JP3746607B2 - Manufacturing method of silicon-based thin film photoelectric conversion device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for manufacturing a thin film photoelectric conversion device, and more particularly to a manufacturing method capable of improving the productivity of a silicon-based thin film photoelectric conversion device while improving rather than reducing the performance.
[0002]
[Prior art]
In recent years, for example, photoelectric conversion devices using thin films containing crystalline silicon such as polycrystalline silicon and microcrystalline silicon have been vigorously developed. These developments are attempts to achieve both low cost and high performance of photoelectric conversion devices by forming a high-quality crystalline silicon thin film on an inexpensive substrate by a low temperature process. Applications to various photoelectric conversion devices such as optical sensors are expected.
[0003]
Conventionally, as a solar cell production apparatus, an in-line method in which a plurality of film deposition chambers (also referred to as chambers) are linearly connected, or a multi-chamber method in which an intermediate chamber is provided in the center and a plurality of chambers are arranged around it. Is adopted. This is because in the conventional manufacturing method, in order to prevent the performance degradation of the solar cell, the one-conductivity-type layer, the photoelectric conversion layer, and the reverse-conductivity-type layer are continuously formed in a vacuum process without being exposed to the atmosphere. is there.
[0004]
For example, in the case of a nip type solar cell in which an n layer, an i layer, and a p layer are sequentially stacked from the substrate side, an n layer deposition chamber for forming an n layer and an i layer for forming a photoelectric conversion layer in the in-line method. A structure in which a deposition chamber and a p-layer deposition chamber for forming a p-layer are connected in series is used. In this case, since the n layer and the p layer are thinner than the i layer and the film formation time is remarkably short, it is common to connect a plurality of i layer deposition chambers in order to increase production efficiency. The productivity increases as the number of i-layer deposition chambers increases until the deposition time of the n-layer and the p-layer reaches the rate-limiting state. However, since this in-line system includes a plurality of i-layer deposition chambers that require the most maintenance, the entire production line can be stopped when maintenance is required even in one i-layer deposition chamber. There is.
[0005]
On the other hand, the multi-chamber method is a method in which a substrate on which a film is to be deposited is moved to each film deposition chamber via an intermediate chamber. In addition, since a movable partition that can maintain airtightness is provided between each chamber and the intermediate chamber, even if a problem occurs in one chamber, the other chamber can be used, and the entire production can be performed. It is never stopped. However, this multi-chamber type production apparatus has a complicated and expensive mechanism for moving the substrate while maintaining the airtightness between the intermediate chamber and each chamber, and is disposed around the intermediate chamber. There is a problem that the number of chambers is spatially limited.
[0006]
[Problems to be solved by the invention]
As described above, in the conventional method for manufacturing a silicon-based thin film photoelectric conversion device, it cannot be produced efficiently at low cost without deteriorating the characteristics of the photoelectric conversion device. This is because if the interface between the photoelectric conversion layer and the p-type layer included in the photoelectric conversion unit is exposed to the atmosphere, the performance of the photoelectric conversion device is significantly reduced. This is because the semiconductor layer is continuously formed in a vacuum process without being exposed to the atmosphere.
[0007]
In view of such a problem of the prior art, the present invention is low cost and excellent while improving rather than reducing the performance of the photoelectric conversion device even if the interface between the photoelectric conversion layer and the p-type layer is exposed to the atmosphere. Another object of the present invention is to provide a method for manufacturing a silicon-based thin film photoelectric conversion device that can exhibit high productivity.
[0008]
[Means for Solving the Problems]
In the present invention, it includes at least one photoelectric conversion unit formed on a substrate, and the unit includes an n-type silicon-based semiconductor layer sequentially stacked by a plasma CVD method, a silicon-based thin-film photoelectric conversion layer containing a crystalline material, A method for manufacturing a silicon-based thin film photoelectric conversion device including a p-type silicon-based semiconductor layer includes: forming a surface oxide thin film by oxidizing a surface of an n-type semiconductor layer; After the surface of the photoelectric conversion layer is once exposed to the atmosphere, the surface is subjected to gas phase etching, and the p-type semiconductor layer is subsequently formed without exposing the gas phase etched surface to the atmosphere. It is characterized by that.
[0009]
In other words, as a result of repeated studies to solve the above-described problems in the prior art, the present inventors have found that in the case of a silicon-based thin film photoelectric conversion device in which all semiconductor layers are formed by plasma CVD at a low temperature, photoelectric conversion is performed. Even if the surface is exposed to the atmosphere after forming the layer, photoelectric conversion is performed by laminating a p-type layer after the surface is vapor-phase etched using appropriate hydrogen plasma or inert gas plasma. It has also been found that the performance of the device can be prevented and the performance of the photoelectric conversion device can be improved under appropriate etching conditions.
