Chapter 3 - Carriers in Semiconductor

ECE 4339
Han Q. Le (copyrighted) U. of Houston

Part 2

0. Physical constants or frequently used formulas

6. Fundamental relations in carrier concentration

6.a Review: Donors and acceptors

    Te donor in GaAs
http://www.mse.berkeley.edu/groups/weber/research/stm.html

http://demonstrations.wolfram.com/DopedSiliconSemiconductors/
Contributed by: S. M. Blinder

6.b Review: Thermal excitation

Discussion of atomic or molecular gas thermal behavior.
Maxwell-Boltzmann distribution: (see demo/discussion of the statistics in class using phet simulation).
We use , Boltzmann’s constant, in unit of eV/K:    (eV/K)

http://phet.colorado.edu/en/simulation/gas-properties

http://physics.weber.edu/schroeder/md/

App Demo: Electron-Hole Thermal Excitation

6.1 Fermi-Dirac statistics

- Instead of classical Maxwell-Boltzmann distribution (which is for distinguishable particles or classical particles), electrons and other fundamental particles obey quantum statistics for indistinguishable particles.

- For even-spin particles (S=0,1,2..), they obey Bose-Einstein statistics. For odd-spin particles, (S=1/2, 3/2,...) (per Pauli exclusion principle), they obey Fermi-Dirac statistics.

Here, we deal with electrons, and hence, we use Fermi-Dirac statistics:

which specifies the probability that states of energy are occupied at a given temperature.

App Demo: Fermi-Dirac distribution

The quantity is a parameter that is a charactistic of a particular system and referred to as Fermi energy level or, for short, just Fermi level.
Note the asymptotic approximation of Fermi-Dirac statistics to Maxwell-Boltzmann for energy far above the Fermi level and much larger than :
                                        for

6.2 Density of states

Review from Pt 1, section 3.3

Concept analogy: How many apartments are available for occupancy at a certain height level?

How many quantum states are available for an electron to occupy at a certain energy level?

Density of state D[E] is a function that determines the number of quantum states available for electrons to occupy at energy level E per unit volumn.
It is a function of the band structure. For isotropic parabolic band, the DoS function is:
                                                   
where is the band edge energy. Usually it is the band gap if we take the energy origin as the valence band. We'll learn more about this in Chapter 4.
To express the function above in its natural unit:
                                             
where                                            and  
We substitute:                      
                                             
                                             
                                             
We can do a similar conversion, except that we use electron rest mass rather than effective mass. Then:
                                             
We see that the unit of density of states is indeed   

For numerical calculation, we can use the unit  
Below is an example:

Density of states

App Demo: 3D Density-of-state of isotropic parabolic bands

Analogy of different e and h effective mass: tall skinny apartment building vs. wide large apartment building.

Also, the number of units may vary vs. floor level.

6.3 Carrier concentration and Fermi level

Having a building with many floors and apartment doesn’t mean that all units are occupied. What is the total number of occupant units for a building? To answer, we must know which apartment is rented and which one is not.
Suppose someone provides us the following information:
The number of units for the floor is .
The percentage of occupied units for the floor

Example: the building has 5 floors. The information is as follow:
          

What is the formula to calculate the total number of occupied units?
                                                   

6.3.1 Carrier distribution and density - electrons in conduction band

We obtain the carrier distribution vs. energy by taking the product of DoS function and Fermi-Dirac statistics:
                                                               

For a parabolic band in a 3-D system:

Hence, carrier concentration is:
                                                   
                                                     

Below, you will plot the conduction band density of state, the Fermi distribution, and their product to obtain the electron energy distribution

App Demo: Electron Distribution in Conduction Band

6.3.2 Carrier distribution and density - electrons in valence band

Below, you will plot the valence band density of state, the Fermi distribution, and their product to obtain the electron energy distribution

App Demo:  Electron Distribution in Valence Band

6.3.3 Carrier distribution and density - holes (absence of electrons) in valence band

Below, you will plot the valence band density of state, the Fermi distribution, and their product to obtain the hole energy distribution

We see that for the valence band, it is usually full of electrons. That’s not what we are interested in. We are interested in the absence of electrons, in other words, holes. Hence, instead of plotting valence band electron density, we want to plot the hole density. To do that, we subtract   as the distribution hole, because the probability of hole=1- prob of electron:
                              

App Demo:  Electron-Void/Hole Distribution in Valence Band

6.3.4 Carrier distribution and density - both electrons and holes in both conduction and valence bands

Below, you will plot both bands density of state, the Fermi distribution, and their products to obtain the electron and hole energy distribution

App Demo:  Electron and Hole Distribution at Thermal Equilibrium

6.4 Calculation and approximation for carrier density and Fermi level

In the above calculation, we obtain the carrier density with the formula:
                                       
This a bit inconvenient because we have to do numerical integration. Fortunately, we can use some approximation of the integral that makes it easier and with sufficient accuracy.

The approximated relation between carrier concentration (in general, not just intrinsic) and the Fermi level is given by:   
               and  
where and are two constants, called density-of-state function that are NOT the DoS functions we have above, but ONLY some values that allow us to do the approximation. They are specific to the semiconductor of interest:
            
            

Which comes first? carrier concentration or Fermi level?

Conceptually, neither. Each determines the other depending on the case! (If carriers are doped, for example, the concentration determines the Fermi level. If E field is applied to cause band bending, such as in MOSFET, the Fermi level determines the carrier concentration).

Example: Consider the ratio of the two types of carrier density

We can chose the orgin of the energy axis to be right in the middle of the band gap

Now we can solve for Ef

Hence:          
Or:               
where             is the intrinsic Fermi level as we see below.

What is the Fermi level?

It is an energy level in a semiconductor that defines and is defined by the energy distribution of the carrier population. That's why we are interested in this parameter: knowing Fermi level is the same as knowing how the carrier density. Their relationship is constitutional, not defining, in which one quantity causally determines the other.

7. Intrinsic and doped carrier concentration

7.1 Intrinsic carriers and intrinsic Fermi level

We learn that at a finite temperature, even in undoped semiconductors, there are some carriers thermally excited from the valence band to conduction band:

App Demo: Electron-Hole Thermal Excitation

If all carriers are intrinsic, then:
    and    
and:    
Can we find what the intrinsic Fermi level is? Just using the result above with .
But here, we use notation , to indicate that they are intrinsic density, not by doing.

7.1.1 Intrinsic Fermi level

Line by line illustration for the calculation of Fermi level (tutorial in Mathematica):

At T=0:

So, indeed, at absolute 0 temperature, the Fermi level is right at the middle of the bandgap as expect. We can find the intrinsic Fermi level and simplify the results somewhat:

A better-looking formula:

What is the Fermi level?

Where is the intrinsic Fermi level at T=0?  Plot the intrinsic Fermi level for GaAs as a function of temperature from 0 to 300 K.

For GaAs: ;

7.1.2 Intrinsic carrier concentration

Because:
    and    
and:     ,
                 

Thus, the intrinsic carriers are given by:

Another useful formula is:

We can find both the intrinsic Fermi level and intrinsic carrier concentration for any semiconductor at any temperature, if we know the semiconductor intrinsic properties.

7.2 Charge neutrality condition and equilibrium condition

What if the semiconductor is doped?
A key condition is charge neutrality:
                       .
Also: at thermal equilibrium (and low doping density), the rate of carrier spontaneous recombination has to be equal to that of generation. Thus:
                           

Hence, these two equations allow solving for carrier densities.

Created with Wolfram Mathematica 9.0