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

Slides:

Advertisements

Similar presentations

Heat, Thermodynamics, Heat Transfer and Weather

Advertisements

Mesoscopic nonequilibrium thermoydnamics Application to interfacial phenomena Dynamics of Complex Fluid-Fluid Interfaces Leiden, 2011 Miguel Rubi.

Temperature, Heat, and the First Law of Thermodynamics

The mesoscopic dynamics of thermodynamic systems J.M. Rubi.

Radiation Heat Transfer

AME Int. Heat Trans. D. B. GoSlide 1 Non-Continuum Energy Transfer: Overview.

Laboratoire EM2C. Near-field radiative heat transfer : application to energy conversion Jean-Jacques Greffet Ecole Centrale Paris, CNRS.

A. Nitzan, Tel Aviv University ELECTRON TRANSFER AND TRANSMISSION IN MOLECULES AND MOLECULAR JUNCTIONS AEC, Grenoble, Sept 2005 Lecture 2.

Phy100: Blackbody radiation

Thermo & Stat Mech - Spring 2006 Class 14 1 Thermodynamics and Statistical Mechanics Kinetic Theory of Gases.

Classical vs Quantum Mechanics Rutherford’s model of the atom: electrons orbiting around a dense, massive positive nucleus Expected to be able to use classical.

MECh300H Introduction to Finite Element Methods

Thermal Radiation Scanning Tunneling Microscopy Yannick De Wilde, Florian Formanek, Remi Carminati, Boris Gralak, Paul-Arthur Lemoine, Karl Joulain, Jean-Philippe.

Phy100: Heat transport Three basic forms of thermal heat transport

Collisional ionization in the beam body  Just behind the front, by continuity  →0 and the three body recombination  (T e,E) is negligible.

Near-field thermal radiation

Thermo & Stat Mech - Spring 2006 Class 21 1 Thermodynamics and Statistical Mechanics Blackbody Radiation.

Prof. Juejun (JJ) Hu MSEG 667 Nanophotonics: Materials and Devices 9: Absorption & Emission Processes Prof. Juejun (JJ) Hu

Chapter 11 Heat Transfer FUNDAMENTALS OF THERMAL-FLUID SCIENCES, 5th edition by Yunus A. Çengel and Michael A. Boles.

Thermal Properties of Crystal Lattices

Gabriel Cwilich Yeshiva University NeMeSyS Symposium 10/26/2008 Luis S. Froufe Perez Ecole Centrale, Paris Juan Jose Saenz Univ. Autonoma, Madrid Antonio.

Quantum physics. Quantum physics grew out failures of classical physics which found some quantum remedies in the Planck hypothesis and wave-particle duality.

Family Homecoming Special Event "Can Climate Engineering Serve as a Complementary Step to Aggressive Mitigation?" ¨Dr. Michael MacCracken, The Climate.

Physics 361 Principles of Modern Physics Lecture 3.

MECHANISMS OF HEAT TRANSFER

Heat Transfer Lecture 1.

Laws of Radiation Heat Transfer P M V Subbarao Associate Professor Mechanical Engineering Department IIT Delhi Macro Description of highly complex Wave.

Hyunggyu Park 박 형 규 Starting … Active …. Hyunggyu Park 박 형 규 Starting … Active …

Chapter 18 Bose-Einstein Gases Blackbody Radiation 1.The energy loss of a hot body is attributable to the emission of electromagnetic waves from.

Ch. 5 - Basic Definitions Specific intensity/mean intensity Flux

INTRODUCTION Characteristics of Thermal Radiation Thermal Radiation Spectrum Two Points of View Two Distinctive Modes of Radiation Physical Mechanism of.

Lecture 24. Blackbody Radiation (Ch. 7) Two types of bosons: (a)Composite particles which contain an even number of fermions. These number of these particles.

ENT 255 HEAT TRANSFER BASICS OF HEAT TRANSFER. THERMODYNAMICS & HEAT TRANSFER HEAT => a form of energy that can be transferred from one system to another.

