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I - V characteristics in Reverse Bias
A PN Junction is said to be in Forward Bias when the P-type region (Anode) is made positive with respect to the N-type region (Cathode).
A PN Junction is said to be in Reverse Bias when the P-type region (Anode) is made negative with respect to the N-type region (Cathode).
Let us consider the Forward bias first and examine qualitatively the mode of operation
The holes are required to move from and electrons from .
There are plenty of holes in P-type region and would like to move to N-region via diffusion but are prevented by theelectric field (or the energy barrier) at equilibrium. The drift and diffusion currents cancel each other
Similarly, there are plenty of electrons in N-type region and would like to move to P-region via diffusion but areprevented by the electric field (or the energy barrier) at equilibrium. The drift and diffusion currents again cancel eachother.
The application of forward bias reduces the barrier and the electric field allowing significant electron and hole currentto flow:
The fraction of electrons that are able to cross over to the P-side or the fraction of holes that are able to cross over
to the N-side and contribute to current goes exponentially with the barrier height (remember, )
Current increases exponentially with the applied forward bias.
Reverse Bias:
The holes are now required by the applied bias to move from and electrons from as shown below:
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Although the electric field favors the flow of holes to the P-region, there are very few holes in N-region to begin with!
The number of holes in N-region is , a very small number.
Further, the number of holes is fixed and unaffected by the bias.
Similarly, the number of available electrons in P-region for current flow is very small and unaffected by the appliedbias.
The only thing that the applied reverse bias does is to increase the junction electric field or the barrier height asshown below
The increased electric field does not alter the current flow because the bottleneck is the small number of carriersavailable for current conduction.
Current in Reverse bias is very small and almost constant
Static I-V Characteristics:
The dc current-voltage characteristics of the PN junction diode will be obtained using the semiconductor equationslisted below:
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Assumption (ii) : Depletion approximation
For a forward bias of 0.6V, the electron drift current can be calculated using the results obtained as equal to
As we shall see later, the net electron current flowing through the junction for this device at a forward bias of 0.6V is
Because the drift current( ) is five orders of magnitude larger than the net current, the drift and diffusion
currents would have to be calculated to an accuracy of .001% to obtain a correct estimate of the net electron current!
This makes the estimation of total current via an analysis at the junction virtually impossible!
Let us consider a region for estimation of current which is far from the junction in say N-type semiconductor.
Far from the junction, on the N-side, the current is expected to be primarily an electron current. Any holes which areinjected from the P-side would recombine and disappear away from the junction.
The electron density being constant, the electron current would be primarily a drift current so that
It might appear that this is a very good place for estimation of current because we have just one component and onlyone unknown , the electric field .
However, this electric field is extremely difficult to estimate because of its very small value.
The voltage applied across the diode gets dropped partially across the junction and partially outside it
where the last two terms represent the voltage dropped across the neutral N and P-regions
The bottleneck for current flow in a PN junction is the space charge region where the potential barrier exists. As aresult, is almost equal to the applied voltage
While it is easy to compute the junction voltage fairly accurately, the estimation of residual drops in the neutralregions becomes very difficult.
The two examples discussed earlier illustrate that the choice of position in the PN junction for computation of its I-Vcharacteristics is very important.
As first demonstrated by Shockley, the computation of currents in PN junction diode is best done at the edges ofdepletion region as explained below:
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During the course of the analysis, several assumptions will be made. There are two ways of justifying theseassumptions. One of them is:
(i) Make the assumption(ii) Solve the resulting simplified equations to obtain the current-voltage characteristics(iii) Check that the assumptions made are consistent with the results obtained.
The assumptions made will be consistent only for certain range of currents, so that the range of validity of the modelwill be obtained.
The other approach is to justify the assumptions in the beginning of the analysis, based on available devicecharacteristics. These assumptions would define the range of validity of the obtained model.
We shall follow a mix of these two approaches
Assumption (1): Negligible recombination within the JunctionWe shall justify this assumption using the first approach, namely that the assumption would be shown to be
consistent with the results obtained within certain limits.All the ho;es that are injected at reach the point so that
Similarly all the electrons that are injected at reach the point , so that
This allows the total current to be expressed as :
The total current can be computed by computing the minority carrier currents at the edges of depletion region in N
and P-regions
Assumption (2) : Minority carrier current is largely diffusiveWe shall justify this assumption using the second approach, namely that the validity of this assumption will bedemonstrated prior to analysis. This is described in Appendix A.
The assumption implies :
The task of computing the currents boils down to the computation of minority carrier profiles: p(x) in N-region and
n(x) in P -region.
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The minority carrier profile can be determined by solving the continuity equation with appropriate boundary conditions
For hole density in N-region:
In Silicon, the dominant recombination mechanism is the Shockley-Hall-Read recombination which can be described
by the relation
under low level injection conditions. is the hole recombination lifetime in N-type material.
The hole continuity equation can be re-written as
where has the units of length and as we shall see later is appropriately called the hole diffusion length
Boundary Conditions:
assuming ideal ohmic contact .
