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CHAPTER 8. MOBILITY. 8.1 INTRODUCTION. 8.1 INTRODUCTION. High mobility material has higher frequency response and higher current. Electron-electron or hole-hole scattering has no first-order effect on the mobility. Electron-hole scattering reduces the mobility.
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CHAPTER 8 MOBILITY
8.1 INTRODUCTION • High mobility material has higher frequency response and higher current. • Electron-electron or hole-hole scattering has no first-order effect on the mobility. Electron-hole scattering reduces the mobility. • Minority carriers has ionized impurity scattering and electron-hole scattering, majority carriers has ionized impurity scattering.
CONDUCTIVITY MOBILITY For p-type material. Measure the majority carrier concentration and the conductivity/resistivity is sufficient to calculate the conductivity mobility.
8.3 HALL EFFECT AND MOBILITY
Basic Equations for Uniform Layers or Wafers Schematic illustrating the Hall effect in a p-type sample.
For p-type sample. For n-type sample. When both carriers present.
Temperature and magnetic field dependent Hall coefficient for HgCdTe showing typical mixed conduction behavior. T=220~300K, n=ni2/p, RH is independent of B. T=100~200K, mixed conduction causes RH to Decrease and depends on B. T<100K, p dominates, RH is independent of B.
Hall coefficient and electron density for GaAs. No mixed conduction, and it is independent of B.
The above results are based on the assumption of energy-independent scattering mechanisms.If it is relaxed, the Hall scattering factor r must be Included:
(a) Bridge-type Hall sample, (b) lamella-type van der Pauw Hall sample. R12,34=V34/I12, V34=V4-V3 F is a function of Rr=R12,34/R23,41 For symmetric samples F=1. ΔR24,13 is the difference with and without the magnetic field.
The van der Pauw F factor plotted against Rr. For uniformly doped samples with thickness d, the sheet Hall coefficient is RHS=RH/d and μH=︳RHS︳/ρs, ρs=ρ/d.
Nonuniform Layers Hall measurements give average values, assuming r=1:
The depth profile can be measured by etch and measure method or by a pn junction controlled depletion width. Schottky-gated thin film van der Pauw sample, (a) top view, (b) cross section along the A-A showing the gate two contacts and the space-charge region of width W. The Hall measurement is performed in the region d-W.
The spatial varying Hall parameters is determined by: This is the so called differential Hall Effect, DHE.
Dopant density profiles determined by DHE, spreading resistance profiling, and secondary ion mass spectrometry.
DHE encounters difficulty with large parameter variation in multi layer system. Assume a upper layer has carrier density p1 and mobility μ1, and a lower layer has carrier density p2 and mobility μ2. The Hall effect measured weighted values are:
Multi layers A two layer structure has a upper layer thickness of d1 a conductivity of σ1, and a lower layer thickness of d2 a conductivity of σ2, the Hall constant is given as: At low magnetic field it becomes:
Multi layers At high magnetic field the Hall constant becomes: where RH1 is the layer 1 Hall constant, RH2 is the layer 2 Hall constant, d=d1+d2 and σ is:
Hall coefficient of a p-type substrate with an n-type layer as a function of n1t1 for two magnetic fields. For low and high n1d1 the Hall coefficient is independent of the magnetic field. If the upper layer is more heavily doped or type inverted by surface charges, then the surface Hall parameters are measured (d1 / d) 1 ; R RH1 (d / d1)
Sample Shapes and Measurement Circuits (a) Bridge-type Hall configuration, (b)-(d) lamella-type Hall configuration.
Effect of non-ideal contact length or contact placement on the resistivity and mobility for van der Pauw samples.
Hall sample with electrically shorted regions at the end; (a) top view with the gate not shown, (b) cross section along cut A-A.
Hall sample with electrically shorted end regions, • (b) ratio of measured voltage VHm to Hall voltages VH. • G=VHm/VH. VHm: VH for W/L<3. VH: VH for W/L<3.