Blackbody Radiation Wien’s displacement law : Stefan-Boltzmann law :

Thermoelectricity  Thermoelectricity / thermoelectric effect electric field and a temperature gradient along the z direction of a conductor Let  : electrochemical.

Yoon kichul Department of Mechanical Engineering Seoul National University Multi-scale Heat Conduction.

Photon Statistics Blackbody Radiation 1.The energy loss of a hot body is attributable to the emission of electromagnetic waves from the body. 2.The.

Radiation Fundamental Concepts EGR 4345 Heat Transfer.

What is temperature? Measure of the average random kinetic energy of the molecules of a substance Physical property that determines the direction of heat.

Chapter 16 MECHANISMS OF HEAT TRANSFER Copyright © 2012 The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Fundamentals of.

How to make a (better?) light bulb Nick Vamivakas Journal Club

Atomic transitions and electromagnetic waves

Chapter 12: Thermal Energy What’s hot and what’s not…

Near-Field Radiation by Quantum Mechanics Thomas Prevenslik QED Radiations Discovery Bay, Hong Kong ASME 4th Micro/Nanoscale Heat Transfer Conf. (MNHMT-13),

Radiation Heat Transfer

MECH4450 Introduction to Finite Element Methods

Radiation (Ch 12 YAC) Thermal energy is emitted by matter as a result of vibrational and rotational motion of molecules, atoms and electrons. The energy.

Thermal Multiscale Modeling of Nanoparticle based Materials Sebastian Volz 1, Jean-Jacques Greffet 1 Denis Rochais 2, Gilberto Domingues 2 and Karl Joulain.

Light is a Particle Physics 12.

MECHANISM OF HEAT TRANSFER.  HEAT TRANSFER  Occurs only between regions that are at different temperature and its direction is always from higher to.

HW/Tutorial # 1 WRF Chapters 14-15; WWWR Chapters ID Chapters 1-2 Tutorial #1 WRF#14.12, WWWR #15.26, WRF#14.1, WWWR#15.2, WWWR#15.3, WRF#15.1, WWWR.

Blackbody. Kirchhoff’s Radiation  Radiated electromagnetic energy is the source of radiated thermal energy. Depends on wavelengthDepends on wavelength.

Winter/ IntroductionM. Shapiro 1 Can calculate Q 12 [J] from the first law of thermo. קצב מעבר חום heat transfer rate can’t calculate from thermo.

Chapter 1. Essential Concepts

Heat transfer mechanism Dhivagar R Lecture 1 1. MECHANISMS OF HEAT TRANSFER Heat can be transferred in three different ways: conduction, convection, and.

STATISTICAL MECHANICS PD Dr. Christian Holm PART 5-6 Some special topics, Thermal Radiation, and Plank distribution.

The Mechanisms of Electromagnetic Emissions

Lecture 24. Blackbody Radiation (Ch. 7)

Raman Effect The Scattering of electromagnetic radiation by matter with a change of frequency.

Molecular Dynamics by X-Rays?

Free Electron Sources of CoherentRadiation: FREE ELECTRON LASERS

Light-Matter Interaction

and Statistical Physics

Thermodynamics and Statistical Mechanics

Physics 2 – Mar 6, 2018 Do Now – How much power is generated by a windmill if it’s blades are 1.30 m long, the density of air is 1.15 kg/m3 and the wind.

Drawing and Examples (2-3) Dictionary Definition

QM2 Concept Test 8.1 The total energy for distinguishable particles in a three dimensional harmonic oscillator potential

Classical Physics Describes objects and their interactions on a macroscopic scale Mechanics Electromagnetism Thermodynamics Seemingly very successful “There.

The Laws of Thermodynamics

Radiation Heat Transfer

Presentation transcript:

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

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

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

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

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

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

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

Entropy production Onsager coefficient

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

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

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

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

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

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

The system

Efficiency

Near-field

Black body

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.