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Energy of Graphs

Ghorbani, Ebrahim | 2010

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  1. Type of Document: Ph.D. Dissertation
  2. Language: Farsi
  3. Document No: 40238 (02)
  4. University: Sharif University of Technology
  5. Department: Mathematical Sciences
  6. Advisor(s): Akbari, Saeid
  7. Abstract:
  8. Let G be a graph with adjacency matrix A and Δ be a diagonal matrix whose diagonal entries are the degree sequence of G. Then the matrices L = Δ− A and Q = Δ+A are called Laplacian matrix and signless Laplacian matrix of G, respectively. The eigenvalues of A, L, and Q are arranged decreasingly and denoted by λ1 ≥ · · · ≥ λn, μ1 ≥ · · · ≥ μn ≥ 0, and q1 ≥ · · · ≥ qn ≥ 0, respectively. The energy of a graph G is defined as E(G) :=
    n
    i=1
    |λi|.
    Furthermore, the incidence energy, the signed incidence energy, and the H¨uckel energy of G are
    defined as
    IE(G) :=
    n
    i=1

    qi, LE(G) :=
    n
    i=1

    μi, HE(G) :=

    2
    r
    i=1 λi, n= 2r;
    2
    r
    i=1 λi + λr+1, n= 2r + 1;
    respectively. In this thesis we study these four kinds of graph energies. For chromatic number and list chromatic number of a graph, we obtain the upper bound E(G) ≥ 2max(n − χ(G), ch(G)) where χ(G) is the chromatic number of the complement of G and ch(G) is the list chromatic
    number of G. The effect of removing or adding an edge on increasing or decreasing of energy is investigated. We show that for a graph G of order n with m edges, where n is even, the following holds:
    HE(G) ≤
    ⎧⎨

    2m
    n−1 +

    2m(n−2)(n2−n−2m)
    n−1 , m≤ n3
    2(n+2) ;
    2
    n

    mn(n2 − 2m) < 4m
    n, m>n3
    2(n+2) .
    Equality is attained if and only if G is a strongly regular graph with parameters (n, k, λ, μ) = (4t2+4t+2, 2t2+3t+1, t2+2t, t2+2t+1). A similar bound also holds if n is odd. Using properties of elementary symmetric functions, we prove that for any 0 < α ≤ 1, qα
    1 +· · ·+qα
    n
    ≥ μα1
    +· · ·+μαn
    .
    If we let α =
    in this inequality, the inequality IE(G) ≥ LE(G) follows. Using a different method, we extend above inequality to the values α ∈ (0, 1] ∪ [2, 3]. Moreover it is shown that the reverse of the inequality holds for α ∈ (1, 2). Further we show that equality holds in all of the above inequalities (excpet for α = 1, 2, 3) if and only if G is bipartite. Finally some lower bounds for IE and LE are found.
  9. Keywords:
  10. Graph Eigenvalue ; Graph Energy ; Laplacian ; Huckle Energy ; Incidence Energy ; Signless Laplacian

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