24 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         

Volume 1, Issue 1, page 24-29 

Submitted  : September 11, 2018  
Accepted  : October 20, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19547 

Built in Potential of a-Si:H Based p-i-n Solar Cell at Different Energy 
Gap of Intrinsic Layer  

 

Rahayu Setyo Yuniarsih
1 
, Endhah Purwandari

1,a
, Misto

1
, Edi Supriyanto

1
 

and Supriyadi
1
  

1
Department of Physics, Faculty of Mathematics and Natural Sciencs, University of Jember, 

Jalan Kalimantan No 37 Jember 68121, Indonesia 

a
endhah.fmipa@unej.ac.id 

 
Abstract. The photovoltaic process inside a solar cell can be described using the distribution of 
electrostatic potential in the material. In this paper, the magnitude of the electrostatic potential of the solar 
cell for the p-i-n junction type is analyzed as the built in potential due to the diffusion activity of electrons 
and holes. The magnitude of the electrostatic potential is obtained by solving the Poisson and Continuity 
equations, which are applied to a-Si: H based materials. The difference in built in potential at the p-i and i-
n junctions is obtained as a function of the energy gap of the intrinsic layer. 

Keywords: Solar Cell, Electrostatic Potential, Built In Potential, Energy Gap 

Introduction 

Hydrogenated amorphous silicon (a-Si:H) based solar cells having p-i-n structure have been 
widely investigated for use as low-cost solar cells [1]. They have also been made using a simple 
method and an abundance of materials [2]. As an electric power source, a-Si:H p-i-n solar cells 
requires improvements in collection efficiency and stability. The performance parameters are 
determined by open-circuit voltage (Voc), short-circuit current (Isc), fill factor (FF) and efficiency 
(η). One of the factors that can increase the short circuit current density is the number of charge 
carriers generated in the device, due to the photogeneration mechanism.The more increased 
the number of charge particle generated, the more enhanced the short circuit current produced.  
 
The greatest number of photogeneration process are created in depletion area, where the 
intrinsic layer plays a major role in the occurrence of the process. Built-in potential generated 
two conjunctions of intrinsic layer and the two outer layer determines the width of depletion 
area. The energy gap possessed by the intrinsic layer affects the photogeneration rate 
produced by the layer. In this paper, various number of energy gap of intrinsic layer have 
investigated to analyze their effect to the built in potential. 
 
Theoretically, transport mechanism of charge carriers in semiconductor devices is well 
described using Poisson and continuity equations [3]. Their numerical solution defines the 
carrier charge of Semiconductor as function of potential electrostatic at operational temperature. 
Having known the electrostatic potential at the point of the junction in p-i-n solar cell, we can find 
out the magnitude of the built in potential in it. The study of hydrogenated amorphous silicon-
based solar cells in modelling area  had investigated since early 1980's. In one-dimensional 
structure, the conversion mechanism of solar cells has been analyzed by Hack and Shur [4], 
Tareto et al. [5] Zhu et al. [6], Kabir et al. [7], Usman [8] and Purwandari [3]. 
 



  
 
 
 
 
 

25 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         

Volume 1, Issue 1, page 24-29 

Submitted  : September 11, 2018  
Accepted  : October 20, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19547 

The measurement of built in potential has been experimentally measured by Olthof using 
ultraviolet photoemission spectroscopy (UPS) method. He had investigated built in potential in 
p-i-n homojunction of pentacene.The results showed that the potential in p-i junction was 
greater than i-n junction [9]. In this research, the built in potential calculation has been carried 
out using a numerical approach based on the finite element method. The ease of application of 
the finite element method is a suitable choice for theoretical studies of solar cells. The finite 
element method is used to analyze the built-in potential in solar cells with the p-i-n connection 
type for variations in the energy gap and output voltage.  

Methods 

A single junction p-i-n amorphous silicon solar cells was presented in one dimensional 
physically-based computer simulation using Finite Elemen Method Laboratory (Figure 1). The 
simulator was applied to the analysis of a p-i-n single junction a-SiC:H/a-Si:H/a-Si:H solar cell. 
The lengths of the p, i and n layer were set at a thickness of 0.015 µm, 0.55 µm and 0.03 µm 
respectively. The energy gaps of the p and n layer were 2.36 eV and 1.7 eV. In this simulation, 
the effects of energy gap of intrinsic layer to built in potential were analyzed by varying them 
from 1.70 to 1.74 eV. The extracted features shown in Table 1 are used as the input parameter 
of simulation. 
 