MAGNETORESISTANCE MOBILITY • Hall sample, (b) short, wide sample, Hall voltage is nearly shorted; • (c) Corbino disk, Hall voltage is shorted. They can be used to measure the magnetoresistance effect.
Physical magnetoresistance effect (PMR): The sample resistance increases when it is placed in a magnetic field. Because the conduction is anisotropic, involves more than one type of carrier, and carrier scattering is energy dependent. Geometrical magnetoresistance effect (GMR): The charge carrier path deviates from a straight line. GMR = H ξ=(〈τ3〉〈τ〉/〈τ2〉2)2 is the magnetoresistance scattering factor.
Geometric magnetoresistance ratio of rectangular samples versus μGMRB as a function of the length-width ratio.
For Corbino disc. For rectangular samples with low L/W ratio and μGMRB<1 For determining the error in μGMR to be <10%, then L/W must be <0.4.
Drift mobility measurement arrange- • ment and normalized output voltage • pulse (μp=180cm2/V.s,τn=0.67 μs, • T=423K, =60V/cm)
(b) output voltage pulses (μn=1000 cm2/V.s,τn=1μs, T=300K, =100V/cm, N=1011 cm-2), (c) output voltage pulses (μn=1000cm2/ V.s, d=0.075cm, T=300K, =100V/cm, N=1011cm-2). td=0.75us.
TIME-OF-FLIGHT DRIFT MOBILITY This method was first demonstrated in Haynes-Shockley experiment. The pulse shape is : Where N is the electron density in the packet at t=0. The first term in the exponent is drift and diffusion part and the second term is the recombination part.
TIME-OF-FLIGHT DRIFT MOBILITY The minority carrier mobility is determined as The diffusion constant is where the pulse width Δt is measured at half the maximum amplitude.
The lifetime is determined by measuring the electron pulse at td1 and td2, corresponding to two drift voltages Vdr1 and Vdr2. If there is no minority carrier trapping, the output pulse is V01and V02, then If there is minority carrier trapping, the pulse area is Ap, then plot log(Ap) vs. delay time td, the slope should be -1/τn. = I/ qtn
Time-of-flight measurement schematic, (b) output voltage for tt«RC, • The dashed lines indicate the effect of carrier trapping. (c) output voltage • for tt»RC, (d) implementation with a p+πn+ diode, both carriers can be • measured.
From the above system, QN=qN=QA+QC • At t=0 QA=0, at t=tt QA=QN, where tt is the • transit time When QA changes from 0 to QN the external current is:
The output voltage I×R is For tt<<RC For tt>>RC tt can be determined from either case.
Two drift mobility measurement implemen- tations as discussed in the text.
In Fig. a, V1 is applied to the gate and the diode, so there won’t have inversion layer under the gate. V2’s period is 100us, its pulse width is 200ns. The poly-Si resistivity is 10KΩ/ □. Holes drift into the substrate, electrons drift along the surface. The time difference between two peaks gives the drift velocity. The field dependence of the • mobility is obtained by varying V2. The gate voltage dependence of the mobility is obtained by varying V1.
For short channel devices with Rs Solve for ID,sat and drop high order terms Plot 1/ ID,satvs.Lm, gives (1/ ID,sat)int and Lm,int
Substituting (1/ ID,sat)int intoLm,intgives The above equation contains no μeff.
Plotting Lm,intvs. Lm,int /(1/ ID,sat)int has the slope A. Plotting A vs. 1/ (VGS-VT) gives the line with slope S. The saturation velocity is sat=1/ (WeffCox(S-2Rs))
MOSFET MOBILITY There are many kinds of mobility due to : lattice (phonon) scattering, ionized impurity scattering,neutral impurity scattering, piezoelectric scattering, or surface scattering. According to Mathiessen’s rule
Effective Mobility A MOSFET drain current is given as below, the first term is drift current, the second term is diffusion current
Surface conditions for gate-to-channel capacitance measurements for (a) VGS<VT, 2Cov is measured (b) VGS>VTb 2Cov+Cch is measured.