Physics of Electronics: 3. Collection of Particles in Gases and Solids

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Presentation transcript:

Physics of Electronics: 3. Collection of Particles in Gases and Solids July – December 2008

Contents overview The hydrogen atom. The exclusion principle. Assemblies of classical particles. Collection of particles obeying the exclusion principle.

(r, , ) = R(r)Y(, ) = R(r)()()‏ The Hydrogen Atom Electron in the electric field of the nucleus: SE in polar coordinates: Full solution by separation of variables assuming: (r, , ) = R(r)Y(, ) = R(r)()()‏ r2  r 1 2m ħ2 +

The Hydrogen Atom Electron in the electric field of the nucleus: Azimuth part: Polar part: Radial part: Total w.v. and energy:

The Hydrogen Atom Electron moving in the electric field of the nucleus: The ground state (level with lowest energy) is: |100 (r)|2 Highest probability of finding the electron at r = a = a

Spin & Exclusion Principle It exist another quantum number describing the electron in an atom: SPIN number. It represents the rotation of the electron over its own axis. It can be obtained by solving the relativistic SE. Therefore, an electron inan atom is completely specified by 4 quantum numbers: The exclusion principle says that no 2 electrons can have the same quantum numbers.

Assemblies of Classical Particles Consider a gas of N neutral molecules For every particle: The number of particles in dVxyz is and in a shell of thickness dv is where P(v2) is the density of particles having a speed v (i.e. density of points in v-space). dVxyz Total number of particles is:

Assemblies of Classical Particles The distribution function (distribution of speeds): To find P(v2) let’s consider collisions inside this gas Constants A and  are found from: Collision and reversed collision: Energy conservation: Total number of particles: Definition of T:  ½(M v2) [A exp(- v2)] Mean kinetic energy

Maxwell-Boltzmann Distribution Function Relation between P(v2) and f (v): Number of particles in a shell of thickness dv: f (v) gives the fraction of molecules (per unit volume) in a given speed range (per unit range of speed). =

Maxwell-Boltzmann Distribution Function Relation between P(v2) and f (v): Number of particles in a shell of thickness dv: f (v) gives the fraction of molecules (per unit volume) in a given speed range (per unit range of speed). Fraction of molecules with speed less than v’

Maxwell-Boltzmann Distribution Function Average values: Most probable velocity: f’(v) = 0  Average velocity: RMS velocity: = 

Energy Distribution Function How the energy is distributed in the ensemble The particles in the ensemble we have considered so far only have kinetic energy: Replacing in the expression for dNv: But then:  Note that the density of the particles is independent of the position

Boltzmann Distribution Function How the energy is distributed in the ensemble We now consider that the particles in the ensemble not only have KE but also PE (gravitational or electrical field). If the PE depends on the position so does the density of the ensemble:

Fermi-Dirac Distribution Ensembles obeying exclusion principle Two quantum particles (E1, E2) interact and end up in two states (E3, E4) previously empty: E1, p(E1) E3, 1- p(E3) E2, p(E2) E4, 1- p(E4)

Fermi-Dirac Distribution Ensembles obeying exclusion principle Two quantum particles (E3, E4) interact and end up in two states (E1, E2) previously empty: E1, 1- p(E1) E3, p(E3) = E2, 1- p(E2) E4, p(E4)

Fermi-Dirac Distribution Ensembles obeying exclusion principle Two quantum particles (E3, E4) interact and end up in two states (E1, E2) previously empty: When E it reduces to the Boltzmann distribution: E1, 1- p(E1) E3, p(E3) = E2, 1- p(E2) E4, p(E4) E1+ E2 = E1+ E2 b = 1/kT

Fermi-Dirac Distribution Ensembles obeying exclusion principle The constant A is redefined through EF and can be found via normalization Therefore: p(E) Note that for T = 0, p(E) reduces to a step function. It means that all the states with energies E  EF are occupied and those above, are empty. When T > 0, some states below EF are emptied and some are occupied due to thermal energy.

Maxwell’s Demon A demon that can violate 2nd. law of energy. Does it really exist? For an experiment see the following article: http://www.nature.com/nature/journal/v445/n7127/pdf/nature 05452.pdf (“A molecular information ratchet” by V. Serreli)