The present invention relates to a high-efficiency solar cell and a method of manufacturing the same, and more particularly, to a high-efficiency solar cell and a method of manufacturing the same, wherein an upper ohmic layer of a semiconductor solar cell is formed at a tilt angle of less than 45° and an ohmic electrode is deposited on the upper ohmic layer so as to lessen shadow loss due to the ohmic electrode and to reduce contact resistance.
This work was supported by the IT R&D program of MIC/IITA. [2006-S-006-02, Component modules for ubiquitous terminals].
A solar cell is a semiconductor device that converts solar energy into electrical energy and has a p-n junction structure. An n-type semiconductor region contains a large number of electrons for majority carriers, while a p-type semiconductor region contains a large number of holes for majority carriers. Thus, when a p-n junction is formed, inter-diffusion of carriers occurs between the n- and p-type semiconductor regions due to a concentration gradient. In this case, space charges are generated to cause built-in potentials. When diffusion components dependent on carriers become equivalent to drift components dependent on the built-in potentials, the solar cell enters a parallel state. Also, when photons having energy higher than the bandgap of a p-n junction diode are incident to the solar cell, electrons receive light energy and are excited from a valence band to a conduction band to thereby generate electron-hole pairs. Thus, both electrodes of the p-n junction diode are connected to an external circuit and transmit electromotive force (EMF) to the external circuit so that the solar cell can perform its proper functions.
Conventional solar cells employ p-n homojunctions formed of single-crystalline silicon (Si). This is because although the solar cells have slightly low photoelectric conversion efficiency, they are less expensive.
In comparison with a III-V group GaAs-based single-crystalline solar cell having a direct bandgap, a Si solar cell having an indirect bandgap has lower photoelectric conversion efficiency, but the Si solar cell is much less expensive and more widely used.
However, in recent years, much research has been done into solar cells with concentrators for focusing light using lenses, and as a result, a percentage taken by a solar cell in the total price of the solar cell system is decreasing greatly. Also, although the photoelectric conversion efficiency of Si solar cells has not greatly been developed since the nineties, the photoelectric conversion efficiency of III-V Group GaAs-based single-crystalline solar cells has been gradually increasing by about 1% every year. Thus, the III-V Group GaAs-based single-crystalline solar cells exhibit about twice the photoelectric conversion efficiency of the Si solar cells. And while Si solar cells with concentrators focus light 20 times as efficiently, III-V Group GaAs-based single-crystalline solar cells with concentrators focus light 500 times as efficiently. Thus, it is expected that the III-V Group GaAs-based single-crystalline solar cells with concentrators will lead the Si solar cells with concentrators in terms of price competitiveness.
Referring to
The BSF layer 120 is heavily doped so as to reduce a recombination rate at an interface between the BSF layer 120 and the lightly doped light absorption layer 130. Also, the window layer 140 functions to reduce a recombination rate on the surface of the window layer 140 to allow most of incident light to be absorbed by the light absorption layer 130. Furthermore, the window layer 140 is used to minimize the reflection rate of incident light along with the AR layer 180.
The upper ohmic electrode 160 and the lower ohmic electrode 170 are used to transmit EMF generated by both electrodes of a p-n junction diode to an external circuit. As shown in
Since GaAs has a high refractive index of about 4, the AR layer 180 is used to lessen reflection loss that occurs due to a difference in refractive index between air and GaAs. In general, the AR layer 180 is a single dielectric thin layer, such as a SiNX layer, a SiO2 layer, or an indium tin oxide (ITO) layer, or a multiple dielectric layer, such as a MgF2/ZnS layer or a Ta2O5/SiO2 layer.
However, in the above-described solar cell, since the upper ohmic electrode 160 is vertically etched as shown in
In general, when the n+-type ohmic layer 150 is formed of Si, the upper ohmic electrode 160 is formed of Al or Ag and when the n+-type ohmic layer 150 is formed of GaAs, the upper ohmic electrode 160 is formed of AuGe/Ni/Au or Au. Owing to interfacial characteristics between the n+-type ohmic layer 150 and the upper ohmic electrode 160, incident light is reflected and causes shadow loss, thereby lowering photoelectric conversion efficiency.
