Turbulent thermal convection over fractal-like multi-scale roughness

ORAL

Abstract

In turbulent Rayleigh-Bénard convection, roughness is often used as a means to enhance heat transport. Yet the community is still debating on whether the Nusselt vs Rayleigh number scaling exponent (Nu∼Raβ) increases or remains unchanged. In our previous study we have shown that for periodic roughness of the same size, the scaling exponent β can reach up to 1/2 for one decade in Ra, and then saturates back to a value close to the smooth wall case. In contrast, we now investigate Rayleigh-Bénard convection with surface roughness of three length scales. We find that the range of Ra in which the 1/2 exponent manifests can be extended substantially. The reason is that with multi-scale roughness, the state where a thin thermal boundary layer is uniformly distributed along the rough surfaces is very much delayed and can only be achieved at very high Ra.

*ERC advanced grant and MCEC

Presenters

  • Xiaojue Zhu

    • University of Twente , Harvard University
    • Univ of Twente
    • University of Twente

Authors

  • Xiaojue Zhu

    • University of Twente , Harvard University
    • Univ of Twente
    • University of Twente

  • Richard Stevens

    • University of Twente
    • Univ of Twente

  • Roberto Verzicco

    • Univ of Roma
    • University of Rome
    • Università di Roma Tor Vergata, PoF University of Twente
    • Univ of Roma Tor Vergata, Univ. of Twente
    • University of Roma
    • Univ of Roma "Tor Vergata"
    • University of Roma, University of Twente
    • Univ of Twente, Univ of Rome 'Tor Vergata'

  • Detlef Lohse

    • University of Twente
    • Physics of Fluids and Max Planck Center for Complex Fluids Dynamics, University of Twente, Enschede, The Netherlands
    • Univ of Twente
    • Univ of Twente, Max Plank Institute for Dynamics and Self-Organization
    • Twente Tech Univ
    • University of Twente, Max Planck Center for complex fluid dynamics