 

 
Figure 1. One dimensional structure of single junction p-i-n a-Si:H. Boundary 1 and 4 are interface 
between metal and device, where boundary 2 represents the interface between layer p and i and 

boundary 3 represents the interface between layer i and n 

 

We have used the modified Poisson and continuity (for electrons and holes) equations [8]. They 
were modelled to take account the potential electrostatic considering doping concentration, free 
charge carrier and its trapped component in amorphous structure. The boundary condition 
applied to the structure involve the contact and non contact device area to metal. We have 
applied Dirichlet boundary condition to define the magnitude of potential and charge carrier 
concentration which passed through the junction of p and n layers to the metal contact and also 
for intra-connection between p-i-n layers. Its electrostatic potentials of the material were 
calculated as the sum of the external voltages and the logarithmic energy equation which 
corresponds to changes in dopant concentration [8]. For other boundaries, Neumann condition 
have applied [10]. 
 



  
 
 
 
 
 

26 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         

Volume 1, Issue 1, page 24-29 

Submitted  : September 11, 2018  
Accepted  : October 20, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19547 

Table 1. Input Parameters of simulation 

Parameters Value 

Permitivity (  ) 11.8 F/cm 

Temperature (T) 300 K 

flux of photon (  ) 10
17

 cm
-2

s
-1

 

Transmission factor (P) 0.71 

Light absorbtion coefficient of a-Si (α) 22222 (cm
-1

) 

Intrinsic concentration (ni) 6.019 x 10
10

 cm
-3

 

Donor concentration (ND) 8.8 x 10
17

 cm
-3

 

Acceptor concentration (NA) 1 x 10
17

 cm
-3

 

Electron diffusion (Dn) 40 cm
2
/s 

Electron diffusion (Dp) 4 cm
2
/s 

Rasio between ionize and neutral charges (c)   50 

Thermal velocity by neutral bonding (vthσN) 10
-11

 cm
-3

s
-1

 

Minimum density at donor and acceptor (gmin) 10
16

 cm
-3

 eV
-1

 

Donor energy (ED) 0.088 eV 

Acceptor energy (EA) 0.053 eV 

minimum energy of conduction band (Emc) 0.65 eV 

Energy of valence band (Ev) 0.15 eV 

Mesh 0.00145 

 

Result and Discussion 

The accumulation of charges in the junction area creates an electrostatic potential. The 

simulation results are electrostatic potential data on all parts of the device. The performance of 

the potential data for a p-i-n junction device is shown in Figure 1 and presented for a voltage of 

0 V where the band gap energy of intrinsic part is 1.7 eV. 

 

From both ends of the device terminal, the potential difference is almost 0 V. The curve 

produces the high increment when the program was taken into account for p and i layers. The 

dopant addition in these layers causes the increase potential, based on the Poisson equation, 

while the intrinsic semiconductor have contributed to change of electrostatic potential at the 

middle part of the device. To observe the effect of difference of energy gap applied to the intrisic 

layers, we need to determine all potential data produced at the junction layers.  

 

 



  
 
 
 
 
 

27 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         

Volume 1, Issue 1, page 24-29 

Submitted  : September 11, 2018  
Accepted  : October 20, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19547 

 
Figure 1. Profile of electrostatic potential of a-Si:H p-i-n junction solar cell with the thickness of 
0.015 µm /0.55 µm/0.03 performed at band gap energy of intrinsic part of 1,7 eV and terminal 

voltage of 0 V 

 

 
Figure 2. Built in potential at the p-i junction when the energy gap of the intrinsic layer is 

varied by 1.70 eV, 1.72 ev and 1.74 eV 

 

-11,50

-11,00

-10,50

-10,00

-9,50

-9,00

-8,50

-8,00

-7,50

-7,00

1,70 1,72 1,74

B
u

il
t 

in
 P

o
te

n
ti
a

l 
(V

) 

Band gap energy (eV) 

Va = 0 V

Va = 0.1 V

Va = 0.2 V

Va = 0.3 V

Va = 0.4 V

Va = 0.5 V



  
 
 
 
 
 

28 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         

Volume 1, Issue 1, page 24-29 

Submitted  : September 11, 2018  
Accepted  : October 20, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19547 

The data of built in potential obtained by the simulation perform that all band gaps of intrinsic 
layer are negative numbers. These has a good agreement that negative charges were 
accumulated at the junction of p and i layers. At energy gap of 1,72 eV, the increasing built 
potential takes place only on terminal output of 0V. The highest built in potential were supported 
by the number of carrier charge. But this condition were not staying longer when the energy 
rising up to 1.74 eV.  

