Title: Emergence of biconnected clusters in explosive percolation

Abstract: By introducing a simple competition mechanism for the insertion of bonds in random graphs, the explosive percolation demonstrates a sharped phase transition with rich critical phenomena. In this paper, we study the high-order connectivity in the explosive percolation by the event-based ensemble, focusing on the biconnected cluster, in which any two sites are connected by at least two independent paths. Although the biconnected clusters are formed only by inserting intra-cluster bonds, we numerically confirm that the percolation threshold of the biconnected cluster is independent of a special competition mechanism for the intra-cluster bond, instead, it shares the same value with the percolation of simply connected clusters. Moreover, it is very interesting that the volume fractal dimension of the biconnected clusters $d_{f}'$ varies when different competition mechanisms are applied to intra-cluster bonds. The fit results suggest that $d_{f}'$ is much smaller than the volume fractal dimension of the connected cluster $d_{f}$, indicating a non-explosive transition of the biconnected cluster. The size distribution of biconnected clusters shows a double-scaling behavior -- the size distribution of large clusters is still governed by the standard Fisher exponent derived from the hyperscaling relation $\tau'=1+1/d_{f}'$, while a modified Fisher exponent $\tau_0\leq1$ is found for small clusters. The value of $\tau_0$, and the crossover of the two scalings depends on the competition mechanism of intra-cluster bonds. All these demonstrate that the high-order connectivity also shows some unusual features by simply suppressing the growth of clusters in the percolation model.