The Efficiency of a p-n Solar Diode as a Function of the Recombination Velocity within the Depletion Layer

doi:10.4236/opj.2012.24040

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Optics and Photonics Journal, 2012, 2, 326-331

http://dx.doi.org/10.4236/opj.2012.24040 Published Online December 2012 (http://www.SciRP.org/journal/opj)

The Efficiency of a p-n Solar Diode as a Function of the

Recombination Velocity within the Depletion Layer

Mohamed K. El-Adawi1, Najla S. Al-Shameri2

1Physics Department, Faculty of Education, Ain Shams University, Cairo, Egypt

2Physics Department, College of Science for Girls, Dammam University, Dammam, KSA

Email: adawish1@hotmail.com

Received September 14, 2012; revised October 16, 2012; accepted October 30, 2012

ABSTRACT

The role of the carrier’s recombination velocity i

within the depletion Layer of junction solar cell and the ex-

ternal bias voltage across the junction in determining the current density “J” through the cell is revealed. The un-

steady carrier diffusion equation is solved under illumination conditions considering a source spectral function

-pn







The efficiency of the device as a function of i

, ,







is obtained. Computations considering a silicon solar cell

are given as an illustrative example.

Keywords: Efficiency; Diffusion Equation; Recombination Velocity

1. Introduction

The performance of a solar cell has aroused the interest

of many investigators [1-17]. The solar p-n cell is a

semiconductor photovoltaic cell. It is a passive trans-

ducer. It is fabricated such that one region is more highly

doped denoted by region. The density of the

charge carriers in the highly doped region may be of

three orders larger than the other region. This surface is

usually subjected to the incident illuminations (emitter

region). Due to large gradients, diffusion of charge carri-

ers take place, holes from

or np



region diffuse to the n-

region, while electrons diffuse from n-region to P



region. As a result a depletion layer is formed on both

sides of the contact metallurgical surface between both

sides. This layer is of small thickness and is

called as the space-charge region (SCR). This layer con-

tains the positive ions of the donner atoms on one side of

the contact surface and the negative ions of the acceptor

atoms on the other side, and thus an electric field is built

and one gets what is called the built-in-voltage



1μm







bi . It

is also called the contact potential or the barrier potential.

The direction of the electric field within the depletion

layer will be from the N-region to the P-region.

At equilibrium the net current (the sum of the diffusion

currents and the drift currents) through the depletion

layer must be zero. Now if the cell is subjected to an ex-

ternal reverse voltage bias, the established external field

will strengthen the internal one, and less current density

passes through the depletion layer and vice versa [18].

This bias voltage disturbs the thermal equilibrium state

of the device. When light strikes the highly doped sur-

face, the absorbed quanta excite the bound electrons and

electron-hole pairs are produced that move in all direc-

tions within the crystal [2]. The electron-hole generation

process is accompanied with recombination processes.

Now if the bias voltage is switched off, the built-

in-voltage will change towards its equilibrium value,

through a recombination process between the electrons

and the holes during the decay of the external voltage [3].

The equilibrium state will be restored within a time in-

terval



called as the relaxation time or it is defined as

the minority carrier life time .It is worth to note that the

electric potential across the depletion layer controls its

electric resistance [4]. Different factors affect the charge

transport properties within the cell, such as the electric

potential across the device, the recombination velocity

between the charge carriers. The most important factor is

the doping level [5,6]. This factor can be controlled

through the fabrication technology. These factors affect

the current density passing through the cell and thus

change its efficiency. Different trials are oriented to

study the performance of the solar cell through the study

of the recombination velocity between the charge carri-

ers.

With this respect one finds in principal two trends

namely:

M. K. EL-ADAWI, N. S. AL-SHAMERI 327

1) The first trend does accept the mechanism where

recombination occurs principally at one end surface of

the semiconductor device (usually it is the highly doped

one). In such a case the coordinate of such a surface is

taken as the origin x = 0, and a boundary condition ex-

pressing the charge continuity at this surface is given

[18]. Such a trend accepts also the study of this perform-

ance considering the collection efficiency of the base, the

emitter and the depletion layer [1,2,7-12]. It is shown

that the normalized surface recombination velocity de-

pends mainly on two parameters; these are the normal-

ized scanning range and the normalized depth of the gen-

eration volume (that is subjected to the incident light).

