Photovoltaic device

A photovoltaic device including a substrate, a first electrode layer provided on the substrate, a photoelectric conversion layer provided on the first electrode, and a second electrode layer provided on the photoelectric conversion layer. A discontinuous interfacial layer is provided at at least one of the interfaces between a first conductivity type layer and a photoactive layer provided in the photoelectric conversion layer, between the photoactive layer and a second, opposite conductivity type layer of the photoelectric conversion layer, and between the photoelectric conversion layer and the second electrode layer. The at least one interface provided with the discontinuous interfacial layer may be so textured that portions of the interface not provided with interfacial layers project toward the substrate.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a photovoltaic device for converting light 
energy to electrical energy. 
2. Description of the Background Art 
Among the factors for evaluating characteristics of a photovoltaic device, 
photoelectric conversion efficiency shows the degree of conversion of 
light energy to electrical energy. 
In order to improve such photoelectric conversion efficiency, studies have 
generally been made relating to (1) optimizing the thickness of the 
semiconductor layer contributing most to photoelectric conversion and (2) 
reducing the electrical resistance of the electrodes. 
Further, the shapes of the employed materials have also been studied for 
improving the photoelectric conversion efficiency. In other words, studies 
have been made of the texture morphology of interfaces between respective 
layers forming a photovoltaic device for improving the photoelectric 
conversion efficiency. 
FIG. 13 is a sectional view showing a conventional photovoltaic device. 
Referring to FIG. 13, a transparent front electrode 2 which is formed by a 
transparent conductive film of tin oxide or the like is provided on a 
transparent substrate 1 of glass or the like. A photoelectric conversion 
layer 3 is provided on the front electrode 2. The interface 2a between the 
photoelectric conversion layer 3 and the front electrode 2 has a textured 
contour. The photoelectric conversion layer 3 is mainly formed of a p-type 
semiconductor layer 3p of an amorphous silicon carbide, a photoactive 
layer 3i of intrinsic amorphous silicon, and an n-type semiconductor layer 
3n of amorphous silicon. In this photovoltaic device, a buffer layer 3b of 
amorphous silicon carbide is provided between the p-type semiconductor 
layer 3p and the photoactive layer 3i for improving interface 
characteristics. A back electrode 4 of aluminum or chromium is provided on 
the photoelectric conversion layer 3. 
This photovoltaic device operates as follows: 
Light 5 which is incident upon the photovoltaic device through the 
transparent substrate 1 passes through the front electrode 2, to enter the 
photoelectric conversion layer 3. At this time, the light 5 is so 
scattered by the textured surface 2a of the front electrode 2 that its 
traveling direction is bent by such scattering even if the light is 
incident perpendicularly to the surface of the transparent substrate 1. 
As a result, the light 5 obliquely passes through the photoelectric 
conversion layer 3, whereby the optical path length thereof is so 
increased that a large amount of the light is absorbed by the 
photoelectric conversion layer 3. With respect to long wavelength light 
which is hardly absorbed in general and requires a relatively large 
optical path length for absorption, the amount of absorption is so 
increased as to improve the photoelectric conversion efficiency of the 
photovoltaic device. 
IEEE Electron Device Letters, vol. EDL-4, No. 5, May 1983pp. 157 to 159 
describes in detail such a photovoltaic device which is provided with a 
front electrode 2 having a textured surface 2a. 
In order to improve the degree of scattering in the aforementioned 
structure utilizing scattering caused by the textured shape of the 
interface 2a between the front electrode 2 and the photoelectric 
conversion layer 3, however, it is necessary to increase the thickness of 
the front electrode 2. The increase in thickness leads to increase in 
light loss based on light absorption by the material of the front 
electrode 2. Therefore, such a structure must be designed taking into 
account the balance between improvement of characteristics caused by light 
scattering and loss by light absorption. 
