Limit laws for component-pruned sparse random graphs and percolated tori

Abstract

We prove an MSO2 zero-one law for a very sparse Erdős-Rényi graph after pruning by component order. Let pn=cn/n, where cn0, and delete every component of order less than f(n), where f(n)∞. If \[ f(n)( f(n)+(1/cn))=o( n), \] then the resulting graph satisfies a zero-one law for MSO2, with quantification over sets of vertices and sets of edges. The proof combines uniform component counts, an MSO Feferman-Vaught decomposition for disjoint unions, and semilinearity of the order spectra of MSO-definable classes of finite trees. We also show that the term f(n) f(n) cannot simply be omitted: star components can occur at first-order-visible Poisson thresholds. We further establish first-order limit laws for bond percolation on the discrete torus TLd. In the two-sided subpolynomial regime, pruning below a sufficiently slow threshold yields a zero-one law. For the unpruned model in either one-sided polynomial regime, the reciprocal exponents α=1/k are precisely the critical scales. At such a scale, an extended limit of N pNk or N qNk equal to 0 or ∞ gives a zero-one law; a positive finite limit gives a convergence law but not a zero-one law; and the absence of an extended limit gives failure of convergence. Finally, MSO1 already detects the parity of the torus side length through bipartiteness, producing a natural obstruction to monadic convergence in a near-deterministic regime.

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