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Overview of Silicon Device Physics

Overview of Silicon Device Physics. Dr. David W. Graham West Virginia University Lane Department of Computer Science and Electrical Engineering. Silicon. At T=0K, the highest energy band occupied by an electron is called the valence band. Silicon has 4 outer shell / valence electrons.

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Overview of Silicon Device Physics

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  1. Overview of Silicon Device Physics Dr. David W. Graham West Virginia University Lane Department of Computer Science and Electrical Engineering

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

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

  5. Band Diagrams Increasing electron energy Increasing voltage EC Eg EV 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. Intrinsic Semiconductor Silicon has 4 outer shell / valence electrons Forms into a lattice structure to share electrons

  7. 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

  8. Semiconductor Properties For T > 0K • 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) Electron shaken free and can cause current to flow h+ e–

  9. 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

  10. Periodic Table Column 3 Elements have 3 electrons in the Valence Shell Column 4 Elements have 4 electrons in the Valence Shell Column 5 Elements have 5 electrons in the Valence Shell

  11. Donors n-Type Material • Donors • Add atoms with 5 valence-band electrons • ex. Phosphorous (P) • “Dontates 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] • ~1015-1020cm-3 • e- is free to move about the crystal (Mobility mn ≈1350cm2/V) +

  12. Donors n-Type Material • Donors • 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] • ~1015-1020cm-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” + – +

  13. Acceptors Make p-Type Material h+ – • Acceptors • 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) –

  14. Acceptors Make p-Type Material p-Type Material • Acceptors • 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” – + –

  15. 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)

  16. 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

  17. Band Diagrams (Revisited) • Virtually all of the valence-band energy levels are filled with e- • Virtually no e- in the conduction band 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

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

  19. Effect of Doping on Fermi Level EC Ef EV Ef is a function of the impurity-doping level p-Type Material • 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

  20. Thermal Motion of Charged Particles Applies to both electronic systems and biological systems Look at drift and diffusion in silicon Assume 1-D motion

  21. Drift E Drift→ Movement of charged particles in response to an external field (typically an electric field) E-field applies force F = qE which accelerates the charged particle. However, the particle does not accelerate indefinitely because of collisions with the lattice (velocity saturation) Average velocity <vx> ≈ -µnEx electrons < vx > ≈ µpEx holes µn → electron mobility → empirical proportionality constant between E and velocity µp → hole mobility µn ≈ 3µp

  22. Drift Drift→ Movement of charged particles in response to an external field (typically an electric field) E-field applies force F = qE which accelerates the charged particle. However, the particle does not accelerate indefinitely because of collisions with the lattice (velocity saturation) Average velocity <vx> ≈ -µnEx electrons < vx > ≈ -µpEx holes µn → electron mobility → empirical proportionality constant between E and velocity µp → hole mobility µn ≈ 3µp Current Density q = 1.6×10-19 C, carrier density n = number of e- p = number of h+

  23. Diffusion Diffusion→ Motion of charged particles due to a concentration gradient Charged particles move in random directions Charged particles tend to move from areas of high concentration to areas of low concentration (entropy – Second Law of Thermodynamics) Net effect is a current flow (carriers moving from areas of high concentration to areas of low concentration) q = 1.6×10-19 C, carrier density D = Diffusion coefficient n(x) = e- density at position x p(x) = h+density at position x → The negative sign in Jp,diff is due to moving in the opposite direction from the concentration gradient → The positive sign from Jn,diff is because the negative from the e- cancels out the negative from the concentration gradient

  24. Einstein Relation Einstein Relation→ Relates D and µ (they are not independent of each other) UT = kT/q → Thermal voltage = 25.86mVat room temperature ≈ 25mVfor quick hand approximations → Used in biological and silicon applications

  25. p-n Junctions (Diodes) p-n Junctions (Diodes) Fundamental semiconductor device In every type of transistor Useful circuit elements (one-way valve) Light emitting diodes (LEDs) Light sensors (imagers)

