• Title of article

    El Naschie’s ε(∞) theory and effects of nanoparticle clustering on the heat transport in nanofluids

  • Author/Authors

    M. Agop، نويسنده , , Anca Harabagiu، نويسنده ,

  • Issue Information
    دوهفته نامه با شماره پیاپی سال 2008
  • Pages
    10
  • From page
    1269
  • To page
    1278
  • Abstract
    Effects of nanoparticle clustering on the heat transfer in nanofluids using the scale relativity theory in the topological dimension DT = 3 are analyzed. In the one-dimensional differentiable case, the clustering morphogenesis process is achieved by cnoidal oscillation modes of the speed field. In such conjecture, a non-autonomous regime implies a relation between the radius and growth speed of the cluster while, a quasi-autonomous regime requires El Naschie’s ε(∞) theory through the cluster–cluster coherence (El Naschie global coherence). Moreover, these two regimes are separated by the golden mean. In the one-dimensional non-differentiable case, the fractal kink spontaneously breaks the ‘vacuum symmetry’ of the fluid by tunneling and generates coherent structures. This mechanism is similar to the one of superconductivity. Thus, the fractal potential acts as an energy accumulator while, the fractal soliton, implies El Naschie’s ε(∞) theory (El Naschie local coherence). Since all the properties of the speed field are transferred to the thermal one, for a certain conditions of an external load (e.g. for a certain value of thermal gradient) the soliton and fractal one breaks down (blows up) and release energy. As result, the thermal conductibility in nanofluids unexpectedly increases. Here, El Naschie’s ε(∞) theory interferes through El Naschie global and local coherences.
  • Journal title
    Chaos, Solitons and Fractals
  • Serial Year
    2008
  • Journal title
    Chaos, Solitons and Fractals
  • Record number

    903412