Presentation is loading. Please wait.

Presentation is loading. Please wait.

Anes BOUCHENAK-KHELLADI Advisors : - Jérôme Saint-Martin - Philippe DOLLFUS Institut d’Electronique Fondamentale Phonon thermal transport in Nano-transistors.

Published byLambert Ray Modified over 8 years ago

Similar presentations

Presentation on theme: "Anes BOUCHENAK-KHELLADI Advisors : - Jérôme Saint-Martin - Philippe DOLLFUS Institut d’Electronique Fondamentale Phonon thermal transport in Nano-transistors."— Presentation transcript:

1 Anes BOUCHENAK-KHELLADI Advisors : - Jérôme Saint-Martin - Philippe DOLLFUS Institut d’Electronique Fondamentale Phonon thermal transport in Nano-transistors

2 Contents 2PHONON THERMAL TRANSPORT 10/12/2015 A - General Introduction (page 3 to 8) B - Simulation Results (page 10 to 23) 1. Fourier equation 2. Boltzmann Transport equation

3 A. General introduction In a uniform solid material 10/12/2015 3PHONON THERMAL TRANSPORT What’s a phonon ? Thermal agitation Atoms in a regular lattice : Wave propagating inside the crystal A quantum of energy of this vibration is a Phonon and vibrate

4 A. General introduction 10/12/2015 4PHONON THERMAL TRANSPORT But Why are we interested in “ Phonons ” ?

5 A. General introduction 10/12/2015 5PHONON THERMAL TRANSPORT In metals But !!! In Semiconductors and insulators heat Mr. electron Lattice vibration “Mr. Phonon”

6 A. General introduction 10/12/2015 6PHONON THERMAL TRANSPORT  Some phonon characteristics : - Behave as particles (quasi-particles) and as waves. - Described by a periodic dispersion : - Particles described by a wave-packet - The group velocity of wave-packet is determined by : - Obey to Bose-Einstein statics just like photons : Pulsation Energy

7 A. General introduction 10/12/2015 7PHONON THERMAL TRANSPORT Bose-Einstein staticsFermi-Dirac statics Phonons Electrons Each energy state can be occupied by any number of phonons Would you like to come with me ? Why not ! I will vibrate !

8 A. General introduction 10/12/2015 8PHONON THERMAL TRANSPORT  The dispersion approximation: -We have then : 1 LA 2 TA 1 LO 2 TO ! Why this order ? ! The slope ?

9 Contents 9PHONON THERMAL TRANSPORT 10/12/2015 A - General Introduction B - Simulation Results 1. Fourier equation 2. Boltzmann Transport equation

10 B. Simulation Results 10/12/2015 10PHONON THERMAL TRANSPORT But what’s the “ Purpose ” ?

11 B. Simulation Results 10/12/2015 11PHONON THERMAL TRANSPORT our device : Y X Propagation axes T1T2 Channel characterized by a dispersion Thermal reservoirs at equilibrium Assumed to be ideal contacts

12 B. Simulation Results 10/12/2015 12PHONON THERMAL TRANSPORT The goal is to get the temperature profile inside our device ! So, just solve the Heat diffusion equation (Fourier equation) ! Euhhh … ! Not exactly … ! … ?

13 Contents 13PHONON THERMAL TRANSPORT 10/12/2015 A - General Introduction B - Simulation Results 1. Fourier equation 2. Boltzmann Transport equation

14 B. Simulation results 1. Fourier equation 10/12/2015 14PHONON THERMAL TRANSPORT Then, at equilibrium => The heat diffusion equation is : In a medium :- Isotropic - with constant thermo-physical parameters So, the variable is T ! but how could we resolve this equation ? The Fourier law :

15 10/12/2015 15PHONON THERMAL TRANSPORT First step: Discretization (mesh of our silicon nano-wire) B. Simulation results 1. Fourier equation

16 10/12/2015 16PHONON THERMAL TRANSPORT Second step: Write the right program in MATLAB After : Check the results !! Then: Simply resolve the linear system: B. Simulation results 1. Fourier equation

17 10/12/2015 17PHONON THERMAL TRANSPORT Third step: Admire the results T source = T drain = 300 K T i = 9 nm = 150 nm T Grilles = 300 K

18 Contents 18PHONON THERMAL TRANSPORT 10/12/2015 A - General Introduction B - Simulation Results 1. Fourier equation 2. Boltzmann Transport equation

19 B. Simulation results 2. Boltzmann Transport equation 10/12/2015 19PHONON THERMAL TRANSPORT The RTA say : The general form is : So, the variable is N s ! but how could we resolve this equation ? What we need to resolve is this: Then =>

20 B. Simulation results 2. Boltzmann Transport equation 10/12/2015 20PHONON THERMAL TRANSPORT First step: Discretization (mesh of our silicon nano-wire both along x and y and in the reciprocal space (the Brillouin zone)) As we work in 2D, the above equation become : fBrown III, Thomas W., et Edward Hensel. « Statistical phonon transport model for multiscale simulation of thermal transport in silicon: Part I – Presentation of the model ». International Journal of Heat and Mass Transfer 55, n o 25 ‑ 26 (décembre 2012): 7444 ‑ 7452.

