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Efficiency of thermal radiation energy-conversion nanodevices Miguel Rubi I. Latella A. Perez L. Lapas.

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Presentation on theme: "Efficiency of thermal radiation energy-conversion nanodevices Miguel Rubi I. Latella A. Perez L. Lapas."— Presentation transcript:

1 Efficiency of thermal radiation energy-conversion nanodevices Miguel Rubi I. Latella A. Perez L. Lapas

2

3 Enhancement of the heat flux in the near-field Heat Transfer coefficient Hu et al., Appl. Phys. Lett. 92, 133106 (2008)

4 Thermal conductance Domingues et al., Phys. Rev. Lett. 94, 085901 (2005) Molecular dynamics Thermal conductance

5 Fluctuation-dissipation regime FDT Fluctuating electrodynamics Domingues et al., PRL, 94, 085901 (2005) Valid when thermalization is very fast

6 Beyond the dipolar approximation… A.Pérez, J.M.Rubi., L. Lapas, Phys. Rev. B 77, 155417 (2008) Dipolar approximation: d>8R Domingues et al.,PRL, 94, 085901 (2005)

7 Equilibrium photon gas Energy conservation # microstates Planck distribution Stefan-Boltzmann TdS=dE Planck’s theory is not valid when length scales are comparable to the wave length of thermal radiation

8 Nonequilibrium photon gas Statistics: Thermodynamics: D. Reguera, J.M. Rubi and J.M. Vilar, J. Phys. Chem. B (2005)

9 Entropy production Onsager coefficient

10 Non-equilibrium Stefan-Boltzmann law Shorter distances, no longer valid Near-field thermodynamics

11 ELECTROMAGNETIC WAVES CONFINED IN A VERY NARROW GAP Spectrum of electromagnetic energy for different detection distances above surface of silicon carbide normalized by its maximum value in far field at T= 300 K. (J.-J. Greffet and C. Henkel, 2007) 11 When the distance diminishes, thermal radiation becomes a highly directional beam of coherent radiation. The narrow gap acts as a resonant cavity Electromagnetic energy density above a plane interface separating glass (amorphous, optical phonons poorly defined) at T = 300 K from vacuum at T = 0 K

12 Photon Kinetics A. Perez, L. Lapas, J.M. Rubi, PRL, 103, 048301 (2009) Heat flux results from the contribution of Different modes

13 Input of the theory Elastic: Inelastic: Lognormal DOS -Statistical model which can describe collective motions. -Stems from the existence of a hierarchy of relaxations mechanisms in the material -The energy consists of a large number of contributions; central limit theorem Y. V. Denisov, A.P. Rylev, JEPT Lett. 52, 411 (1990)

14 14 Yu. V. Denisov and A.P. Rylev, JETP Lett. 52 (1990), 411.

15 Heat transfer coefficient 15 A. Perez, L. Lapas, J.M. Rubi, PRL, 103, 048301 (2009) FF NF

16 A. Perez-Madrid, L. Lapas, J.M. Rubi, Plos One, 8, e58770 (2013)

17 The system

18 Efficiency

19 Near-field

20

21

22 Black body

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25 Conclusions Near-field thermal radiation dramatically increases the amount of energy exchanged between bodies separated by a nanogap as compared to the black-body limit. We have evaluated the heat transfer coefficient and the thermal conductance in a wide range of length scales, giving a thermokinetic description of several experiments involving heat radiation through a very narrow gap. The theory presented may also be used in the study of other heat exchange processes such as those occurring in phonon systems and in the analysis of thermal contributions to Casimir forces. Near-field energy converters are more efficient than devices working in the black-body limit.

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