Solution:
Similarly for the N-side:
where is called the electron diffusion length.
Boundary conditions:
assuming ideal ohmic contact
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There are two extreme cases:
(i) Wide Base diode:
For this case, the minority carrier densities can be simplified to:
The minority carrier densities decay exponentially with the distance from the junction, with a characteristics decaylength of for holes and for electrons.
It can be shown that the average distance a hole diffuses before recombining is equal to so that it is called the
diffusion length.
The other extreme case is :
(ii) Narrow Base diode:
The minority carrier profile can be simplified to
The carrier densities vary linearly with position now !
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The total diode current for wide and narrow base diodes can be expressed as
Wide base diode:
Narrow base diode:
The task of determining the I-V Characteristics now reduces to finding a relationship between the minority carrierdensities at the edges of depletion region and the applied voltage.
We start with the relation:
where quasi-neutrality
The low level injection assumption invoked earlier can be used here also for simplification. The first obviousconsequence is that
So that the first term on the LHS of the above expression can be neglected.
The second consequence of low level injection, explained in detail in Appendix A is that
for in the N-region and the depletion region
for in the P-region and the depletion region
The quasi-Fermi level on the N-side must coincide with the Fermi level of the metal forming the ohmic contact
to the N-side if an ideal contact with no voltage drop across it is assumed.
Similarly, the quasi-Fermi level on the P-side must coincide with the Fermi level of the metal forming the ohmic
contact to the P-side if an ideal contact with no voltage drop across it is assumed.
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(c) majority carrier drift currents in N and P regions(d) electric field in the N-region(e) minority carrier drift currents. Confirm that they are much smaller than minority carrier diffusion currentscalculated in example 2.1
Solution: We will carry out the solution for the N-region since the solution for P-region is similar. The minority holecurrent in N-region can be written using the results of previous example as:
The hole current is primarily diffusion current and the sum of hole and electron currents is equal to the total current.The electron current on the N-side is therefore simply:
The electron diffusion current can be written as:
Using the concept of quasi-neutrality in the N-region : , so that
The electron diffusion current can therefore be expressed as
The term in the bracket is simply the hole diffusion current which has already been obtained earlier:
The electron drift current can be written as
The low level injection assumption holds true in this case because
so that
An electron mobility of 800 was assumed. Let us calculate the hole drift current at the depletion edge where
there is an electric field of 28.7 mV/cm. The hole drift current is
which is much smaller than the diffusion current component.
Example 2.3 A PN junction diode has the same characteristics as that of example 2.1 except that the thickness ofthe N region The thickness of the P-region remains very long. Calculate the total current flowing
through the diode.
Solution : This is an example of a diode that can neither be considered a fully wide-basediode nor a fully narrow-base diode. On the P-side, the diode is very thick so that we canuse the expression for electron current valid for wide base diodes. Therefore
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as before.
On the N-side so that the narrow-base model can be used
The net current will be 0.44 + 25.2 mA = 25.64 mA.The current is predominantly determined by the narrow base side of the junction.
Example 2.4 Suppose the P-side thickness is also reduced to . Calculate the total current flowing through the
diode again.
Solution: This diode can be modeled as a narrow-base diode. We have already calculated the hole current inexample 2.3 which remains the same. The electron can similarly be calculated as
The net current will be 12.32+25.2 = 37.5 mA
This current is significantly higher than that calculated for wide-base diode in
example 2.1. This illustrates that for comparable doping values, narrow-base diodes provide higher current for thesame bias or equivalently have a smaller turn-on voltage.
The expression for current was derived on the basis of two assumptions:
(i) negligible recombination within the depletion region(ii) low level injection within N and P-regions
These assumptions limit the range of validity of the derived expression. The first assumption determines the lowerlimit, while the second assumption determines the upper limit.
Lower limit: As stated earlier, this is determined by neglect of space charge recombination.
If the hole continuity equation is integrated across the depletion region, we obtain the relation
where
Eq.(80) implies that the correct expression for total current should be
In other words
So as long as , the neglect of SCR recombination is justified
So what we need to do first is to get an estimate for the SCR recombination current:
We shall use a simple model for the Shockley-Hall-Read recombination:
The recombination is assumed to take place via a single deep level at the midgap with equal hole and electronrecombination lifetimes
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Within the depletion region:
where the definition has been used
Noting that either p(x) or :
Because of the exponential dependence of p and n on the voltage (which varies quadratically with x ), the function
is a rapidly varying function of the form shown below:
The recombination rate would have a peak value where the factor attains a maximum value. Since pn =
constant,this would occur when
The sharp variation of U implies that most of the recombination current comes from a small region around the peakvalue. This allows the following simplification to be performed:
In appendix C, this relation is derived more rigorously, where it is also shown that
where is the magnitude of the electric field at the place where peak recombination occurs.
Let us now determine the condition under which
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Substituting the expressions for and derived earlier, we obtain the following condition:
So as long as
recombination within the SCR can be neglected within ~10% accuracy and the ideal diode equation can be used.
