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Since (pp) >>(np)

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1 Since (pp) >>(np)
Electronic Physics Dr. Ghusoon Mohsin Ali Conductivity of Extrinsic Semiconductor.   n e  p e i n i p For n-type   n e  p e n n n n p Since (nn) >>( pn )   n e n n n and if nn=ND then  n  NDen For p-type   n e  p e p p n p p Since (pp) >>(np)  p e p p p and if pp=NA then  N e p A p Example P-type sample with l=6mm, A=0.5mm2, R=120Ω. Calculate majority and minority carriers if intrinsic carrier density is 2.5×1019/ m3. Given μn=0.38m2/Vs, μp=0.18m2/Vs . Solution l R   l  A A   p e p p p

2 ni =np pp   p n 2 p 100  3.461021 / m3 e 1.6 1019  0.18
Electronic Physics Dr. Ghusoon Mohsin Ali 2 ni =np pp   p p 100  3.461021 / m3 p e 1.6 1019  0.18 p n 2 n  i  1.9 1017 / m3 p p p Drift Current Density An electric field is applied to a semiconductor will produce force on electrons and holes so that they will experience a net acceleration and net movement. This net movement of charge due to an electric field is called drift. The net drift of charge gives rise to a drift current. The current density due to electrons drift J  ne E n n The current density due to electrons drift J  pe E p p The total current density due to electrons and holes drift J  J  J  ne E  pe E n p n p Example Calculate the drift current density in a gallium arsenide sample at T=300 K, with doping concentration Na=0, Nd=1022/m3, µn=0.85m2/V.s, µp=0.04m2/V.s, E=10 V/cm, ni=2.2×1017/m3. Solution

3 Electronic Physics Dr. Ghusoon Mohsin Ali Since ND>>Na then it is n-type n  N  N n D n  1022 / m3 A The minority hole concentration is n 2 p  i  3.24102 / m3 n J  1.6 1019 0.851022 103  136104 A / m2 Diffusion Current Density It is gradual flow of charge from a region of high density to a region of low density. Current density due to electron diffusion is J  eD dn n n dx Current density due to hole diffusion is J  eD dp p p dx Where Dn, Dp (cm2/s) are electron and hole diffusion constants, respectively. dn dx dp dx Density gradient of electrons Density gradient of holes

4 L  D  L  D    J  en E  ep E  eD dn  eD dp D D kT  e
Electronic Physics Dr. Ghusoon Mohsin Ali Total Current Density The total current density is the sum of these four components J  en E  ep E  eD dn  eD dp n p n dx p dx Einstein Relation This relation between the mobility and diffusion coefficient. D D p n    kT e n p D  kT    e 39 Example Determine the diffusion coefficient, assume the mobility is 1000cm2/V.s at T=300K. Solution D  kT   1000  25.9cm2 / s e Rcombination Recombination that result from the collision of an electron with a hole. This process is the return of a free electrons in the conduction band to valence band, there is a net recombination rate by difference between the recombination and generation rates. L  D  L  D  n n p p Where L the distance traveled by charge carrier before, recombination τ life time.

5 the current density Jx is given by:
Electronic Physics Dr. Ghusoon Mohsin Ali Hall Effect: As shown there is a current Ix resulting from an applied electric field Ex in x- direction an electrons will drift vx. A magnetic field By (wb/m2) is superposed on applied electric field Ex , whereby the current Ix and the magnetic flux By are perpendicular to each other. The electrons will experience a Lorentz force Fz perpendicular to Ix and By ( in z direction) F  ev B z x y Thus the electrons under the influence of this force will tend to crowds one face in the sample. This collection of electrons to one side establish an electric field in z-direction is known Hall effect EH or Ez. Resulting a voltage VH between the upper and the lower faces of the sample is observed: On the other hand eE  ev B z x y the current density Jx is given by: E  v B Jx  Ex J  nev x x z x y VH Fig Hall measurement situation

6  x  x  1 J E  x B ne I I A bd J ne R I E  R V I b I d V  R I
Electronic Physics Dr. Ghusoon Mohsin Ali J E  x B z ne y I I  x  x A bd J x Hall coefficient  1 ne R Where n is the total number of charge carrier per volum H I x B E  R z H bd y V I H  R x B b H bd y I x B d V  R H H y I n  x B V ed y H Where all the quantities in the right-hand side of the equation can n measured. Thus the carrier concentration and carrier type can e obtained directly from the Hall measurement. J  E  neE x x x I neV x x A L

7  x  x   I L neV A I n  x B V ed  (103 )(5102 ) n 
Electronic Physics Dr. Ghusoon Mohsin Ali I L  x neV A x Example Determine the majority carrier concentration and mobility, sample 10-1cm length and 10-2×10-3cm2 cross section area, given Hall effect parameters Ix=1mA, Vx=12.V, B=5×10-2tesla, VH=-6.25mV. Solution The negative Hall voltage indicate n-type semiconductor I n  x B V ed y H  (103 )(5102 ) n   510 m 21 3 (1.61019 )(105 )(6.25103 ) I L  x neV A x (103 )(103 )    0.1m /V.s 2 (1.61019 )(51021)(12.5)(104 )(105 )

8 Electronic Physics Dr. Ghusoon Mohsin Ali
Problems Q1: Calculate the drift current density in silicon sample. If T=300 K, Nd=1021/m3, Na=1020/m3V, µn=0.85m2/V.s, µp=0.04m2/V.s, E=35 V/cm.. (Ans: 6.8×104A/m2). Q2: A cubic doped n-type silicon semiconductor sample at T=300 K, µn=0.85m2/V.s, R=10kΩ, J=50A/cm2 when 5V is applied. Calculate ND. . Q3: Determine 10mm×1mm×1mm sample, a magnetic field 0.2wb/m2 is superposed on applied voltage 1mV. Calculate Hall voltage if electrons density 7×1021/m3μn=0.4 m2/Vs.

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