In addition to the aforementioned optical path length, photoelectric 
conversion efficiency is influenced by recombination of carriers in the 
interface between semiconductor layers. In a photoelectric conversion 
layer, charge carriers are recombined at interfaces between semiconductor 
layers and the photoactive layer. Since p-type and n-type semiconductor 
layers are generally inferior in film quality to an intrinsic 
semiconductor layer of amorphous silicon, charge carriers such as 
electrons are easily recombined at interfaces formed by such semiconductor 
layers. In a photovoltaic device including such interfaces, therefore, 
carriers disappear to reduce photoelectric conversion efficiency. Such 
recombination of carriers is also caused at a junction between different 
types of materials, such as an interface between a metal back electrode 
and a photoelectric conversion layer, for example. 
SUMMARY OF THE INVENTION 
An object of the present invention is to provide a photovoltaic device with 
increased optical absorption and decreased recombination of charge 
carriers, thereby improving photoelectric conversion efficiency. 
A photovoltaic device according to the present invention comprises a 
substrate, a first electrode layer which is provided on the substrate, a 
photoelectric conversion layer which is provided on the first electrode 
layer by successively stacking a first conductivity type layer, a 
photoactive layer, and a second opposite conductivity type layer, and a 
second electrode layer which is provided on the photoelectric conversion 
layer, a discontinuous interfacial layer being disposed at at least one of 
the interfaces between the first conductivity type layer and the 
photoactive layer, between the photoactive layer and the second, opposite 
conductivity type layer, and between the photoelectric conversion layer 
and the second electrode layer. 
According to the present invention, the at least one discontinuous 
interfacial layer is provided at the interface between the photoactive 
layer and either the first or second conductivity type layer, to reduce 
the contact areas of the photoactive layer and the first and/or the second 
conductivity type layer. Such area reduction leads to a reduction in the 
degree of recombination of photo-generated carriers at the interfaces, 
whereby a larger amount of photo-generated carriers can be outputted with 
no recombination. Also, when such interfacial layers are provided between 
the photoelectric conversion layer and the electrode layer, it is possible 
to further reduce the degree of recombination of the photo-generated 
carriers, thereby improving photoelectric conversion efficiency. 
The percent of the interfacial area occupied by such interfacial layers is 
preferably 30 to 70%, more preferably 50 to 70% of the overall interfacial 
area. 
The interfacial layers are preferably several .ANG. to 1 .mu.m in 
thickness. 
When the present invention is applied to a front side incidence type 
photovoltaic device, the substrate is a transparent substrate, while the 
first electrode layer serves as a front electrode layer and the second 
electrode layer serves as a back electrode layer, respectively. 
When the present invention is applied to a back side incidence type 
photovoltaic device, on the other hand, the substrate is a non-transparent 
substrate, while the first electrode layer serves as a back electrode 
layer and the second electrode layer serves as a front electrode layer, 
respectively. 
When one of the first conductivity type layer and the second, opposite 
conductivity type layer is formed by a p-type layer, the other one is 
formed by an n-type layer. 
According to the present invention, the material for the interfacial layers 
is not particularly restricted, so far as the layers form no interfacial 
energy levels which trap and recombine charge carriers by coming into 
contact with the photoactive layer and the first or second conductivity 
type layer. For example, silicon dioxide, silicon nitride, or zinc oxide 
may be employed as the material for such interfacial layers. 
According to the present invention, the interfacial layers are not 
particularly restricted in shape but may be provided in the form of films 
or grains. 
According to the present invention, further, a buffer layer may be provided 
in the photoelectric conversion layer. Such a buffer layer may be provided 
between the photoactive layer and one of the first and second conductivity 
type layers. 
According to one of the preferred modes of the present invention, the 
interface provided with the interfacial layers is so textured that 
portions of the interface not provided with interfacial layers project 
toward the substrate. 
