819 research outputs found
On the pinning strategy of complex networks
In pinning control of complex networks, a tacit believing is that the system
dynamics will be better controlled by pinning the large-degree nodes than the
small-degree ones. Here, by changing the number of pinned nodes, we find that,
when a significant fraction of the network nodes are pinned, pinning the
small-degree nodes could generally have a higher performance than pinning the
large-degree nodes. We demonstrate this interesting phenomenon on a variety of
complex networks, and analyze the underlying mechanisms by the model of star
networks. By changing the network properties, we also find that, comparing to
densely connected homogeneous networks, the advantage of the small-degree
pinning strategy is more distinct in sparsely connected heterogenous networks
Relic Vector Field and CMB Large Scale Anomalies
We study the most general effects of relic vector fields on the inflationary
background and density perturbations. Such effects are observable if the number
of inflationary e-folds is close to the minimum requirement to solve the
horizon problem. We show that this can potentially explain two CMB large scale
anomalies: the quadrupole-octopole alignment and the quadrupole power
suppression. We discuss its effect on the parity anomaly. We also provide
analytical template for more detailed data comparison.Comment: 15 pages, v4, references added, some comments revised, JCAP versio
Non-Bunch-Davies Anisotropy
We introduce a generic mechanism that can extend the effects of relic
anisotropies at the beginning of inflation to relatively much shorter scales in
density perturbations. This is induced by non-Bunch-Davies states of the
quantum fluctuations, and can show up in the non-oscillatory components of the
density perturbations. This mechanism works for general forms of anisotropies,
and, to illustrate it, we use an example of relic vector field. The detailed
scale-dependence of these anisotropies can be used to probe the initial quantum
state of our universe.Comment: 10 page
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