Presentation is loading. Please wait.

Presentation is loading. Please wait.

Electrons in metals ++++++++ Energy E Spatial coordinate x Nucleus with localized core electrons Jellium model: electrons shield potential to a large extent.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Electrons in metals ++++++++ Energy E Spatial coordinate x Nucleus with localized core electrons Jellium model: electrons shield potential to a large extent."— Presentation transcript:

1 Electrons in metals ++++++++ Energy E Spatial coordinate x Nucleus with localized core electrons Jellium model: electrons shield potential to a large extent Electron “sees” effective smeared potential  

2 Electron in a box In one dimension: In three dimensions: where and

3  Fixed boundary conditions: ++++++++ x 0 L + + + + + + + + Periodic boundary conditions: and kxkx “free electron parabola” density of states Remember the concept of # of states in

4 1. approach use the technique already applied for phonon density of states where Density of states per unit volume Because I copy this part of the lecture from my solid state slides, I use E as the single particle energy. In our stat. phys. lecture we labeled the single particle energy  to distinguish it from the total energy of the N-particle system. Please don’t be confused due to this inconsistency.

5 1/ Volume occupied by a state in k-space kxkx kyky kzkz Volume( )

6 Free electron gas: Independent from and  Independent from and  2 Each k-state can be occupied with 2 electrons of spin up/down k2k2 dk

7 2. approach calculate the volume in k-space enclosed by the spheres and kxkx kyky # of states between spheres with k and k+dk : with 2 2 spin states

8 E D(E) E’E’+dE D(E)dE =# of states in dE / Volume

9 The Fermi gas at T=0 E f(E,T=0) EFEF 1 E D(E) EF0EF0 Electron density #of states in [E,E+dE]/volume Fermi energy depends on T Probability that state is occupied T=0

10 Energy of the electron gas @ T=0: there is an average energy of per electron without thermal stimulation with electron densitywe obtain Energy of the electron gas :

11 Specific Heat of a Degenerate Electron Gas here: strong deviation from classical value only a few electrons in the vicinity of E F can be scattered by thermal energy into free states Specific heat much smaller than expected from classical consideration D(E) Density of occupied states E EFEF energy of electron state #states in [E,E+dE] probability of occupation, average occupation # 2k B T Before we calculate U let us estimate: These # of electrons increase energy from to

12 π2π2 3 subsequent more precise calculation Calculation of C el from Trick: Significant contributions only in the vicinity of E F

13 with and E D(E) EFEF decreases rapidly to zero for

14 withand in comparison with for relevant temperatures W.H. Lien and N.E. Phillips, Phys. Rev. 133, A1370 (1964) Heat capacity of a metal: electronic contribution lattice contribution @ T<<Ө D

Download ppt "Electrons in metals ++++++++ Energy E Spatial coordinate x Nucleus with localized core electrons Jellium model: electrons shield potential to a large extent."

Similar presentations

Lecture 27 Electron Gas The model, the partition function and the Fermi function Thermodynamic functions at T = 0 Thermodynamic functions at T > 0.

Lecture 27 Electron Gas The model, the partition function and the Fermi function Thermodynamic functions at T = 0 Thermodynamic functions at T > 0.
Heat capacity at constant volume

Heat capacity at constant volume
Free Electron Fermi Gas

Free Electron Fermi Gas
The Quantized Free Electron Theory ++++++++ Energy E Spatial coordinate x Nucleus with localized core electrons Jellium model: electrons shield potential.

The Quantized Free Electron Theory Energy E Spatial coordinate x Nucleus with localized core electrons Jellium model: electrons shield potential.
MSEG 803 Equilibria in Material Systems 9: Ideal Gas Quantum Statistics Prof. Juejun (JJ) Hu

MSEG 803 Equilibria in Material Systems 9: Ideal Gas Quantum Statistics Prof. Juejun (JJ) Hu
Bose systems: photons, phonons & magnons Photons* and Planck’s black body radiation law

Bose systems: photons, phonons & magnons Photons* and Planck’s black body radiation law
Atomic Vibrations in Solids: phonons

Atomic Vibrations in Solids: phonons
A Box of Particles. Dimensions We studied a single particle in a box What happens if we have a box full of particles?? x y z We get a model of a gas The.

A Box of Particles. Dimensions We studied a single particle in a box What happens if we have a box full of particles?? x y z We get a model of a gas The.
1 Lecture 5 The grand canonical ensemble. Density and energy fluctuations in the grand canonical ensemble: correspondence with other ensembles. Fermi-Dirac.

1 Lecture 5 The grand canonical ensemble. Density and energy fluctuations in the grand canonical ensemble: correspondence with other ensembles. Fermi-Dirac.
Lecture Notes # 3 Understanding Density of States

Lecture Notes # 3 Understanding Density of States
CHAPTER 3 Introduction to the Quantum Theory of Solids

CHAPTER 3 Introduction to the Quantum Theory of Solids
Www.soran.edu.iq Solid state Phys. Chapter 2 Thermal and electrical properties 1.

Solid state Phys. Chapter 2 Thermal and electrical properties 1.
MSEG 803 Equilibria in Material Systems 10: Heat Capacity of Materials Prof. Juejun (JJ) Hu

MSEG 803 Equilibria in Material Systems 10: Heat Capacity of Materials Prof. Juejun (JJ) Hu
P461 - Quan. Stats. II1 Boson and Fermion “Gases” If free/quasifree gases mass > 0 non-relativistic P(E) = D(E) x n(E) --- do Bosons first let N(E) = total.

P461 - Quan. Stats. II1 Boson and Fermion “Gases” If free/quasifree gases mass > 0 non-relativistic P(E) = D(E) x n(E) --- do Bosons first let N(E) = total.
Lecture 25 Practice problems Boltzmann Statistics, Maxwell speed distribution Fermi-Dirac distribution, Degenerate Fermi gas Bose-Einstein distribution,

Lecture 25 Practice problems Boltzmann Statistics, Maxwell speed distribution Fermi-Dirac distribution, Degenerate Fermi gas Bose-Einstein distribution,
CHAPTER 5 FREE ELECTRON THEORY

CHAPTER 5 FREE ELECTRON THEORY
18.38. 19.2 The calculation of μ(T) To obtain these curves, we must determine μ(T). The calculation is considerably more complicated than it was for.

The calculation of μ(T) To obtain these curves, we must determine μ(T). The calculation is considerably more complicated than it was for.
PY4007 Nanoscience 3D free electron gas 1 volume of e-gas Want to find: Write: For a free electron: so: Now need:

PY4007 Nanoscience 3D free electron gas 1 volume of e-gas Want to find: Write: For a free electron: so: Now need:
P460 - Quan. Stats. III1 Boson and Fermion “Gases” If free/quasifree gases mass > 0 non-relativistic P(E) = D(E) x n(E) --- do Bosons first let N(E) =

P460 - Quan. Stats. III1 Boson and Fermion “Gases” If free/quasifree gases mass > 0 non-relativistic P(E) = D(E) x n(E) --- do Bosons first let N(E) =
EEE539 Solid State Electronics 5. Phonons – Thermal Properties Issues that are addressed in this chapter include:  Phonon heat capacity with explanation.

EEE539 Solid State Electronics 5. Phonons – Thermal Properties Issues that are addressed in this chapter include:  Phonon heat capacity with explanation.

Similar presentations

Ads by Google