, Huhn, Dobbertin, Goodearl, and Handelman that the ℵ₂ bound is optimal in all three negative results above.

 

 

 

 

This counterexample has been modified subsequently by Ploščica and Tůma to a direct semilattice construction. For a (∨,0)-semilattice, the larger semilattice ''R(S)'' is the (∨,0)-semilattice freely generated by new elements ''t(a,b,c)'', for ''a, b, c'' in ''S'' such that ''c ≤ a ∨ b'', subjected to the only relations ''c=t(a,b,c) ∨ t(b,a,c)'' and ''t(a,b,c) ≤ a''. Iterating this construction gives the ''free distributive extension'' <math>D(S)=\bigcup(R^n(S)\mid n<\omega)</math> of ''S''. Now, for a set Ω, let ''L(Ω)'' be the (∨,0)-semilattice defined by generators 1 and ''a_i,x'', for ''i<2'' and ''x'' in Ω, and relations ''a_0,x ∨ a_1,x=1'', for any ''x'' in Ω. Finally, put ''G(Ω)=D(L(Ω))''.

In most related works, the following ''uniform refinement property'' is used. It is a modification of the one introduced by Wehrung in 1998 and 1999.

 

Let ''e'' be an element in a (∨,0)-semilattice ''S''. We say that the ''weak uniform refinement property'' WURP holds at ''e'', if for all families <math>(a_i)_{i\in I}</math> and <math>(b_i)_{i\in I}</math> of elements in ''S'' such that ''a_i ∨ b_i=e'' for all ''i'' in ''I'', there exists a family <math>(c_{i,j}\mid (i,j)\in I\times I)</math> of elements of ''S'' such that the relations

 

hold for all ''i, j, k'' in ''I''. We say that ''S'' satisfies WURP, if WURP holds at every element of ''S''.

 

 

 

The semilattice Con_c F_'''V'''(Ω) does not satisfy WURP, for any set Ω of cardinality at least ℵ₂ and any non-distributive variety '''V''' of lattices. Consequently, Con_c F_'''V'''(Ω) does not satisfy Schmidt's Condition.

 

 

==Solving CLP: the Erosion Lemma==

Hence, the counterexample to CLP had been known for nearly ten years, it is just that nobody knew why it worked! All the results prior to the theorem above made use of some form of permutability of congruences. The difficulty was to find enough structure in congruence lattices of non-congruence-permutable lattices.

 

 

We let ''L'' be an [[Universal algebra|algebra]] possessing a structure of semilattice (''L'',∨) such that every congruence of ''L'' is also a congruence for the operation ∨ . We put

and we denote by Con_c^''U'' ''L'' the (∨,0)-subsemilattice of Con_c ''L'' generated by all principal congruences Θ(''u'',''v'') ( = least congruence of ''L'' that identifies ''u'' and ''v''), where (''u'',''v'') belongs to ''U'' ×''U''. We put Θ⁺(''u'',''v'')=Θ(''u ∨ v'',''v''), for all ''u, v'' in ''L''.br />

 

Let ''x''₀, ''x''₁ in ''L'' and let <math>Z=\{z_0,z_1,\dots,z_n\}</math>, for a positive integer ''n'', be a finite subset of ''L'' with <math>\bigvee_{i<n}z_i\leq z_n</math>. Put

:<math>\alpha_j=\bigvee(\Theta_L(z_i,z_{i+1})\mid i<n,\ \varepsilon(i)=j),\text{ for all }j<2.</math>

</math>

 

 

The proof of the theorem above runs by setting a ''structure'' theorem for congruence lattices of semilattices—namely, the Erosion Lemma, against ''non-structure'' theorems for free distributive extensions ''G(Ω)'', the main one being called the ''Evaporation Lemma''. While the latter are technically difficult, they are, in some sense, predictable. Quite to the contrary, the proof of the Erosion Lemma is elementary and easy, so it is probably the strangeness of its statement that explains that it has been hidden for so long.

More is, in fact, proved in the theorem above: ''For any algebra L with a congruence-compatible structure of join-semilattice with unit and for any set Ω with at least ℵ_ω+1 elements, there is no weakly distributive homomorphism μ: Con_c L → G(Ω) containing 1 in its range''. In particular, CLP was, after all, not a problem of lattice theory, but rather of [[universal algebra]]—even more specifically, [[Semilattice|''semilattice theory'']]! These results can also be translated in terms of a ''uniform refinement property'', denoted by CLR in Wehrung's paper presenting the solution of CLP, which is noticeably more complicated than WURP.

 

 

'''Theorem (Růžička 2008).'''

The semilattice ''G(Ω)'' is not isomorphic to Con_c ''L'' for any lattice ''L'', whenever the set Ω has at least ℵ₂ elements.

 

Růžička's proof follows the main lines of Wehrung's proof, except that it introduces an enhancement of [[Kuratowski's Free Set Theorem]], called there ''existence of free trees'', which it uses in the final argument involving the Erosion Lemma.

 

==A positive representation result for distributive semilattices==

 

'''Theorem (Wehrung 2008).''' For any distributive (∨,0)-semilattice ''S'', there are a (∧,0)-semilattice ''P'' and a map μ : ''P'' × ''P'' → ''S'' such that the following conditions hold:

 

It is not hard to verify that conditions (1)–(4) above imply the distributivity of ''S'', so the result above gives a ''characterization'' of distributivity for (∨,0)-semilattices.

 

==References==