  26. p-n Junctions (Diodes) + + + + + + + + – – – – – – – – – – – – + – + + + – – – + + + + + + + + + + + + – – – – – – – – – + – + – + – + – + + + – – + – + + + + + + + + – – – – – – – – + – – – – – + – + + + + + – – + p-type n-type Bring p-type and n-type material into contact

  27. p-n Junctions (Diodes) + + + + + + + + + + + + + + + + + + – – – – – – – – – – – – – – – + – – + – + + – – – – – – – – – – + – – – – – + + + – + – + + – + – + + + + – + + + + + + + + + + + + + + + + + + – – – – – – – – – – – – – – + + + + – – + – + – + + + – + + – + – – – – + + – – – – – – – + – + – – – – – – + + + + + + + + + + + + + + + + + + – – – – – – – – – – – – – – – – – + + – – + – + + – – + – + – – – – + + + + + + – + – – – – – – – + – – + – Depletion Region p-type n-type • All the h+ from the p-type side and e- from the n-type side undergo diffusion • → Move towards the opposite side (less concentration) • When the carriers get to the other side, they become minority carriers • Recombination → The minority carriers are quickly annihilated by the large number of majority carriers • All the carriers on both sides of the junction are depleted from the material leaving • Only charged, stationary particles (within a given region) • A net electric field •  This area is known as the depletion region (depleted of carriers)

  28. Charge Density p-type n-type + + + + + + + + + + + + + + + + + + – – – – – – – – – – – – – + – – – – – – – + – – + + + – + + – + + + + + – + + + + – – – – – – – – – – – – – + + + + + + + + + + + + + + + + + + – – – – – – – – – – – – – + – – – + – + + – – + + – – + + + + – – – – + + – + – – + + – – – – – – – – – + – + + + + + + + + + + + + + + + + + + – – – – – – – – – – – – – + + – – – – – + + – + + + + – + – + – – – + + + + – – – – – – – – – – – – – + – + Depletion Region Charge Density The remaining stationary charged particles results in areas with a net charge

  29. Electric Field Areas with opposing charge densities creates an E-field E-field is the integral of the charge density Poisson’s Equation ε is the permittivity of Silicon Charge Density Electric Field

  30. Potential Charge Density Electric Field Potential • E-field sets up a potential difference • Potential is the negative of the integral of the E-field

  31. Band Diagram Charge Density Electric Field Potential Band Diagram • Line up the Fermi levels • Draw a smooth curve to connect them

  32. p-n Junction Band Diagram p-type n-type

  33. p-n Junction – No Applied Bias If VA = 0 • Any e- or h+ that wanders into the depletion region will be swept to the other side via the E-field • Some e- and h+ have sufficient energy to diffuse across the depletion region • If no applied voltage • Idrift = Idiff

  34. p-n Junction – Reverse Biased If VA < 0 • Barrier is increased • No diffusion current occurs (not sufficient energy to cross the barrier) • Drift may still occur • Any generation that occurs inside the depletion region adds to the drift current • All current is drift current Reverse Biased

  35. p-n Junction – Forward Biased If VA < 0 • Barrier is reduced, so more e- and h+ may diffuse across • Increasing VA increases the e- and h+ that have sufficient energy to cross the boundary in an exponential relationship (Boltzmann Distributions) • →Exponential increase in diffusion current • Drift current remains the same Forward Biased

  36. p-n Junction Diode Diffusion Drift Combination of drift and generation → Thermal voltage = 25.86mV

  37. p-n Junction Diode for VA > 0 for VA < 0

  38. Curve Fitting Exponential Data (In MATLAB) • Curve Fitting Exponential Data (In MATLAB) • Given I and V (vectors of data) • Use the MATLAB functions • polyfit – function to fit a polynomial (find the coefficients) • polyval – function to plot a polynomial with given coefficients and x values • [A] = polyfit(V,log(I),1); • % polyfit(independent_var,dependent_var,polynomial_order) • % A(1) = slope • % A(2) = intercept • [I_fit] = polyval(A,V); • % draws the curve-fit line

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