In order to improve the photoelectric conversion efficiency of a solar cell, an upper ohmic electrode may be formed of a transparent material, such as SnO2, In2O3, or TiO2. However, the transparent upper ohmic electrode has poorer characteristics than other ordinary metal electrodes.
Accordingly, in order to reduce shadow loss of the upper ohmic electrode, it is important to lessen an area occupied by a grid line, bus line, and metal pad. However, as the width of the upper ohmic electrode decreases, the contact resistance of the upper ohmic electrode increases, thereby deteriorating photoelectric conversion efficiency.
Furthermore, when a spacing between grid lines (or a grid spacing) is increased, shadow loss may decrease, but electrons (or holes) caused by solar light are recombined and lost. Thus, shadow loss due to the grid spacing is traded off with shadow loss due to recombination of carriers. Therefore, it is very complicated to optimize the grid width and grid spacing while considering contact resistance, shadow loss, and recombination of carriers.
In another approach, an upper ohmic electrode 260 having a curved surface may be formed as shown in
Referring to
Compared to the upper ohmic electrode 160 shown in
A third method of lessening shadow loss of an upper ohmic electrode is illustrated in
Referring to
However, since a typical substrate has a thickness of about 200 to 800 μm, it is difficult to dry or wet etch the thick substrate to form a via hole. Also, unlike when a p-n homojunction formed of a single material is formed as shown in
The present invention is directed to a high-efficiency solar cell, which lessens shadow loss caused by an upper ohmic electrode so as to improve photoelectric conversion efficiency, and a method of manufacturing the same.
One aspect of the present invention provides a high-efficiency solar cell for converting light energy of incident light into electrical energy, the solar cell comprising an upper ohmic layer and an upper ohmic electrode of which lateral surfaces have a predetermined tilt angle to allow the incident light to be incident into the solar cell.
Another aspect of the present invention provides a method of manufacturing a high-efficiency solar cell. The method comprising: forming an etch mask using a photolithography process on a substrate including a back surface field (BSF) layer, a light absorption layer, a window layer, and an upper ohmic layer that are formed sequentially; etching a lateral surface of the upper ohmic layer to have a predetermined tilt angle; and forming an upper ohmic electrode using a metallization process on the upper ohmic layer having the lateral surface with the predetermined tilt angle.
Still another aspect of the present invention provides a method of manufacturing a high-efficiency solar cell. The method comprising: forming a growth prevention mask using a photolithography process on a substrate on which a back surface field (BSF) layer, a light absorption layer, and a window layer are formed sequentially; selectively growing an upper ohmic layer on a portion of the window layer using the growth prevention mask such that the upper ohmic layer has a lateral surface with a predetermined tilt angle; and forming an upper ohmic electrode using a metallization process on the upper ohmic layer having the lateral surface with the predetermined tilt angle.
The predetermined tilt angle may be less than 45°, so that incident light incident to the lateral surface of the upper ohmic electrode is reflected at a reflection angle greater than the predetermined tilt angle and incident to the solar cell.
According to the present invention as described above, an upper ohmic layer of a semiconductor solar cell is formed at a tilt angle less than about 45°, and an ohmic electrode is deposited on the upper ohmic layer, thereby lessening shadow loss caused by the ohmic electrode and reducing contact resistance.
Also, according to the present invention, it is possible to form an ohmic electrode with an appropriately wide ohmic contact width and a minimum grid spacing.
Hereinafter, a high-efficiency solar cell and a method of manufacturing the same according to the present invention will be described name fully with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown.
Referring to
In this case, the inclined lateral surface is formed at a tilt angle 0 less than 45°, so that light is incident to the inclined lateral surface at an incidence angle φ greater than 45°.