In a front side incidence type photovoltaic device employing a transparent 
substrate, at least one discontinuous interfacial layer is provided at the 
interface between the photoelectric conversion layer and a back electrode 
layer, and these interfaces are textured. When the interface between the 
photoactive layer and the first or second conductivity type layer has a 
textured shape, the back electrode layer stacked thereon is textured along 
the contour of the interface, whereby the interface between the 
photoelectric conversion layer and the back electrode layer is also 
textured. Whichever interface has a textured shape, therefore, the 
interface between the back electrode layer and the photoelectric 
conversion layer is textured. For light which is incident through the 
transparent substrate, the portion thereof passing through the 
photoelectric conversion layer with no absorption reaches the back 
electrode layer. Since the interface between the back electrode layer and 
the photoelectric conversion layer has a textured shape, this part of the 
light is scattered and reflected back into the photoelectric conversion 
layer. Thus, it is possible to increase substantially the optical path 
length of the incident light for increasing the amount of absorption of 
the light, thereby improving photoelectric conversion efficiency of the 
photovoltaic device. In particular, the absorption of long wavelength 
light, which requires a relatively large optical path length for 
absorption, is increased whereby the photoelectric conversion efficiency 
is improved. 
Also, in a back side incidence type photovoltaic device employing a 
non-transparent substrate, the interface between the front electrode layer 
and the photoelectric conversion layer has a textured shape similarly to 
the aforementioned front side incidence type photovoltaic device. The path 
of light which is incident through the front electrode layer is bent by 
the textured surface of the front electrode layer, whereby the optical 
path length can be substantially increased in the photoelectric conversion 
layer. Also in this case, therefore, it is possible to increase the 
absorption of a long wavelength, thereby improving photoelectric 
conversion efficiency. 
According to one of the preferred modes of the present invention, it is 
possible to reduce carrier recombination by interposition of the 
aforementioned interfacial layers as well as to further increase the 
optical path length in the photoelectric conversion layer, thereby further 
improving the photoelectric conversion efficiency by both effects. 
According to this preferred mode of the present invention, the textured 
shape of the interface can be easily defined by forming interfacial layers 
and thereafter selectively etching an underlayer using the interfacial 
layers as a mask during the manufacturing steps. Thus, it is possible 
readily to manufacture a photovoltaic device having improved photoelectric 
conversion efficiency without complicating the manufacturing steps. 
When the interfacial layers are provided at the interface between a first 
or second conductivity type layer which is closer to the substrate and the 
photoactive layer, it is necessary to etch the first or second 
conductivity type layer to increase the thickness of the first or second 
conductivity type layer to some extent. When a reduction in thickness of 
the first or second conductivity type layer is desired, therefore, it is 
preferable not to carry out such etching step. 
The foregoing and other objects, features, aspects, and advantages of the 
present invention will become more apparent from the following detailed 
description of the present invention when taken in conjunction with the 
accompanying drawings.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
FIG. 1 shows an embodiment of a front side incidence type photovoltaic 
device employing a transparent substrate 11. A front electrode 12 is 
provided on the transparent substrate 11. The transparent substrate 11 is 
made of glass or quartz, while the front electrode 12, which is also 
transparent, is made of tin indium oxide, tin oxide, or zinc oxide. A 
photoelectric conversion layer 13, which is mainly formed by an amorphous 
silicon film, is provided on the front electrode 12. The photoelectric 
conversion layer 13 is formed by a p-type layer 13p which is provided on 
the front electrode 12, a photoactive layer 13i which is provided on the 
p-type conductive layer 13p, and an n-type conductive layer 13n which is 
provided on the photoactive layer 13i. The interface 12a between the front 
electrode 12 and the p-type layer 13p has a lesser texture than the 
interface 2a in the conventional photovoltaic device shown in FIG. 13. The 
interface 13a between the p-type layer 13p and the photoactive layer 13i 
also has a texture. The p-type layer 13p is formed by an amorphous silicon 
carbide film, while the photoactive layer 13i is made of intrinsic 
amorphous silicon and the n-type layer 13n is made of amorphous silicon. 
A discontinuous interfacial layer 14 is disposed at the interface 13b 
between the photoactive layer 13i and the n-type layer 13n. Such 
interfacial layer 14 can be formed by a well known method such as 
sputtering or atmospheric pressure CVD. According to this embodiment, the 
interfacial layer 14 is made of silicon oxide. 
