Statistics of temperature and thermal energy dissipation rate in low-Prandtl number turbulent thermal convection

Xu, Ao; Shi, Le; Xi, Heng-Dong

doi:10.1063/1.5129818

Cited by 42 publications

(20 citation statements)

References 52 publications

(46 reference statements)

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“…/ρ, and T = ∑ 4 i=0 g i , respectively. More numerical details on the LB method and validation of the in-house code can be found in our previous work [37][38][39] .…”

Section: Numerical Methods a Numerical Model For Incompressible Therm...mentioning

confidence: 99%

Transport and deposition of dilute microparticles in turbulent thermal convection

Tao

Shi

et al. 2020

Physics of Fluids

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We analyze the transport and deposition behavior of dilute microparticles in turbulent Rayleigh-Bénard convection. Two-dimensional direct numerical simulations were carried out for the Rayleigh number (Ra) of 10 8 and the Prandtl number (Pr) of 0.71 (corresponding to the working fluids of air). The Lagrangian point particle model was used to describe the motion of microparticles in the turbulence. Our results show that the suspended particles are homogeneously distributed in the turbulence for the Stokes number (St) less than 10 −3 , and they tend to cluster into bands for 10 −3 St 10 −2. At even larger St, the microparticles will quickly sediment in the convection. We also calculate the mean-square displacement (MSD) of the particle's trajectories. At short time intervals, the MSD exhibits a ballistic regime, and it is isotropic in vertical and lateral directions; at longer time intervals, the MSD reflects a confined motion for the particles, and it is anisotropic in different directions. We further obtained a phase diagram of the particle deposition positions on the wall, and we identified three deposition states depending on the particle's density and diameter. An interesting finding is that the dispersed particles preferred to deposit on the vertical wall where the hot plumes arise, which is verified by tilting the cell and altering the rotation direction of the large-scale circulation. a a) This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in Xu et al., Phys. Fluids 32, 083301 (2020) and may be found at

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“…/ρ, and T = ∑ 4 i=0 g i , respectively. More numerical details on the LB method and validation of the in-house code can be found in our previous work [37][38][39] .…”

Section: Numerical Methods a Numerical Model For Incompressible Therm...mentioning

confidence: 99%

Transport and deposition of dilute microparticles in turbulent thermal convection

Tao

Shi

et al. 2020

Physics of Fluids

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“…The macroscopic temperature T is obtained from T = ∑ 4 i=0 g i . More numerical details on the LB method and validation of the in-house DNS code can be found in our previous work [36][37][38] .…”

Section: Numerical Methods a Direct Numerical Simulation Of Turbulent...mentioning

confidence: 99%

Correlation of internal flow structure with heat transfer efficiency in turbulent Rayleigh-Bénard convection

Xu,

Chen,

Wang

et al. 2020

Preprint

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“…In macroscopic perspective, the GL theory successfully reveals the mathematical form of Nu and Re as functions of Ra and Pr. However, understanding the microscopic physical mechanisms of heat transport and flow dynamics still needs the insights offered by a deep and detailed investigation of ε T and ε u 4,8,17 . Measuring ε u requires the simultaneous measurement of all 5 (for incompressible flow) components of strain-rate tensor, and ε T requires the simultaneous measurements all 3 components of ∇T .…”

Section: A Dissipation In Rbcmentioning

confidence: 99%

“…buoyancy force typically injects energy into the large flow structures, and this energy is then (on average) transferred to smaller scales by the energy cascade, and is finally dissipated at the smallest scales 4 . The rate of energy dissipation regulates both the global energy balances and the local fluctuations of flow quantities [5][6][7] , and studying its behavior provides insights into the fundamental properties of turbulent convective flows 8,9 .…”

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confidence: 99%

The effect of tilt on turbulent thermal convection for a heated soap bubble

He,

Xiong,

Bragg

et al. 2022

Preprint

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We use direct numerical simulation (DNS) to explore the effect of tilt on two-dimensional turbulent thermal convection on a half-soap bubble that is heated at its equator. In the DNS, the bubble is tilted by an angle δ ∈ [0 • , 90 • ], the Rayleigh number is varied between Ra ∈ [3 × 10 6 , 3 × 10 9 ], and the Prandlt number is fixed at Pr = 7. The DNS reveals two qualitatively different flow regimes: the dynamic plume regime (DPR) and the stable plume regime (SPR). In the DPR, small dynamic plumes constantly emerge from random locations on the equator and dissipate on the bubble. In the SPR, the flow is dominated by a single large and stable plume rising from the lower edge of the bubble. The scaling behaviour of the Nusselt number Nu and Reynolds number Re are different in these two regimes, with Nu ∝ Ra 0.3 for the DPR and Nu ∝ Ra 0.24 for the SPR. Concerning Re, the scaling in the DPR lies between Re ∝ Ra 0.48 and Re ∝ Ra 0.53 depending on Ra and δ , while in the SPR, the scaling lies between Re ∝ Ra 0.44 and Re ∝ Ra 0.45 depending on δ . The turbulent thermal and kinetic energy dissipation rates (ε T and ε u , respectively) are also very different in the DPR and SPR. The probability density functions (PDF) of the normalized log ε T and log ε u are close to a Gaussian PDF for small fluctuations, but deviate considerably from a Gaussian at large fluctuations in the DPR. In the SPR, the PDFs of normalized log ε T and log ε u deviate considerably from a Gaussian PDF even for small values. The globally averaged thermal energy dissipation rate due to the mean temperature field was shown to exhibit the scaling ε T B ∝ Ra −0.23 in the DPR, and ε T B ∝ Ra −0.28 in the SPR. The globally averaged kinetic energy dissipation rate due to the mean velocity field is shown to exhibit the scaling ε u B ∝ Ra −0.47 in the DPR (the exponent reduces from 0.47 to 0.43 as δ is increased up to 30 • ). In the SPR, the behavior changes considerably to ε u B ∝ Ra −0.27 . For the turbulent dissipation rates, the results indicate the scaling ε T B ∝ Ra −0.18 and ε u B ∝ Ra −0.29 in the DPR. However, the dependencies of ε T B and ε u B on Ra cannot be described by power-laws in the SPR. I. INTRODUCTIONTurbulent thermal convection is ubiquitous in nature and plays a significant role in large scale flows on the Earth, such as the cyclones in the atmosphere and the circulation of the deep oceans 1 . Convective flows are also vital for a great number of industrial applications, for example cooling systems on chip-boards 2 . The fluid motion in turbulent thermal convection is driven by buoyancy which arises due to temperature gradients imposed by boundary conditions 3 . In these flows, the a) Also at

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Statistics of temperature and thermal energy dissipation rate in low-Prandtl number turbulent thermal convection

Cited by 42 publications

References 52 publications

Transport and deposition of dilute microparticles in turbulent thermal convection

Transport and deposition of dilute microparticles in turbulent thermal convection

Correlation of internal flow structure with heat transfer efficiency in turbulent Rayleigh-Bénard convection

The effect of tilt on turbulent thermal convection for a heated soap bubble

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