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In the explosion scenario, the deep potential wells at "knots" where three shells intersect are the natural sites for the formation of rich galaxy clusters. We use a simple toy model to study the spatial distribution of rich clusters in a generic type of explosion scenario. The model, parametrized by the distribution of shell radii and the filling factor, places spherical shells at random and identifies each "knot" as a cluster. Even though the distribution of shell centers is random, the resulting cluster correlation function is close to a power law extending to the diameter of the largest spheres (beyond which it vanishes), ξcc_ (r) = (r/r₀_) ^-γ^, with γ typically ~1. 5-2. Richer clusters form at the intersections of bigger shells and so have stronger correlations. The correlation length in our basic models, when scaled to the mean neighbor separation dᵇar^, exceeds the observed value by a factor ~3. Plausible modifications to account for the effects of shell interactions and mergers of nearby clusters reduce this discrepancy. Typical shell radii R ~ 20-40h^-1^ Mpc and filling factors f ~ 0. 3-0. 6 are required to produce the observed number density of clusters. Models with a power-law radius distribution, P (R) is proportional to Rbeta^ for R < Rₘax_, β ~ -4, also reproduce the richness distribution of clusters in the Abell catalog. Analytic estimates show that a physical model in which 20-40h^-1^ Mpc shells overlap at z ~ 5-10 can produce clusters of mass ~10¹5^ Mₛun_. We compute other measures of large-scale structure, which depend on higher order correlations. Supercluster multiplicity functions, void probabilities, number counts, topology statistics, and velocity correlations confirm the presence of strong superclustering and quantify the non-Gaussian nature of the model. Superclustering in the explosion scenario substantially exceeds that in more conventional models where clusters form by the gravitational collapse of Gaussian density fluctuations-this may be the only current theory that can produce the observed cluster-cluster correlations in an OMEGA = 1 universe. Our most successful model has a power-law radius distribution with β = -4. 5, Rₘax_ = 30h^-1^ Mpc, and modifications to account for shell interactions and cluster mergers. It appears consistent with the available observational data, except that its correlation length, r₀_ = 41h^-1^ Mpc, exceeds the observed value by ~50%~ (~2 σ). Primordial explosions amplified by several generations of galaxy formation, cosmological detonation waves with efficiencies ~ 10^-4^, and plasma sweeping by superconducting cosmic strings can generate shells of the required size.
Weinberg et al. (Sun,) studied this question.