A back electrode 15 is provided on the n-type layer 13n. The back electrode 
15 can be made of a metal such as aluminum or chromium. According to this 
embodiment, the interface 13c between the n-type layer 13n and the back 
electrode 15 is slightly textured due to the texture of the interfacial 
layers 14 formed on the interface 13b. 
According to this embodiment, light 16 which is incident upon the device 
through the transparent substrate 11 passes through the front electrode 12 
and reaches the photoelectric conversion layer 13, and is partially 
absorbed therein. Then the remaining part of the light 16 passing through 
the photoelectric conversion layer 13 is reflected by the interface 13c, 
to re-enter the photoelectric conversion layer 13. According to this 
embodiment, the interface 13c defining the surface of the back electrode 
15 is slightly textured that the light 16 is reflected by its textured 
surface in various directions. Thus, the optical path length of the light 
16 is increased in the photoelectric conversion layer 13, so that a large 
amount of the light is absorbed. 
A comparative sample of a photovoltaic device was prepared in a similar 
manner to the embodiment shown in FIG. 1, except that discontinuous 
interfacial layer 14 was not provided. The back electrode layer 15 of this 
sample had a flat surface. 
A sample of the photovoltaic device shown in FIG. 1 and tile comparative 
sample were subjected to measurement of photoelectric conversion 
efficiency. The photoelectric conversion efficiency of the inventive 
sample was 12.0%, while that of the comparative sample was 11.1%. In the 
inventive sample, the photoelectric conversion efficiency was improved 
conceivably because portions of the interface 13b allowing direct contact 
of the photoactive layer 13i and the n-type layer 13n were reduced in area 
due to the interfacial layer 14 provided at the interface 13b, thereby 
reducing recombination of carriers, and absorption efficiency of the 
reflected light was increased by the textured shape of the surface 13c of 
the back electrode 15. 
FIG. 2 shows a second embodiment of a front side incidence type 
photovoltaic device according to the present invention. Referring to FIG. 
2, a discontinuous interfacial layer 24 is disposed at the interface 23c 
between an n-type layer 23n and a back electrode 25. As to the remaining 
elements, a front electrode 22 is provided on a transparent substrate 21 
and a photoelectric conversion layer 23 is provided on the front electrode 
22, similarly to the embodiment shown in FIG. 1. The photoelectric 
conversion layer 23 is formed by a p-type layer 23p, a photoactive layer 
23i, and the n-type conductive layer 23n. Light 26 is incident this device 
through the transparent substrate 21. 
FIG. 3 shows a third embodiment of a front side incidence type photovoltaic 
device according to the present invention. Referring to FIG. 3, 
discontinuous interfacial layer 34 is disposed at the interface 33a 
between p-type layer 33p and photoactive layer 33i. As to the remaining 
elements, a front electrode 32 is provided on a transparent substrate 31 
and a photoelectric conversion layer 33 is provided on the front electrode 
32 while a back electrode 35 is provided on the photoelectric conversion 
layer 33, similarly to the embodiment shown in FIG. 1. Due to the 
interfacial layer 34 provided at the interface 33a, respective interfaces 
33b and 33c between the photoactive layer 33i and the n-type layer 33n and 
between the n-type conductive layer 33n and the back electrode 35 are 
slightly textured. Light 36 incident the device through the transparent 
substrate 31 reaches the photoelectric conversion layer 33, and is 
reflected by the interface 33c defining the surface of the back electrode 
35. The reflected light is scattered in various directions due to the 
textured shape of the interface 33c, whereby the optical path length 
thereof in the photoelectric conversion layer 33 is increased to improve 
photoelectric conversion efficiency. Since the interfacial layer 34 is 
provided at the interface 33a, recombination of photo-generated carriers 
at the interface 33a is reduced, whereby the photoelectric conversion 
efficiency is further improved. 