2) The second trend accepts the mechanism where an

effective interface recombination velocity i

that oc-

curs principally within the depletion layer at the metal-

lurgical interface [3,4,13,14]. Indeed, the effect of the

characteristics of the space charge region and the proc-

esses taking place within this layer has rarely been con-

sidered [3,9]. El-Adawi et al. [15] studied theoretically

the characteristics of the depletion layer. As a result, the

dependence of its thickness and capacity on the doping

ratio and the applied bias voltage is revealed. It is

worth to note that a restriction on the doping ratio

is also obtained [15]. A novel method [16] to estimate

experimentally the thickness of the depletion layer

is introduced.



6.7 μm



The main objective of the present article is to establish

a relation between the recombination velocity at the met-

allurgical interface within the depletion layer and the

current density which in turn affects the efficiency of the

solar cell. The unsteady carrier diffusion equation is

solved under illumination conditions.

2. Derivation of the Basic Equations

Consider a solar device (Figure 1), subjected to

incident solar flux

-pn









and a bias voltage a. For the

unsteady state, the diffusion equation (after switching off

the bias voltage) is written for the minor charge carriers

in the form:











 

nxtn

nxtnDt

nxtnGx







 





(1)

where



,nxt



m, the concentration of the minor charge carriers,

, the concentration at equilibrium,





m.

n, is the intrinsic carrier,

Base

SCR

Figure 1. A model for the considered cell.

N, is the concentration of the acceptor atoms,



, the recombination life time (sec) , the diffusion

coefficient

sec











,Gx



, is the source function de-

fined as [1]







 

 

,1exp

exp

GxR x



 

 

  

 (2)

where,













secm

the incident solar photon flux [17].







1

m absorption coefficient.

R, the reflection coefficient at the front surface.







 

 



Equation (1) is subjected to the following conditions:











nxtn

at xDt

snxt n





 





0, 0

0 ,0,

exp ii

at xtnx t

nkT











(ii) is a starting (initial) condition.





,0 iii

at xWnx tn





where x = 0 is an arbitrary plane in the depletion layer

, the recombination velocity between the charge carri-

ers at the boundary x = 0.

W, is the width of the base region.

V is the applied bias voltage.

Let the solution of Equation (1) be in the form:

 

,,exp

nxtnvxt







 







(3)

Substitute Equation (3) into Equation (1) to get:









,,,

1exp

vxtvxtG xt

Dt D





 

 





(4)

The Fourier separation of variables method is used to

find the solution of the homogeneous part. This is ob-

M. K. EL-ADAWI, N. S. AL-SHAMERI

328

tained in the form:





,exp exp



tA Dtx



 (5)

where, ,

 are parameters.

While the particular solution can be obtained using the

inverse differential operator.

Equation (4) can be rewritten in the form:





exp

1exp























(6)

This gives the solution in the form:

 

,exp

Vxt D













 (7)

Thus, the general solution can be written in the form:



,exp exp

,exp

tA Dtx



 















(8)

Substituting





into Equation (3) one gets the

required expression for n(x, t) in the form:





,expexp 1

nxtnAtxD





 



(9)

where,



 (10)

To find ,

 let us apply the boundary conditions.

This gives:









exp 1

in n

sD D

 





 

 





(11)





ni i

Df D

 

 



 







(12)

where,

exp 1

fn kT





















(13)

Finally, one gets the solution in the form:



,e ee

nxtfD









 



 







(14)

where,







,,nxtnxtn 

The boundary condition (iii) makes it possible to get

the equation for in the form:











 (15)

where,

011

















 (16)

Discussing the order of magnitude of different physi-

cal quantities included in expression (16) one can get the

following results:





φφ



φφ

This gives:





 (17)

Equations (15) and (17) are very important expressions

since they establish a relation between the recombination

life time and the recombination velocity for the given

parameters.

3. The Efficiency

In order to estimate the efficiency, one has to compute

the charge current SC

according to the relation:



SC nn

nxt

JJqD



 

is obtained in the form:



exp

nn n

qD x

qD Gx

 



 











 





(18)

The efficiency



is expressed through the relation:

OC SC

sc in

FV J



 (19)

where,

FF the fill factor.

