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Overview of Silicon Device Physics

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Presentation on theme: "Overview of Silicon Device Physics"— Presentation transcript:

1 Overview of Silicon Device Physics
Dr. Ethan Farquhar University of Tennessee Department of Electrical Engineering and Computer Science

2 Silicon Silicon is the primary semiconductor used in VLSI systems
Si has 14 Electrons Energy Bands (Shells) Valence Band Nucleus At T=0K, the highest energy band occupied by an electron is called the valence band. Silicon has 4 outer shell / valence electrons

3 Energy Bands Electrons try to occupy the lowest energy band possible Not every energy level is a legal state for an electron to occupy These legal states tend to arrange themselves in bands Disallowed Energy States } Increasing Electron Energy Allowed Energy States } Energy Bands

4 Energy Bands EC Eg EV Conduction Band
First unfilled energy band at T=0K Eg Energy Bandgap EV Valence Band Last filled energy band at T=0K

5 Increasing electron energy
Band Diagrams Increasing electron energy Eg EC EV Increasing voltage Band Diagram Representation Energy plotted as a function of position EC  Conduction band  Lowest energy state for a free electron EV  Valence band  Highest energy state for filled outer shells EG  Band gap  Difference in energy levels between EC and EV  No electrons (e-) in the bandgap (only above EC or below EV)  EG = 1.12eV in Silicon

6 Conductor, Semiconductor or Insulator?
Examples Silver Copper Gold Silicon Si/Ge SiO2 Diamond Overlapping Bands - or - Partially Filled Bands Conductor Semiconductor Insulator

7 Intrinsic Semiconductor
Silicon has 4 outer shell / valence electrons Forms into a lattice structure to share electrons

8 Intrinsic Silicon The valence band is full, and no electrons are free to move about EC EV However, at temperatures above T=0K, thermal energy shakes an electron free

9 Semiconductor Properties
For T > 0K Electron shaken free and can cause current to flow Generation – Creation of an electron (e-) and hole (h+) pair h+ is simply a missing electron, which leaves an excess positive charge (due to an extra proton) Recombination – if an e- and an h+ come in contact, they annihilate each other Electrons and holes are called “carriers” because they are charged particles – when they move, they carry current Therefore, semiconductors can conduct electricity for T > 0K … but not much current (at room temperature (300K), pure silicon has only 1 free electron per 3 trillion atoms) h+ e–

10 Doping Doping – Adding impurities to the silicon crystal lattice to increase the number of carriers Add a small number of atoms to increase either the number of electrons or holes

11 Periodic Table Column 3 Elements have 3 electrons in the Valence Shell

12 Donors n-Type Material
Add atoms with 5 valence-band electrons ex. Phosphorous (P) “Donates” an extra e- that can freely travel around Leaves behind a positively charged nucleus (cannot move) Overall, the crystal is still electrically neutral Called “n-type” material (added negative carriers) ND = the concentration of donor atoms [atoms/cm3 or cm-3] ~ cm-3 e- is free to move about the crystal (Mobility mn ≈1350cm2/V) +

13 Donors n-Type Material
Add atoms with 5 valence-band electrons ex. Phosphorous (P) “Donates” an extra e- that can freely travel around Leaves behind a positively charged nucleus (cannot move) Overall, the crystal is still electrically neutral Called “n-type” material (added negative carriers) ND = the concentration of donor atoms [atoms/cm3 or cm-3] ~ cm-3 e- is free to move about the crystal (Mobility mn ≈1350cm2/V) n-Type Material + + + + + + + + + + + + + + + + + + + Shorthand Notation Positively charged ion; immobile Negatively charged e-; mobile; Called “majority carrier” Positively charged h+; mobile; Called “minority carrier” + +

14 Acceptors Make p-Type Material
Add atoms with only 3 valence-band electrons ex. Boron (B) “Accepts” e– and provides extra h+ to freely travel around Leaves behind a negatively charged nucleus (cannot move) Overall, the crystal is still electrically neutral Called “p-type” silicon (added positive carriers) NA = the concentration of acceptor atoms [atoms/cm3 or cm-3] Movement of the hole requires breaking of a bond! (This is hard, so mobility is low, μp ≈ 500cm2/V) h+

15 Acceptors Make p-Type Material
Add atoms with only 3 valence-band electrons ex. Boron (B) “Accepts” e– and provides extra h+ to freely travel around Leaves behind a negatively charged nucleus (cannot move) Overall, the crystal is still electrically neutral Called “p-type” silicon (added positive carriers) NA = the concentration of acceptor atoms [atoms/cm3 or cm-3] Movement of the hole requires breaking of a bond! (This is hard, so mobility is low, μp ≈ 500cm2/V) + + + + + + + + + + + + + + + + + Shorthand Notation Negatively charged ion; immobile Positively charged h+; mobile; Called “majority carrier” Negatively charged e-; mobile; Called “minority carrier” +

16 The Fermi Function The Fermi Function
Probability distribution function (PDF) The probability that an available state at an energy E will be occupied by an e- E  Energy level of interest Ef  Fermi level  Halfway point  Where f(E) = 0.5 k  Boltzmann constant = 1.38×10-23 J/K = 8.617×10-5 eV/K T  Absolute temperature (in Kelvins)

17 Boltzmann Distribution
If Then Boltzmann Distribution Describes exponential decrease in the density of particles in thermal equilibrium with a potential gradient Applies to all physical systems Atmosphere  Exponential distribution of gas molecules Electronics  Exponential distribution of electrons Biology  Exponential distribution of ions

18 Band Diagrams (Revisited)
EC Eg Ef EV Band Diagram Representation Energy plotted as a function of position EC  Conduction band  Lowest energy state for a free electron  Electrons in the conduction band means current can flow EV  Valence band  Highest energy state for filled outer shells  Holes in the valence band means current can flow Ef  Fermi Level  Shows the likely distribution of electrons EG  Band gap  Difference in energy levels between EC and EV  No electrons (e-) in the bandgap (only above EC or below EV)  EG = 1.12eV in Silicon Virtually all of the valence-band energy levels are filled with e- Virtually no e- in the conduction band

19 Effect of Doping on Fermi Level
Ef is a function of the impurity-doping level n-Type Material EC EV Ef High probability of a free e- in the conduction band Moving Ef closer to EC (higher doping) increases the number of available majority carriers

20 Effect of Doping on Fermi Level
Ef is a function of the impurity-doping level p-Type Material EC EV Ef Low probability of a free e- in the conduction band High probability of h+ in the valence band Moving Ef closer to EV (higher doping) increases the number of available majority carriers

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