FIG. 4 shows an embodiment of a back side incidence type photovoltaic 
device according to the present invention. Referring to FIG. 4, a back 
electrode 42 is provided on a non-transparent substrate 41 and a 
photoelectric conversion layer 43 is provided on the back electrode 42, 
while a transparent front electrode 45 is provided on the photoelectric 
conversion layer 43. The non-transparent substrate 41 is made of ceramics, 
for example, and the back electrode 42 is made of aluminum or silver, for 
example, while the front electrode 45 is made of indium tin oxide, for 
example. According to this embodiment, a discontinuous interfacial layer 
44 is disposed at the interface 43b between a photoactive layer 43i and a 
p-type layer 43p. Due to the interfacial layer 44, the interface 43c 
between the front electrode 45 and the p-type layer 43p is slightly 
textured. As shown in FIG. 4, the photoelectric conversion layer 43 is 
formed by an n-type layer 43n, the photoactive layer 43i, and the p-type 
layer 43p. Light 46 incident the device through the front electrode 45 
passes through the photoelectric conversion layer 43 and is reflected by 
the surface of the back electrode 42, to again pass through the 
photoelectric conversion layer 43. 
FIG. 5 shows a photovoltaic device according to one of the preferred modes 
of the present invention. This photovoltaic device is of front side 
incidence type. A front electrode is provided on a transparent substrate 
51, and has a textured surface. A photoelectric conversion layer 53 is 
provided on the front electrode 52. This photoelectric conversion layer 53 
is formed by a p-type layer 53p, a photoactive layer 53i, and an n-type 
layer 53n. A discontinuous interfacial layer 54 is provided at the 
interface 53b between the photoactive layer 53i and the n-type layer 53n. 
Portions of the interface 53b between the interfacial layer 54 project 
toward the transparent substrate 51. Such a textured shape of the 
interface 53b can be obtained by forming the interfacial layer 54 and 
thereafter selectively etching portions of the photoactive layer 53i not 
provided with interfacial layer 54 during the manufacturing steps, as 
hereinafter described. 
The n-type layer 53n is provided on the photoactive layer 53i. Interface 
53c defining the surface of the n-type layer 53n also has a textured 
shape, due to the influence of the textured surface of the interface 53b. 
A back electrode 55 is provided on the n-type layer 53n. 
According to this embodiment, the interface 53b is so textured as to 
increase the degree of texturing of the interface 53c defining the surface 
of the back electrode 55. Thus, it is possible to increase reflection at 
the surface of the back electrode 55, thereby further improving the 
photoelectric conversion efficiency. 
FIG. 6 shows an embodiment of a back side incidence type photovoltaic 
device according to the present invention. Referring to FIG. 6, a back 
electrode 62 is provided on a non-transparent substrate 61, and a 
photoelectric conversion layer 63 is provided on the back electrode 62. A 
front electrode 65 is provided on the photoelectric conversion layer 63. 
The photoelectric conversion layer 63 is formed by an n-type layer 63n, a 
photoactive layer 63i, and a p-type layer 63p. According to this 
embodiment, a discontinuous interfacial layer 64 is provided at the 
interface 63b between the photoactive layer 63i and the p-type layer 63p. 
Regions of the interface 63b not provided with interfacial layer 64 
project toward the non-transparent substrate 61. Such a texture shape of 
the interface 63b can be defined by etching during the manufacturing 
steps, similarly to the embodiment shown in FIG. 5. Due to such a textured 
shape of the interface 63b, the interface 63c between the front electrode 
65 and the p-type layer 63p is also textured. Thus, light 66 incident the 
device through the front electrode 65 is scattered to travel through the 
photoelectric conversion layer 63. Thus, the optical path length is 
increased to improve photoelectric conversion efficiency. Due to the 
interfacial layer 64 provided at the interface 63b, recombination of 
carriers is reduced and the photoelectric conversion efficiency is further 
improved. 
FIG. 7 shows another embodiment of a front side incidence type photovoltaic 
device according to the present invention, which is similar to that shown 
in FIG. 5. Referring to FIG. 7, this embodiment is characterized in that a 
buffer layer 73b is provided between p-type layer 73p and photoactive 
layer 73i. This buffer layer 73b is adapted to improve interface 
characteristics of the p-type layer 73p and the photoactive layer 73i. The 
buffer layer 73b can be made of amorphous silicon carbide, for example. 
