The multiplicative coalescent, inhomogeneous continuum random trees, and new universality classes for critical random graphs

Abstract: One major open conjecture in the area of critical random graphs, formulated by statistical physicists, and supported by a large amount of numerical evidence over the last decade (Braunstein et al. in Phys Rev Lett 91(16) (3,4), distances between typical points both within maximal components in the critical regime as well as on the minimal spanning tree on the giant component in the supercritical regime scale like n (τ −3)/(τ −1) . In this paper we study the metric space structure of maximal components of the … Show more

“…Then the maximal components in the critical scaling window still belong to the Erdős‐Rényi universality class as in () above with distances scaling like n −1/3 . This contrasts drastically with critical percolation on these random graphs where maximal components with distances scaled by converge to limiting random fractals .…”

“…Personal communication from Remco van der Hofstad suggests that the limits here differ substantially from critical percolation. Scaling limits for critical percolation in such heavy tailed random graphs were derived in , where scaling limits of maximal components in Aldous's multiplicative coalescent were established in terms of tilted inhomogeneous continuum random trees. One ramification of these results ([, Thm.…”

“…Scaling limits for critical percolation in such heavy tailed random graphs were derived in , where scaling limits of maximal components in Aldous's multiplicative coalescent were established in terms of tilted inhomogeneous continuum random trees. One ramification of these results ([, Thm. 1.2]) is the continuum scaling limits of the maximal components in the critical regime of the so‐called Norros‐Reittu model where the driving weight sequence is assumed to have heavy tails with exponent τ ∈ (3,4).…”

“…The first space T IJ was formulated in where it was used to study trees spanning a finite number of random points sampled from an inhomogeneous continuum random tree (ICRT). A more general space was used in the proofs in . The index I in T IJ and is needed for the purpose of keeping track of the number of marked “hubs,” that is, vertices of high (or infinite) degrees in such trees (see for a proper definition).…”

“…Proof The result is essentially contained in [, Lem. 4.9], and we only outline how to extract the result from its proof.…”

Geometry of the vacant set left by random walk on random graphs, Wright's constants, and critical random graphs with prescribed degrees

“…Then the maximal components in the critical scaling window still belong to the Erdős‐Rényi universality class as in () above with distances scaling like n −1/3 . This contrasts drastically with critical percolation on these random graphs where maximal components with distances scaled by converge to limiting random fractals .…”

“…Personal communication from Remco van der Hofstad suggests that the limits here differ substantially from critical percolation. Scaling limits for critical percolation in such heavy tailed random graphs were derived in , where scaling limits of maximal components in Aldous's multiplicative coalescent were established in terms of tilted inhomogeneous continuum random trees. One ramification of these results ([, Thm.…”

“…Scaling limits for critical percolation in such heavy tailed random graphs were derived in , where scaling limits of maximal components in Aldous's multiplicative coalescent were established in terms of tilted inhomogeneous continuum random trees. One ramification of these results ([, Thm. 1.2]) is the continuum scaling limits of the maximal components in the critical regime of the so‐called Norros‐Reittu model where the driving weight sequence is assumed to have heavy tails with exponent τ ∈ (3,4).…”

“…The first space T IJ was formulated in where it was used to study trees spanning a finite number of random points sampled from an inhomogeneous continuum random tree (ICRT). A more general space was used in the proofs in . The index I in T IJ and is needed for the purpose of keeping track of the number of marked “hubs,” that is, vertices of high (or infinite) degrees in such trees (see for a proper definition).…”

“…Proof The result is essentially contained in [, Lem. 4.9], and we only outline how to extract the result from its proof.…”

Geometry of the vacant set left by random walk on random graphs, Wright's constants, and critical random graphs with prescribed degrees

A probabilistic approach to the leader problem in random graphs

On breadth‐first constructions of scaling limits of random graphs and random unicellular maps