For values of current , the diode current would be determined primarily by the SCR recombination current.
If we compare this recombination current with ideal diode current, we can see two major differences:
(i) The ideal diode current increases as while the recombination current increases as
The other way of stating this is that the ideality factor defined as
is unity for ideal diode current and 2 for SCR recombination current.
(ii) The SCR current goes as , while the ideal current goes as for wide base diode and is independent oflifetime for narrow base diodes.
It is for this reason that the SCR current is considered as an index of material quality because the recombinationlifetime is very sensitive to fabrication conditions.
The upper limit for the validity of ideal diode equation is determined by the assumption of low level injectioncondition.
This low level injection condition will first break down for the region which has the smaller doping level. We shallassume, for the sake of discussion, that N-region is the lightly doped region.
The low level injection assumption had allowed the following simplifications to be made:
(i) Minority carrier current is diffusive
(ii) The expression to be simplified as
(iii)
The major departure in I-V Characteristics is caused by the breakdown of (ii) and (iii) relations because they areassociated with an exponential factor.
When , the actual minority carrier density at the depletion edge is about 10 % smaller than that predicted
by the simplified expression.
The (iii) simplification amounted to neglect of the IR drop in the N-region. This drop is negligible when
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The hole continuity equation can be re-written as
The solution of this equation gives:
As before:
The net current can be written as:
Thus the current includes an additional component due to light which represents the current due to flow of carriersgenerated effectively within a distance of one diffusion length of the depletion edge. There would be an opticalgeneration current due to generation within the depletion region as well which can be written as , where W is
the total depletion width. Since depletion width is often much smaller than diffusion length, this component can beneglected. However, in some especially designed PIN diode structures, this component is the dominant current.
Example 2.8 In the analysis of narrow base diodes, it was assumed that the excess carrier density at the contact iszero. This however is true only if the contact can be assumed to be ideal. For practical contacts, the excess carrierdensity may be small but is nonzero. These contacts are characterized by a parameter called surface recombinationvelocity, which for holes can be defined as
(a) Derive an expression for current in a diode using the above boundary condition
(b) Determine the value of SP that is needed for a contact to be considered ideal.Assume a diode with
Solution :
Using the boundary condition at the contact: , we obtain the final expression for current:
s
(b) The first term represents the standard current expression, while the second term represents the modification due
to finite recombination velocity. The equation above shows that as , the expression becomes identical withthat derived for ideal contacts. Thus an ideal contact is one with an infinite recombination velocity. More
practically when the factor , then the contact could be considered almost
ideal. This condition for the values given translates into .
Appendix A
The assumption that minority carrier current is largely diffusive can be shown to be true provided low level injectionconditions prevail within the device:
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Consequences of Low Level Injection:In the N-region:
In the P -region:
We will need another result before we can demonstrate the soundness of our assumption: The regions outside thespace charge region are quasi-neutral so that:
In the N-region:
Similarly,In the P -region:
We will now show that the minority carrier currents can be assumed to be diffusive provided low level injectioncondition prevails. Although this result is general, we shall assume that the N and P regions are of comparabledoping. This implies that the electron and hole currents close to the depletion edge will also be comparable.
We have already shown that electron and hole diffusion currents are comparable and that for low level injection
electron drift current is much larger than the hole drift current in the N-region so that
Appendix B
To show that in the P-region and within the depletion region.
Similarly, in the N-region and within the depletion region.
We shall first consider the neutral P-region and show that for low level injection conditions, the hole quasi Fermi levelcan be considered to be almost flat.
We start with the expression:
Noting that :
where the integral is over the entire length of the neutral P-region.Since
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Noting that the resistance of the neutral p-region is
where A is the device crossectional area, we can obtain
Therefore, as long as the IR drop is sufficiently small, the hole quasi-Fermi level can be assumed to be constant.
How much is sufficiently small ?
As shown in the main text, the expression which results from making the assumption is
Therefore, as long as , the error will be less than 10%.
What is this constraint in terms of injection level?
Since we obtain the constraint:
This constraint would be satisfied if : the low level injection condition!
That hole and electron quasi-Fermi levels can be assumed to be flat within the depletion region can be demonstratedas follows:
As before, we start with the expression:
Noting that within the depletion region
where W is the depletion width
Since,
We obtain
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So as long as , The assumption is fine
Since the depletion width is of the order and diffusion length , the assumption is very well
satisfied.
Appendix C
Substitution of the expressions for electron and hole densities in the expression for current results in
Since most of the recombination occurs within a very narrow spatial region and electric field is a slowly varying
function, it can be taken out of the integral with a value at the position of maximum recombination rate ( ).
Substitution of in the above expression allows the integral to be re-written
The limits of integration correspond to and . Upon Integration , one obtains
Substitution of the limits of integration gives
Using the approximation that , we obtain the final expression for the integral as
The required expression for current can now be obtained by substituting this expression in Eq. (C5)
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