Thus, a photoelectric conversion layer 73 is formed by the p-type layer 
73p, the buffer layer 73b, the photoactive layer 73i, and the n-type layer 
73n according to this embodiment. This photoelectric conversion layer 73 
is provided on a front electrode 72, which is provided on a transparent 
substrate 71. A discontinuous interfacial layer 74 is provided at the 
interface 73 between the photoactive layer 73i and the n-type layer 73n. 
Portions of the interface 73d not provided with interfacial layer 74 
project toward the transparent substrate 71. Such a texture of the 
interface 73d can be defined by etching during the manufacturing steps, 
similarly to the embodiments shown in FIGS. 5 and 6. An n-type layer 73n 
is formed on the interface 73d, while the interface 73c between the n-type 
layer 73n and back electrode 75 is textured due to the influence of the 
textured shape of the interface 73d. As shown in FIG. 7, therefore, light 
76 incident the device through the transparent substrate 71 passes through 
the photoelectric conversion layer 73 and is irregularly reflected by the 
interface 73c defining the surface of the back electrode 75, whereby the 
optical path length is further increased in the photoelectric conversion 
layer 73. 
Also in the embodiment shown in FIG. 7, photoelectric conversion efficiency 
is improved by the textured shape of the interface 73c and provision of 
the interfacial layer 74. 
FIGS. 8A to 8E are sectional views illustrating the manufacturing steps of 
the photovoltaic device shown in FIG. 7, 
Referring to FIG. 8A, a front electrode 72 is formed on a transparent 
substrate 71, and then a p-type layer 73p of about 100 .ANG. in thickness, 
a buffer layer 73b, of about 100 .ANG. in thickness, and a photoactive 
layer 73i of about 5000 .ANG. in thickness are sequentially stacked by 
well-known plasma CFD processes. 
Referring to FIG. 8B, an interfacial layer 74 of silicon oxide is formed on 
the photoactive layer 73i by atmospheric pressure CVD. According to this 
embodiment, the interfacial layer 74 is about 500 .ANG. in thickness. 
Referring to FIG. 8C, the as-formed interfacial layer 64 is selectively 
removed by etching through well-known photolithography employing a 
photoresist material, to obtain the discontinuous or island-like structure 
shown in FIG. 8C. The intervals between the islands of the interfacial 
layer 74 are preferably set in a range of 0.1 to 10 .mu.m. According to 
this embodiment, such intervals are 0.4 .mu.m. 
Referring to FIG. 8D, the surface of the photoactive layer 73i provided 
with the discontinuous interfacial layer 74 is exposed to hydrogen plasma, 
to be etched. The depth of such etching, which is preferably adjusted in a 
range of 500 to 4000 .ANG., is 2000 .ANG. in this embodiment. Such 
treatment with hydrogen plasma is performed under conditions of an H.sub.2 
gas flow rate of 200 sccm, a reaction pressure of 0.3 Torr, a temperature 
of 190.degree. C., and RF power of 40 W. 
Due to such etching with hydrogen plasma, the surface of the photoactive 
layer 73i is textured as shown in FIG. 8D. 
Referring to FIG. 8E, an n-type semiconductor layer 73n of about 200 to 300 
.ANG. in thickness is deposited on the photoactive layer 73i by plasma 
CVD. The surface of the n-type semiconductor layer 73n is also textured. A 
back electrode 75 of about 2000 .ANG. in thickness is then formed on the 
n-type semiconductor layer 73n by evaporation. 
In the photovoltaic device manufactured in the aforementioned manner, the 
interface 73c defining the interior surface of the back electrode 75 has a 
texture shape of about 1500 .ANG. in height. In general, the texture shape 
of the back electrode is preferably about 1000 to 5000 .ANG. in height. 
FIG. 9 shows photosensitivity spectra of an inventive photovoltaic device A 
manufactured in the aforementioned manner, the conventional photovoltaic 
device B shown in FIG. 13, and a comparative photovoltaic device C 
prepared by simply etching the surface of a photovoltaic layer 73i by 
hydrogen plasma without provision of interfacial layers 74. 