21 10/12/2015 21PHONON THERMAL TRANSPORT B. Simulation results 2. Boltzmann Transport Equation (BTE) Then: Simply resolve the linear system: with Second step: Write the right program in MATLAB After : Check the results !! Third step: Admire the results ! Euhh … ! Not yet !  We have to find a way to compute the Temperature using Ns (or more exactly Es = h’.w.Ns)

22 10/12/2015 22PHONON THERMAL TRANSPORT B. Simulation results 2. Boltzmann Transport Equation (BTE) So, we compute the equilibrium local phonon energy After, we draw the E(T) graph … ! Then, we make a polynomial fit to get T(E) Euhh ! In fact, we draw T(E)

23 10/12/2015 23PHONON THERMAL TRANSPORT B. Simulation results 2. Boltzmann Transport Equation (BTE) And : The temperature profile …

24 10/12/2015 24PHONON THERMAL TRANSPORT B. Simulation results 2. Boltzmann Transport Equation (BTE) Pending Work … ! But almost done !

Download ppt "Anes BOUCHENAK-KHELLADI Advisors : - Jérôme Saint-Martin - Philippe DOLLFUS Institut d’Electronique Fondamentale Phonon thermal transport in Nano-transistors."

Similar presentations

Lattice Dynamics related to movement of atoms

Lattice Dynamics related to movement of atoms
Materials properties at low temperature

Materials properties at low temperature
Electrical and Thermal Conductivity

Electrical and Thermal Conductivity
Institute of Technical Physics 1 conduction Hyperbolic heat conduction equation (HHCE) Outline 1. Maxwell – Cattaneo versus Fourier 2. Some properties.

Institute of Technical Physics 1 conduction Hyperbolic heat conduction equation (HHCE) Outline 1. Maxwell – Cattaneo versus Fourier 2. Some properties.
Non-Continuum Energy Transfer: Phonons

Non-Continuum Energy Transfer: Phonons
ME 381R Fall 2003 Micro-Nano Scale Thermal-Fluid Science and Technology Lecture 4: Crystal Vibration and Phonon Dr. Li Shi Department of Mechanical Engineering.

ME 381R Fall 2003 Micro-Nano Scale Thermal-Fluid Science and Technology Lecture 4: Crystal Vibration and Phonon Dr. Li Shi Department of Mechanical Engineering.
Introductory Nanotechnology ~ Basic Condensed Matter Physics ~

Introductory Nanotechnology ~ Basic Condensed Matter Physics ~
Computational Solid State Physics 計算物性学特論 第2回 2.Interaction between atoms and the lattice properties of crystals.

Computational Solid State Physics 計算物性学特論 第2回 2.Interaction between atoms and the lattice properties of crystals.
AME 60614 Int. Heat Trans. D. B. GoSlide 1 Non-Continuum Energy Transfer: Overview.

AME Int. Heat Trans. D. B. GoSlide 1 Non-Continuum Energy Transfer: Overview.
CHAPTER 3 Introduction to the Quantum Theory of Solids

CHAPTER 3 Introduction to the Quantum Theory of Solids
AME 60614 Int. Heat Trans. D. B. GoSlide 1 Non-Continuum Energy Transfer: Gas Dynamics.

AME Int. Heat Trans. D. B. GoSlide 1 Non-Continuum Energy Transfer: Gas Dynamics.
ME 595M J.Murthy1 ME 595M: Computational Methods for Nanoscale Thermal Transport Lecture 10:Higher-Order BTE Models J. Murthy Purdue University.

ME 595M J.Murthy1 ME 595M: Computational Methods for Nanoscale Thermal Transport Lecture 10:Higher-Order BTE Models J. Murthy Purdue University.
PERSPECTIVES FOR SEMICONDUCTOR DEVICE SIMULATION: A KINETIC APPROACH A.M.ANILE DIPARTIMENTO DI MATEMATICA E INFORMATICA UNIVERSITA’ DI CATANIA PLAN OF.

PERSPECTIVES FOR SEMICONDUCTOR DEVICE SIMULATION: A KINETIC APPROACH A.M.ANILE DIPARTIMENTO DI MATEMATICA E INFORMATICA UNIVERSITA’ DI CATANIA PLAN OF.
1 Motivation (Why is this course required?) Computers –Human based –Tube based –Solid state based Why do we need computers? –Modeling Analytical- great.

1 Motivation (Why is this course required?) Computers –Human based –Tube based –Solid state based Why do we need computers? –Modeling Analytical- great.
ME 595M J.Murthy1 ME 595M: Computational Methods for Nanoscale Thermal Transport Lecture 6: Introduction to the Phonon Boltzmann Transport Equation J.

ME 595M J.Murthy1 ME 595M: Computational Methods for Nanoscale Thermal Transport Lecture 6: Introduction to the Phonon Boltzmann Transport Equation J.
Thermal Properties of Crystal Lattices

Thermal Properties of Crystal Lattices
Crystal Lattice Vibrations: Phonons

Crystal Lattice Vibrations: Phonons
ME 595M J.Murthy1 ME 595M: Computational Methods for Nanoscale Thermal Transport Lecture 11:Extensions and Modifications J. Murthy Purdue University.

ME 595M J.Murthy1 ME 595M: Computational Methods for Nanoscale Thermal Transport Lecture 11:Extensions and Modifications J. Murthy Purdue University.
Laser Physics I Dr. Salah Hassab Elnaby Lecture(2)

Laser Physics I Dr. Salah Hassab Elnaby Lecture(2)
AME 60634 Int. Heat Trans. D. B. GoSlide 1 Non-Continuum Energy Transfer: Electrons.

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

Similar presentations

Ads by Google