V the open circuit voltage.

the short circuit current.

in the input solar power absorbed at the front surface

of the solar device.

The open circuit voltage is given as [18].

ln 1

OC J

VqJ













(20)

where,

1.38 10



 is Boltzmann constant.

M. K. EL-ADAWI, N. S. AL-SHAMERI 329

,TK is the absolute temperature.

Jm is the diode saturation current density.

1.6 10Cq

 is the charge of an electron.

The value of 0

is expressed as [19]

0exp g

JAT kT











(21)

where, A is the ideality factor. It is taken as unity for

simplification.

E is the energy gap expressed as [20].

 

ET ETb



 (22)

where, a and b are parameters.

4. Computations

As an illustrative example, computations for a silicon p-n

solar cell are given concerning the above mentioned

functions.

For a silicon solar cell [20]:

4.7310eV Ka

 ,

636bK



01.17eV

E,

300TK

The following values for further parameters are also

considered [1,17,21]:



421

10 319

10.678, D32.310, 810m,

sec

n110m, 710

msec









 

 

1) The recombination life time as a function of the re-

combination velocity is computed first with “W” as a

parameter, then for a

V as a parameter. The obtained

results are illustrated graphically in Figures 2 and 3. It is

clear that as the recombination velocity increases the

recombination life time decreases.

2) The relation between





,nxt

Volts,

and “x” for follow-

ing parameters: a

V0.40 20msec

s



ustrated graphically in Figure 4.

It is clear that the function

and

0.41 10sec



, is ill





,nxt es with “x”

through the cell.

decreas

3) The current density “J” and the efficiency



computed. The following values of the applied voltage

a are considered as parameters: 0.51, 0.52, 0.53, 0.54

volts.

The obtained values are given in Table 1 and are illus-

trated graphically in Figure 5.

5. Conclusions

The obtained results reveal that:

020 40 60 80100120140

0.5

1.5 x 10-6

recom b i n ation velocity (m /sec )



w=200e-6

w=400e-6

w=600e-6

(sec)

Figure 2. A relation between the recombination life time

and the recombination velocity for “W” as a parameter.

02040 6080100120140

7x 10-6

rec om bi nat i on veloc i t y (m/s ec)



V a=0.40v

V a=0.42v

V a=0.44v

(sec)

W = 200 microns

Figure 3. A relation between the recombination life time

and the recombination velocity for as a parameter.

1) The recombination velocity i

does affect the cur-

rent density through the depletion layer. It decreases with

the increase of i

. This in turns leads to the decrease in

the efficiency.

2) Taking the bias voltage a

V as a parameter. One

finds that for a certain recombination velocity the applied

voltage has positive effect on the efficiency.

The efficiency increases with since

VSC

in-

creases with .

M. K. EL-ADAWI, N. S. AL-SHAMERI

330

20 4060 80100

recombination velocit y (m/s ec)



va=0.54v

va=0.53v

va=0.52v

va=0.51v

0246 8

x 1 0-4

14 x 1019

x(m)

n( x,t),(1/m3)

0.4volts

V

Figure 5. The efficiency



of a silicon solar cell as a func-

tion of the recombination velocity .

Figure 4. A between “x” through the cell.



,and nxt

Table 1. The current density “J” and the efficiency “η” as a function of the recombination velocity si (m/sec) with the applied

voltage as parameter.

V = 0.51 volts a

V = 0.52 volts a

V = 0.53 volts a

V = 0.54 volts



msec



J %







J %







J %





J %



20 2.53 6. 3.68 8.8 5.29 13 7.5 19

40 1.77 4.2 2.6 6.2 3.83 9.2 5.63 14

60 0.85 1.9 1.26 2.9 1.85 4.3 2.73 6.5

80 0.35 0.8 0.51 1.1 0.75 1.7 1.1 2.5

100 0.13 0.3 0.19 0.4 0.28 0.6 0.41 0.9

3) For computation revealed that the recom-

bination life time is not affected by the width “w” of the

cell. But it is positively affected by the applied voltage.





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