As shown in FIG. 9, the inventive device A has higher photosensitivity for 
long wavelength light exceeding 600 nm in wavelength as compared with the 
other devices B and C. This is because the long wavelength light can be 
effectively absorbed by surface reflection at the back electrode 75 having 
a textured shape while the incident light is reflected also by the 
interfacial layer 74 provided between the photoactive layer 73i and the 
n-type semiconductor layer 73n to increase the amount of light absorption 
in the photoactive layer 73i as a result. In the photovoltaic device C 
having the photoactive layer 73i whose surface is textured only by 
treatment with hydrogen plasma, on the other hand, absorption of long 
wavelength light is only slightly increased due to insufficient texture 
shape of the surface. 
In the photovoltaic devices A, B, and C, the front electrodes for receiving 
light have the same thickness of 9000 .ANG., while the front electrodes 
themselves are textured substantially to the same degree. In the inventive 
photovoltaic device A, the surface of the photoactive layer 73i is so 
textured as to attain a further efficient light scattering effect, whereas 
the front electrode may not be remarkably textured dissimilarly to the 
conventional photovoltaic device. Therefore, the degree of front electrode 
texturing may be reduced and the electrode itself can be reduced in 
thickness. Thus, it is possible to reduce light absorption loss based on 
light absorption by the front electrode, while improving sensitivity for 
short wavelength light. 
Further, it is possible to suppress electrical short circuits across the 
front and back electrodes, which has been relatively frequently caused in 
general because of inferior texture shape, by reducing the texture shape 
of the front electrode. 
Photoelectric conversion characteristics of the inventive and conventional 
photovoltaic devices A and B are now described. Table 1 shows such 
photoelectric conversion characteristics. 
TABLE 1 
______________________________________ 
Device B 
Device A 
______________________________________ 
Open-Circuit Voltage (V) 
0.90 0.90 
Short-Circuit Current (mA/cm.sup.2) 
17.30 18.80 
Curve Factor 0.71 0.72 
Conversion Efficiency 
11.10 12.20 
______________________________________ 
As shown in Table 1, the short-circuit current of the inventive 
photovoltaic device A is larger than that of the conventional photovoltaic 
device B by 8.5%. As a result, the photoelectric conversion efficiency is 
improved by about 10% in the inventive photovoltaic device A. 
Further, the characteristics of the inventive photovoltaic device A are 
improved on the basis of the aforementioned increase in amount of light 
absorption, as well as by reduction of carrier recombination caused by the 
discontinuous interfacial layer provided at the interface with the 
photoelectric conversion layer. In other words, the island-like 
interfacial layer is positioned at the relatively interior interface 
between the photoactive layer and the n-type semiconductor layer so as to 
reduce the areas of direct contact of these layers, thereby reducing the 
recombination of charge carriers. Such reduction of carrier recombination 
contributes to improvement of the fill factor and the open-circuit voltage 
characteristics of the photovoltaic device. 
FIG. 10 shows the wavelength dependency of charge carrier collection 
efficiency in the inventive and conventional photovoltaic devices A and B. 
The wavelength dependency is indicated by the ration (I.sub.0 /I.sub.-5) 
of the photoelectric current I.sub.-5 in a reverse-biased state (-5 V) to 
the photoelectric current I.sub.0 in a zero-biased state (0 V) of each 
photovoltaic device irradiated with light of various wavelengths. 
The value of the current in the reverse-biased state is employed as the 
reference value for normalization since most of the photogenerated charge 
carriers generated at respective wavelengths can be collected as a 
photoelectric current in such a state. Thus, charge carrier recombination 
is reduced as the ratio approaches 1. 
As clearly shown in FIG. 10, the inventive photovoltaic device A is 
superior in carrier collection to the conventional photovoltaic device B 
in the wavelength of 350 to 800 nm. 
