Abstract
The models of k-core percolation and interdependent networks (IN) have been extensively studied in their respective fields. A recent study has revealed that they share several common critical exponents. However, several newly discovered exponents in IN have not been explored in k-core percolation, and the origin of the similarity still remains unclear. Thus, in this paper, by considering k-core percolation on random networks, we first verify that the two newly discovered exponents (fractal fluctuation dimension, d f ′ , and correlation length exponent, ν ′ ) observed in d-dimensional IN spatial networks also exist with the same values in k-core percolation. That is, the fractality of the k-core giant component fluctuations is manifested by a fractal fluctuation dimension, d ˜ f = 3 / 4 , within a correlation size Nʹ that scales as N ′ ∝ ( p − p c ) − ν ˜ , with ν ˜ = 2 . Here we define, ν ˜ ≡ d ⋅ ν ′ and d ˜ f ≡ d f ′ / d . This implies that both models, IN and k-core, feature the same scaling behaviors with the same critical exponents, further reinforcing the similarity between the two models. Furthermore, we suggest that these two models are similar since both have two types of interactions: short-range (SR) connectivity links and long-range (LR) influences. In IN the LR are the influences of dependency links while in k-core we find here that for k = 1 and k = 2 the influences are SR and in contrast for k ⩾ 3 the influence is LR. In addition, analytical arguments for a universal hyper-scaling relation for the fractal fluctuation dimension of the k-core giant component and for IN as well as for any mixed-order transition are established. Our analysis enhances the comprehension of k-core percolation and supports the generalization of the concept of fractal fluctuations in mixed-order phase transitions.
Original language | English |
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Article number | 013006 |
Journal | New Journal of Physics |
Volume | 26 |
Issue number | 1 |
DOIs | |
State | Published - 2024 |
Bibliographical note
Publisher Copyright:© 2024 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft.
Funding
We thank the Israel Science Foundation, the Binational Israel-China Science Foundation Grant No. 3132/19, NSF-BSF Grant No. 2019740, the EU H2020 project RISE (Project No. 821115), the EU Horizon Europe grant OMINO (Grant No. 101086321) and the EU H2020 DIT4TRAM for financial support. Li D acknowledges the support from National Natural Science Foundation of China (72225012, 72288101, 71822101, 71890973/71890970). She Z acknowledges the support from the National Key RD Program of China (No. 2022YFA1005103). Gross B acknowledges the support of the Mordecai and Monique Katz Graduate Fellowship Program. Gao S and Xue L acknowledge the support from the program of China Scholarship Council.
Funders | Funder number |
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Binational Israel-China Science Foundation | 3132/19 |
EU H2020 | 821115 |
EU H2020 DIT4TRAM | |
NSF-BSF | 2019740 |
HORIZON EUROPE European Innovation Council | 101086321 |
National Natural Science Foundation of China | 72288101, 72225012, 71890973/71890970, 71822101 |
Israel Science Foundation | |
China Scholarship Council | |
National Key Research and Development Program of China | 2022YFA1005103 |
Keywords
- critical exponents
- fractal fluctuations
- interdependent networks
- k-core percolation
- long-range influences
- mixed-order phase transitions
- short-range influences