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MATERIALS SCIENCE TUTORIAL: Electronic Materials (ND Broom) Problem 1.
Calculate the conductivity of pure copper at 300 and -50 °C given that its resistivity at room temperature (20°C) is 1.67 x 10 -8Ω.m and α = 0.0068/ °C. Cu
Assume there is no residual component of resistance. (note: ρ =ρo + ρo α ΔT, where ρo is the resistivity at a given reference temperature.)
T)] σ = σoexp(-(Ec-Ed)/k T) Choose the appropriate relationships from those given above and the data from the table shown below to calculate the conductivity of pure germanium at 323, 360, 425, 473 and 500°K. Plot your data of σ vs T and explain any important limitation the curve tells us about intrinsic semiconductors. Note: Boltzmann's constant k = 8.63 x 10 -5 eV/° K. Electronic charge q = 1.6 x 10-19 C. PROPERTIES OF SOME COMMON SEMICONDUCTORS AT ROOM TEMPERATURE (300K)
Energy Gap Electron mobility Hole mobility Carrier Density 2 μe[m / (V.s)] μh[m2 / (V.s) Material Eg (eV) ne (= nh) (m-3) __________________________________ __________________ ___________________________________ ____________________________________ _________________ _ Si 1.107 0.140 0.038 14 x 10 15 Ge 0.66 0.364 0.190 23 x 10 18 CdS 2.59 0.034 0.0018 GaAs 1.47 0.720 0.020 1.4 x10 12 InSb 0.17 8.00 0.045 13.5 x 10 21
Problem 3
Write down the expression for the conductivity of an intrinsic semiconductor. Manipulate this expression to show how the energy band gap for such a semiconductor can be determined graphically from conductivity vs temperature data.
Problem 4.
You are required to characterise a new type of pure (i.e. undoped) semiconductor material. (a). If its conductivity at 20°C is 250/ Ω.m and at 100°C is 1100/ Ω.m, what is its band gap, Eg? (b). Calculate its conductivity at 50°C.
Worked solutions Problem (1)
Use ρ = ρo + ρoαΔT
∴
When ρ
=
resistivity at given reference temperature i.e. 20°c (in this problem)
ρ300°c
= =
1.67 x 10-8+ 1.67x10 -8 x 0.0068 x (300-20) 4.88 x 10-8 Ω m
Conductivity σ = 1/ ρ
∴
=
σ300°c
ρ -50°c
−50° c
4.88x10 −8
=
0.205x 108 Ω-1 m-1
= = =
1.67 x 10-8 + 1.67x10-8 x 0.0068 x(-50-20) 1.67 x 10-8 (1-0.48) 0.868 x 10 -8 Ω m
=
σ
1
=
1 0.868 x10 −8 1.15x 108 Ω-1m-1
Problem (2)
Conductivity σ
=
&
=
σ
nq (µe +µh) - Eg σ e 0 2kt
(1) (2)
since we are considering a pure or intrinsic semi conductor.
From data table Eg for Ge Electron mobility µe = Hole mobility µh = & charge q on electron =
Since the semiconductor is undoped the number of electrons that enter the conduction band equals the number of holes left in the valence band ∴
nĕ = nh = n = 23x10 18 /m3
Using eqn (1) σ 300K
= =
23 x 1018 x 0.16 x 10 -18(0.364+0.190 2.04/ Ω m
We can now use this value of σ300.k to obtain value of equation constant σo If we re-arrange eqn (2) + Eg = σo σ exp 2k T
i.e
σo
= = =
σ300K exp
+ Eg
2k T
300 K
2.04 x exp(0.66/(2x8.62x10 -5x300) 7.1x 105 Ω-1 m-1
(2) cont…/ Now obtain conductivity σ at remaining temperatures of 323K, 360K, 473.K & 500K using eqn (2) Since we now have σo Eg & T − 0.66 σ 323° K = 7.1 x 105x exp 5 2 × 8.62 × 10− × 323 = 5.07 / Ω. m − 0.66 σ 360° K = 7.1x10 5x exp 5 2 × 8.62 × 10 − × 360 = 17.2/ Ω. m − 0.66 = 7.31x105 x e σ 473° K 5 2 × 8.62 × 10 − × 473 = 217/ Ω. m − 0.66 σ 500° K = 7.31 x105 x e 5 2 × 8.62 × 10− × 500 = 335/ Ω. M Now plot data as shown below in friendly “low-tech” format:-
Problem (3 ) Holes and electrons are the charge carriers in an intrinsic semi conductor ∴ use the equation
σ
=
σo exp
=
lnσo -
− Eg
2kT
Take natural log of both sides ln σ
Eg
2kT
which can be expressed in the form of:y = C + mx 1 − Eg where y = ln σ, x = and gradient m = T 2k and intercept on y axis is ln σ0 1 Now plot ln σ vs T In σ gradient (y/x) =
1 T
Energy gap E g
− Eg
2k
(.K)
= - [gradient x 2 k ]
]
Problem (4) Use σ =
σo exp [-Eg/2kT]
(a)
at T at T
= =
20°C (293K) 100°C (373K)
∴
250
=
σo exp [
&
1100
=
σo exp [
(2) divided by (1) gives :1100 = 250 ln
i.e
1100 250
1.482
=
= =
Eg
= =
σ = 250/ Ω m σ = 1100/ Ω m
− Eg
2 × k × 293 − Eg
2 × k × 373
σ
0
exp
σ
0
Eg
[
2k Eg
(1)
]
(2)
Eg
[
1
2k 293
1
2k 293 Eg
]
−
1 373
−
1 373
]
]
[3.413 - 2.681] x 0.732x10 -3
2k 1.482 × 2 × 8.62x10 -5 0.732 × 10 −3 0.35eV
4(b) Using value of Eg from (a) and knowing that σ = 250/ Ω at T = 293K we can now solve for σo − 0.35 250 = ] ∴ σo exp [ 2 × k × 293 + 0.35 and σo = 250xexp [ ] 2 × 8.62 ×10 −5 × 293 = 250xexp [6.93] = 250x1022 = 2.56x105 /Ω m We can now obtain the conductivity at 50oC (323K) − 0.35 = 2.56x105xexp [ ] σ323 2 × 8.62 ×10 −5 × 323 = 2.56x105 x exp [-6.286] = 2.56x105 x 186x10 -3 = 477 / Ω m