FIG. 11 illustrates the relation between the areal percent of the 
interfacial layer occupying the interface between the photoactive layer 
and the n-type semiconductor layer, i.e., the area occupation rate, in the 
photovoltaic device according to the present invention and photoelectric 
conversion efficiency. When the occupation rate is less than 30%, the 
photoelectric conversion efficiency remains substantially constant at a 
value of 0.75, while the conversion efficiency is remarkably improved in a 
range of 30 to 50% of the occupation rate, as shown in FIG. 11. When the 
occupation rate exceeds about 50%, on the other hand, the photoelectric 
conversion efficiency is reduced and when the occupation rate exceeds 
about 70%, the photoelectric conversion efficiency is reduced as compared 
with a device not provided with an interfacial layer, i.e., an occupation 
rate of 0%. Therefore, the occupation rate of the interfacial layer is 
preferably 30 to 70%, and more preferably 50 to 70% in the present 
invention. 
Such a change of the photoelectric conversion efficiency depending on the 
occupation rate conceivably results from the balance between improvement 
of the photoelectric conversion efficiency due to increase in number of 
collected charge carriers caused by reduction of carrier recombination and 
reduction of the photoelectric conversion efficiency caused by an 
increased in the distance of charge carrier movement required for carrier 
collection due to an excessive increase of the occupation rate. 
According to the present invention, as hereinabove described, it is 
possible to improve photoelectric conversion efficiency remarkably. 
Reduction of charge carrier combination significantly contributes to such 
improvement, while an increase in optical path length caused by the 
texture shape of the electrode layer may also contribute to this. 
FIG. 12 shows still another embodiment of a front side incidence type 
photovoltaic device according to the present invention, which is provided 
with a granular interfacial layer 84. Such interfacial layer 84 can be 
made of silicon oxide grains which are prepared by mechanically 
pulverizing glass or the like and sorting the obtained grains by size. In 
the photovoltaic device according to this embodiment, a photoactive layer 
83i is formed and thereafter silicon oxide grains 84 are distributed on 
this photoactive layer 83i, to be interspersed on its surface. Then, 
surface regions of the photoactive layer 83i not provided with silicon 
oxide grains 84 are etched with a hydrogen plasma, whereby the 
photovoltaic device shown in FIG. 12 can be obtained. A front electrode 82 
is provided on a transparent substrate 81, and a photoelectric conversion 
layer 83 is provided on the front electrode 82. A back electrode 85 is 
provided on the photoelectric conversion layer 83. The photoelectric 
conversion layer 83 is formed by a p-type layer 83p, a buffer layer 83b, a 
photoactive layer 83i, and an n-type layer 83n. 
Although the interfacial layers are made of silicon oxide in each of the 
aforementioned embodiments, such interfacial layers may alternatively be 
made of silicon nitride or zinc oxide, to obtain a similar effect. 
Although the p-type layer, the photoactive layer and the n-type layer are 
stacked in this order in the photoelectric conversion layer as viewed from 
the transparent substrate in each embodiment of the front side incidence 
type photovoltaic device, the present invention is not restricted to such 
order of stacking. For example, the n-type layer, the photoactive layer 
and the p-type layer may be stacked in this order as viewed from the 
transparent substrate, Also in the back side incidence type photovoltaic 
device, the order of stacking may be reversed. According to the present 
invention, the p-type layer, the photoactive layer, and the n-type layer 
may be made not only of amorphous silicon but of microcrystalline silicon 
containing crystal grains. 
According to the present invention, further, the interfacial layer can be 
arranged between the photoelectric conversion layer and either electrode, 
or between the photoactive layer or the photoelectric conversion layer and 
either the p- or n-type layer. 
Although the photoactive layer and the conductive layer are etched with 
hydrogen plasma in each of the aforementioned embodiments, the present 
invention is not restricted to this. For example, such layers can be 
chemically or physically etched with an inert gas such as helium or argon, 
or a reactive gas such as Freon gas of CF.sub.4 or the like. 
Alternatively, the layers may be wet etched with a solution of KOH or the 
like. 
Although the present invention has been described and illustrated in 
detail, it is clearly understood that the same is by way of illustration 
and example only and is not to be taken by way of limitation, the spirit 
and scope of the present invention being limited only by the terms of the 
appended claims.