Semiconductor Physics. Lecture 6

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Transcription:

Semiconductor Physics Lecture 6

Recap pn junction and the depletion region Driven by the need to have no gradient in the fermi level free carriers migrate across the pn junction leaving a region with few free carriers (depletion region) Have uncompensated changed acceptor and donor ions leading to an eletrostatic potential Vbi (n side positive with respect to the p side) which bend the bands to produce a flat fermi level Absence of carriers in the depletion region means that the pn junction can be regarded as a high resistance region sandwiched between two low resistance regions Resistance is a function of the magnitude and sign of the applied voltage We will now consider the effect of applying a voltage

Applied voltage forward bias If a the p end of the junction is made positive relative to the equilibrium state the junction is said to be forward biased Step between energy levels is reduced No longer have a flat Fermi level since current is now flowing replace with quasi Fermi levels -qφ p, -qφ n for holes and electrons Bulk of gradient close boundary since resistance is highest here Have a situation where the free carrier density in the depletion region is increased (lowering its resistance) and carriers cross the boundary

Applied voltage reverse bias If a the p end of the junction is made negative relative to the equilibrium state the junction is said to be forward biased Step between energy levels is increased Have a situation where the free carrier density in the depletion region is decrease (increasing its resistance)

Shockley equation Want to calculate current voltage relationship Assume that all of the potential gradients are supported by the depletion layer and that outside of this region the semiconductor is neutral Assume that the relationships between the quasi-fermi level and the carrier density are the same as for the thermal equilibrium case ( departures from equilibrium are small) Low injection conditions apply. The injected minority carrier concentrations are small compared with the majority No generation of carriers in the depletion layer

Shockley equation II In thermal equilibrium the electron and hole concentrations are Change made from energies to potentials so that we can handle the applied voltage Applied voltage means that Φ is replaced by Φ p, Φ n quasi Fermi levels If Φ p >Φ n then pn>n i 2 forward bias, Φ p <Φ n pn<n i 2 reverse bias

Current density The current density is the sum of the currents produced by the electric field (gradient of the potential) and the diffusion current produced by the concentration gradient. Which reduces to Thus the current density is simply proportional to the spatial gradients of the quasi Fermi levels Since the carrier density varies by many orders of magnitude across the depletion layer and yet J n is roughly constant it follows that Φ n has a very small gradient across the depletion layer

Carrier densities The voltage across the junction is V= Φ p -Φ n At the p side of the depletion layer (x=x p ) For holes at x=x n I.E. excess of minority carriers at the edges of depletion layer for forward bias and depletion for reverse bias wrt equilibrium concentration

Continuity equations For a steady state the change in carrier concentration with time is zero and the continuity equations become consider the case in the neutral region of the n type material If we assume approximate charge neutrality so that n n -n no p n -p no then the spatial variations of p and n are the same. We can then eliminate the term in the electric field gradient to obtain

Continuity equations II Where And

Continuity equations III For low injection conditions n is much greater than p and approximately equal to n no Becomes Once we are far enough away from the junction there is no electric field With the boundary condition that p n ( )=p no the solution is

Current densities

Shockley equation Total current density is the sum of the hole current density at x=x n and the electron current density at x=-x p Shockley equation

Notice ease with which current flows in forward bias Difficulty in reverse Max reverse current is Current voltage characteristics Instantaneous resistance Is almost infinite in reverse bias pn junction acts as a rectifier Also known as a diode

Important breakthrough Prior to solid state rectifiers Rectifiers we based on vacuum electronics Thermionic diode or mercury rectifiers For industrial application high heat output and large and cumbersome For example to power a train takes ~1000 A DC at 1 kv 1 rectifier house every 10 miles Now such equipment can be put on the train Power transmission at much higher voltage more effficent

Departures from the ideal case The shockley equation is an idealised form but it incorporates some approximations which are not valid for real systems It assumes carriers are not generated in the depletion region For a reverse biased junction we have emission in the depletion region given by a rate Current density is simply the integral of this over the width of the depletion layer But the width increases as the square root of the applied voltage Total reverse current is for low n i (for example Si second term is significant

Departures from the ideal case Also have recombination effects in forward bias case And at very high currents the effects of the resistance of the neutral parts away from the junction and high injection where the number of injected carriers becomes comparable with the number of majority carriers overall behaviour looks like

Diffusion capacitance We have met depletion capacitance associated with reversed biased junctions but in forward bias there is a significant capacitance from rearrangement of minority carriers. Consider a small ac signal For small V 1 Continuity equation becomes

Diffusion capacitance II This is the same as the static case Current is then Admittance (generalised conductance or inverse impedance

For low frequencies when ϖτ<1 Diffusion capacitance III Conductance Capacitance

Breakdown At extreme reverse bias the junction begins to conduct and is said to break down 3 Causes Thermal instability where the heat dissipated by the reverse voltage excites more carriers causing a runaway current Tunnelling Avalanche multiplication

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