493 research outputs found
Subgraphs with Restricted Degrees of their Vertices in Large Polyhedral Maps on Compact Two-manifolds
AbstractLet k≥ 2, be an integer and M be a closed two-manifold with Euler characteristic χ(M) ≤ 0. We prove that each polyhedral map G onM , which has at least (8 k2+ 6 k− 6)|χ (M)| vertices, contains a connected subgraph H of order k such that every vertex of this subgraph has, in G, the degree at most 4 k+ 4. Moreover, we show that the bound 4k+ 4 is best possible. Fabrici and Jendrol’ proved that for the sphere this bound is 10 ifk= 2 and 4 k+ 3 if k≥ 3. We also show that the same holds for the projective plane
On the Roman Bondage Number of Graphs on surfaces
A Roman dominating function on a graph is a labeling such that every vertex with label has a neighbor
with label . The Roman domination number, , of is the
minimum of over such functions. The Roman bondage
number is the cardinality of a smallest set of edges whose removal
from results in a graph with Roman domination number not equal to
. In this paper we obtain upper bounds on in terms of
(a) the average degree and maximum degree, and (b) Euler characteristic, girth
and maximum degree. We also show that the Roman bondage number of every graph
which admits a -cell embedding on a surface with non negative Euler
characteristic does not exceed .Comment: 5 page
Gibbs and Quantum Discrete Spaces
Gibbs measure is one of the central objects of the modern probability,
mathematical statistical physics and euclidean quantum field theory. Here we
define and study its natural generalization for the case when the space, where
the random field is defined is itself random. Moreover, this randomness is not
given apriori and independently of the configuration, but rather they depend on
each other, and both are given by Gibbs procedure; We call the resulting object
a Gibbs family because it parametrizes Gibbs fields on different graphs in the
support of the distribution. We study also quantum (KMS) analog of Gibbs
families. Various applications to discrete quantum gravity are given.Comment: 37 pages, 2 figure
Renormalization: an advanced overview
We present several approaches to renormalization in QFT: the multi-scale
analysis in perturbative renormalization, the functional methods \`a la
Wetterich equation, and the loop-vertex expansion in non-perturbative
renormalization. While each of these is quite well-established, they go beyond
standard QFT textbook material, and may be little-known to specialists of each
other approach. This review is aimed at bridging this gap.Comment: Review, 130 pages, 33 figures; v2: misprints corrected, refs. added,
minor improvements; v3: some changes to sect. 5, refs. adde
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