As shown in
Accordingly, incident light L is incident to the lateral surface of the upper ohmic electrode 460 and reflected by the lateral surface of the upper ohmic electrode 460 at a reflection angle greater than 45°. Thus, the incident light L is not scattered elsewhere but incident to the solar cell via an anti-reflection (AR) layer 480, so that the ohmic electrode 460 does not cause shadow loss.
Also, the mesa-type ohmic electrode 460 according to the present embodiment has a greater ohmic contact width between the ohmic electrode 460 and the ohmic layer 450 than the square ohmic electrode shown in
Meanwhile, although the present embodiment exemplarily describes a III-V Group GaAs-based single-crystalline solar cell, the present invention can be applied to all kinds of solar cells, such as single-crystalline Si solar cells, poly-crystalline Si solar cells, amorphous Si solar cells, Cu—In—Ge—Sn (CIGS) solar cells, dye-sensitized solar cells (DSSCs), etc.
Referring to
In other words, the upper ohmic layer 550 has a triangular shape, and an upper ohmic electrode 560 formed on the upper ohmic layer 550 also has a triangular shape.
As compared with the solar cell shown in
Referring to
That is, when the tilt angle θ is less than 45°, the reflection angle φ becomes greater than 45°, so that the reflected light is not scattered externally but incident to the solar cell. In this case, it is necessary to keep a minimum grid spacing so as not to re-reflect the reflected light by an adjacent lateral surface of the upper ohmic electrode 560.
Referring to
That is, an ohmic electrode of the solar cell should be designed to maximize ohmic contact width and minimize minimum grid spacing. Referring to
A conventional ohmic layer of a III-V Group GaAs-based solar cell is formed to a thickness of approximately 0.1 to 0.5 μm, while a solar cell according to the present invention adopts an ohmic layer with a thickness of 0.5 μm or name.
Hereinafter, a method of forming an inclined upper ohmic layer according to the present invention will be described in further detail.
The ohmic upper layers with the inclined lateral surfaces shown in
Referring to
In this case, the ohmic layer 550 is not only etched in a vertical direction due to a wet etchant, but also etched in a horizontal direction to form an undercut, thereby resulting in the inclined ohmic layer 550.
The etch mask M1 may be a hard mask or a soft mask. The hard mask may be a SiNX mask, a SiO2 mask, or a metal mask, and the soft mask may be photoresist (PR). However, the soft mask is more appropriate than the hard mask in facilitating the formation of the undercut.
Referring to
Referring to
In addition to the wet etching process, the upper ohmic layer 550 may be etched into an inclined shape using a reactive dry etching process as follows.
Referring to
Referring to
The growth prevention mask M2 may be formed to an appropriate thickness and used as an AR layer. In this case, after the upper ohmic electrode 560 is formed, the manufacture of the solar cell is completed without adding any subsequent process, thereby simplifying the entire process.
Meanwhile, when the inclined upper ohmic electrode 560 is formed using the above-described selective etching process or the selective area growth process, the reflection angle of incident light can be varied by shifting the direction of a grid line in the upper ohmic electrode 560, as will be described in further detail below.
Meanwhile, in the above-described solar cell in which an upper ohmic layer and an ohmic electrode are inclined at a predetermined angle, a metal layer made of a metal which has a high reflection rate in ultraviolet (UV) and visible (V) regions (e.g. an Ag layer), may be additionally deposited on the upper ohmic electrode 560 in order to improve the reflective characteristics of metals. In this case, the ohmic electrode can have a higher reflection rate, thereby improving photoelectric conversion efficiency. Also, a bus line of the upper ohmic electrode 560 may be formed in the same manner as the grid line shown in
While the invention has been shown and described with reference to m certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
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10-2007-0100597 | Oct 2007 | KR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/KR2008/004463 | 7/31/2008 | WO | 00 | 3/5/2010 |