 

 
Figure 3. Built in potential at the i-n junction when the energy gap of the intrinsic 

layer is varied by 1.70 eV, 1.72 ev and 1.74 eV 

 

All built in potential data is positive, which means that the hole dominates the charge carrier in 
the i-n junction area. Almost all potential data decreased when the energy gap of layer i was 
increased by 1.72 eV. When the energy gap of layer i is increased to 1.74 eV, the built in 
potential calculation for all output voltage data has decreased, except for the voltage of 0.2 V.    

Conclusion 

The electrostatic potential distribution of amorphous silicon based solar cells, with a p-i-n 
linkage structure, has different profiles when analyzed at various output voltages. Negative 
potential performs electron charges accumulated at the junction of p and i layers, where its 
positive number represent the hole charges at i-n junction. The application of different energy 
gaps in the i-layer has a significant effect on the built-in potential of the two junctions (p-i and i-
n). The device has a significant change in built in potential when the output voltage is 0 V. When 
the energy gap of layer i is 1.72 eV, the device has the highest potential and then drops 
drastically at 1.74 eV. A decrease in built in potential due to an increase in the energy gap of the 
intrinsic layer occurs at all output voltages, except at 0.3 V. 

 

0,00

0,20

0,40

0,60

0,80

1,00

1,20

1,70 1,72 1,74

B
u
il
t 

in
 P

o
te

n
ti
a
l 
(V

) 

Energy gap (eV) 

Va = 0 V

va = 0.1 V

Va = 0.2 V

Va = 0.3 V

Va = 0.4 V

Va = 0.5 V



  
 
 
 
 
 

29 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         

Volume 1, Issue 1, page 24-29 

Submitted  : September 11, 2018  
Accepted  : October 20, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19547 

References 

[1]  R Kaplan and B Kaplan, 2001, Built-in Potential Measurements in a-Si:H p-i-n Solar Cells, 
Turk J Phys, volume 25, pp 375 – 383. 

[2]  A Siregar, 2011, Pengaruh Konsentrasi Ekstrak Antosianin Pomegranate Fruits (Buah 
Delima) sebagai Dye-Sensitizer terhadap Efisiensi Sel Surya jenis DSSC (Dye Sensitized 
Solar Cell,. Jakarta, Universitas Pendidikan Indonesia 

[3]  E Purwandari and T Winata, 2012, Optimasi Tekanan Deposisi dalam Simulasi Efisiensi Sel 
Surya, Gradien, volume 8(1), page 716-721. 

[4]  M Hack and M Shur, 1985, Physics of Amorphous Silicon Alloy p-i-n Solar Cells. J. Appl. 
Phys., volume 58(2), page 997-1020. 

[5]  K Taretto, U Rau, and J H Werner, 2003, Closed-Form Expression for The Current/Voltage 
Characteristics of pin Solar Cells, Appl. Phys. A., volume 77, page 865-871. 

[6]  Zhu, Kalkan, Hou, and Fonash, 1999, Application of AMPS-1D for Solar Cell Simulation. 
The America Institute of Physics, volume 4(1), page 309-314. 

[7]  Kabir, Shahahmadi, Lim, Zaidi, Sopian, and Amin, 2009, Amorphous Silicon Single-
Junction Thin-Film Solar cell Exceeding 10% Efficiency by Design Optimization, 
International Journal Photoenergy, (460919)7. 

[8]  I Usman, 2006, Penumbuhan Lapisan Tipis Silikon Amorf Terhidrogenisasi dengan Teknik 
HWC-VHF-PECVD dan Aplikasinya pada Sel Surya, Disertasi, Bandung: ITB. 

[9]  Olthof, Kleeman, Lussem, and Leo, 2010, Built-in Potential of a Pentacene p-i-n 
Homojunction Studied by Ultraviolet Photoemission Spectroscopy, Matter. Res. Soc. Symp. 
Proc., 1270-(2), 09-49. 

[10] E Purwandari and T Winata, 2013, Efficiency Calculation Analysis of A-Si:H Solar Cells for 
Determination of Optimum Filament Temperature in Material Deposition, Jurnal Ilmu Dasar, 
volume 14(1), page 29-32.