about
Explosive synchronization as a process of explosive percolation in dynamical phase space.Stacked triangular lattice: Percolation propertiesTwo Types of Discontinuous Percolation Transitions in Cluster Merging ProcessesDense percolation in large-scale mean-field random networks is provably "explosive".Enhancing robustness of coupled networks under targeted recoveriesSpreading of cooperative behaviour across interdependent groups.Center of mass in complex networks.Percolation framework to describe El Niño conditions.Connectivity disruption sparks explosive epidemic spreading.How to share underground reservoirs.Weakly explosive percolation in directed networks.Avoiding a spanning cluster in percolation models.Phase transitions in supercritical explosive percolation.Discontinuous percolation transitions in epidemic processes, surface depinning in random media, and Hamiltonian random graphs.Crossover behavior of conductivity in a discontinuous percolation model.Growth dominates choice in network percolation.Unstable supercritical discontinuous percolation transitions.Percolation model with continuously varying exponents.Percolation transition of cooperative mutational effects in colorectal tumorigenesis.Formation mechanism and size features of multiple giant clusters in generic percolation processes.Finite-size effects and dynamics of giant transition of a continuum quorum percolation model on random networks.Controlling percolation with limited resources.Explosive percolation on directed networks due to monotonic flow of activity.Degree mixing in multilayer networks impedes the evolution of cooperation.Percolation of spatially constrained Erdős-Rényi networks with degree correlations.Clustering determines the dynamics of complex contagions in multiplex networks.Crossover phenomena of percolation transition in evolution networks with hybrid attachment.Phase transitions in the q-voter model with noise on a duplex clique.Percolation with long-range correlated disorder.Scaling Laws in Spatial Network Formation.Critical Fragmentation Properties of Random Drilling: How Many Holes Need to Be Drilled to Collapse a Wooden Cube?Inverting the Achlioptas rule for explosive percolation.Solution of the explosive percolation quest: scaling functions and critical exponents.Degree-dependent network growth: from preferential attachment to explosive percolation.Critical exponents of the explosive percolation transition.Achlioptas processes are not always self-averaging.Nonlocal product rules for percolation.Bohman-Frieze-Wormald model on the lattice, yielding a discontinuous percolation transition.Explosive percolation is continuous.Explosive percolation with multiple giant components.
P2860
Q27309191-AF852A8B-9F34-4AD2-8FC1-90CEFFB13E1DQ27444875-14698676-CDE9-4F94-A994-35EB47504728Q33551354-3D66F7D0-38A3-4364-9B87-C0AA1C6572F9Q34525803-E3ED97CF-8895-4EE5-912E-C2EA51D1708DQ35081108-3FEF6CD3-F9E5-4EE5-99D8-49C08BECCE20Q37107784-E9687FEB-3CB2-4C08-8D09-018B16D3BB95Q37595357-6854F3BA-ADE4-4318-B8B6-7F797C7EF3DFQ38736779-6B7016B9-0259-417D-9253-24AEB160E722Q40675747-C8FD9966-D2DD-4301-BC5E-3B1A1686D5DFQ42079347-7F3ACF3D-D036-4B1D-BFE9-944BB3538A43Q42258987-4C71740A-C7DB-40D5-857A-9C5C3E962B70Q42271987-B17C7CDF-9576-48AE-BDC7-62AD02BF58CFQ43464642-111EDCD6-2212-409C-84A3-DCA0A7BFCE16Q45152627-8B3AE223-F2EF-4910-B0E4-5AC53D7529BFQ45361381-AA7218E1-D5A8-40DA-9727-8947EDAD6C77Q45375422-4C48E186-10D7-4A86-8079-4B350CE41C49Q46099671-F9712F1A-10F5-4C9D-BC69-66253C95D508Q46642582-DDD62072-EF95-4B3B-8F14-F3F70FFBC9B3Q47162501-7535617C-29FD-4CE2-9317-2343ED2E84F6Q47268335-0EFD7774-03EF-4B69-98B8-6C37F8A6EA71Q47311086-87A2B703-AA9F-4516-B409-684627281EDFQ47547195-793FAA93-6891-4661-82D5-FDCD62EB0C6CQ47557557-D70B896E-EC97-49E8-929A-531623E2493FQ47715048-C078FAC1-12F9-42CC-B166-C34BD4C06E20Q47794666-F82E6120-B2D9-4D18-A28B-560E0F9E76CDQ47969527-7C6C96F6-F567-49C5-9C90-3E789FC1468BQ49072275-200D1641-C263-4A08-BC0A-AA5E71C84393Q50262058-64CC162E-22C3-4967-98AD-0B41D1B96ADAQ50482425-8EF6B6C8-15B5-4A17-8D23-15593CD2FDEEQ50557979-D06CF0A1-9A1B-47EC-880F-E16599A602DAQ50709038-40F1ED99-646F-4575-B5A4-4C8689C0DA80Q50914648-6348C3B0-737F-4EE5-B569-8C3008724898Q51039029-F6CA9BE6-4D07-4B7E-9168-6D0BB8748F49Q51087125-411DBFE8-B472-49B8-B1B4-184A813F95A4Q51087517-7C9B1BD9-DD2C-40B7-86A2-C5C22EE42E56Q51319231-A247D88F-97F5-410F-AFBC-69742C40FB83Q51357427-2FE10C9B-67B4-4E17-B447-69135A41C38EQ51368320-ECB1819B-1CD0-4198-AB45-166AD0DAF99BQ51547663-64133077-8F7C-4B8A-9D50-715F3CBBFB20Q51581610-541D3891-163B-439D-894A-C42F5D350D7D
P2860
description
article
@en
im Januar 2011 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в січні 2011
@uk
ലേഖനം
@ml
name
Impact of single links in competitive percolation
@en
Impact of single links in competitive percolation
@nl
type
label
Impact of single links in competitive percolation
@en
Impact of single links in competitive percolation
@nl
prefLabel
Impact of single links in competitive percolation
@en
Impact of single links in competitive percolation
@nl
P2093
P2860
P356
P1433
P1476
Impact of single links in competitive percolation
@en
P2093
Anna Levina
Jan Nagler
Marc Timme
P2860
P2888
P304
P356
10.1038/NPHYS1860
P577
2011-01-16T00:00:00Z