[0010]
This eliminates the need to transfer the substrate between the film deposition chambers in a vacuum atmosphere when laminating the p-type layer after forming the photoelectric conversion layer, thereby producing a low-cost and efficient photoelectric conversion device. It becomes possible. That is, a plurality of substrates on which an n-type layer and a photoelectric conversion layer requiring a long deposition time are stacked can be transported and waited in the atmosphere, and the plurality of substrates can be formed in the next short time. Allows rapid processing in a film deposition chamber for p-type layers.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic perspective view illustrating a silicon-based thin film photoelectric conversion device manufactured as a first embodiment of the present invention. As the substrate 101 of this apparatus, a metal such as stainless steel, an organic film having a low expansion coefficient such as polyimide, or an inexpensive glass having a low melting point can be used.
[0012]
The electrode 110 on the substrate 101 includes one or more of the following thin films (A) and (B), and is formed in the back electrode deposition chamber by, for example, vacuum evaporation or sputtering. In FIG. 1, the light 109 is depicted as being incident from above, but it may be incident from below, in which case the electrode 110 does not include a metal thin film.
(A) A metal thin film made of at least one metal selected from Ti, Cr, Al, Ag, Au, Cu and Pt, or an alloy thereof.
(B) ITO, SnO ₂ And a transparent conductive thin film comprising at least one oxide selected from ZnO.
[0013]
The substrate 101 on which the back electrode 110 is formed is taken out from the back electrode deposition chamber and transferred into the film deposition chamber for forming the n-type semiconductor layer, and the n-type semiconductor layer 104 included in the photoelectric conversion unit 111 is formed by plasma CVD. Is deposited. Even if the transfer of the substrate between the chambers at this time is performed in the atmosphere, no problem occurs. As n-type semiconductor layer 104, for example, an n-type microcrystalline silicon thin film doped with 0.01 atomic% or more of phosphorus, which is a conductivity-determining impurity atom, can be used. However, these conditions regarding the n-type layer 104 are not limited, and a layer of an alloy material such as microcrystalline silicon carbide or microcrystalline silicon germanium may be used. The thickness of the n-type microcrystalline silicon thin film 104 is set in the range of 3 to 100 nm, and more preferably in the range of 5 to 50 nm.
[0014]
After the n-type layer 104 is formed, the substrate 101 is preferably transferred to the photoelectric conversion layer deposition chamber via the atmosphere. At this time, a silicon-based oxide thin film 116 is formed on the surface of the n-type microcrystalline layer 104. From the experience, the thickness of the silicon-based oxide thin film 116 is preferably in the range of 0.5 to 50 nm, and more preferably in the range of 0.1 to 5 nm. Several other methods are possible for forming such a silicon-based oxide thin film 116. For example, a method of oxidizing by exposing the surface of the n-type microcrystalline layer 104 to another oxygen-containing gas, or a method of oxidizing using a plasma CVD method is also possible.
[0015]
On the silicon-based oxide thin film 116, a silicon-based thin film containing a crystalline material is formed as a photoelectric conversion layer 105 at a base temperature of 400 ° C. or lower by plasma CVD. The photoelectric conversion layer 105 may be a non-doped i-type polycrystalline silicon thin film, an i-type microcrystalline silicon thin film with a volume crystallization fraction of 80% or more, or a weak p-type or weak n-type photoelectric conversion function containing a small amount of impurities. A crystalline silicon-based thin film that is sufficiently equipped with can be used. In addition, the photoelectric conversion layer 105 is not limited thereto, and a film of an alloy material such as silicon carbide or silicon germanium may be used.
[0016]
The film thickness of the photoelectric conversion layer 105 is set in the range of 0.5 to 20 μm, more preferably in the range of 1 to 10 μm, and the thickness is necessary and sufficient for a silicon-based thin film photoelectric conversion layer containing crystalline material. The Since the photoelectric conversion layer 105 is formed at a low temperature of 400 ° C. or less, the photoelectric conversion layer 105 contains a large amount of hydrogen atoms that terminate or inactivate defects in crystal grain boundaries and grains, and the preferable hydrogen content is 0.5 to 30 atomic%. More preferably, it exists in the range of 1-20 atomic%.
[0017]
Most of the crystal grains contained in the silicon-based thin film photoelectric conversion layer 105 are extended and extended in a column shape upward from the base layer. Many of these crystal grains have (110) preferential crystal orientation plane parallel to the film surface, and the intensity ratio of (111) diffraction peak to (220) diffraction peak in X-ray diffraction is 1/5 or less, More preferably, it is 1/10 or less.
[0018]
When the above-described silicon-based oxide thin film 116 is formed before the photoelectric conversion layer 105 is formed, the (110) plane orientation in the photoelectric conversion layer 105 becomes conspicuous as compared with the case where the oxide thin film 116 is not formed. The particle size also increases. That is, in the X-ray diffraction from the photoelectric conversion layer 105, the (220) plane reflection peak is high and the half width is narrow. Therefore, by forming the silicon-based oxide thin film 116, the crystal structure of the photoelectric conversion layer 105 can be made more preferable. After the photoelectric conversion layer 105 is formed, the substrate 101 may be taken out into the atmosphere, and the surface of the photoelectric conversion layer 105 may be exposed to the atmosphere. The substrate 101 is then transferred into the p-type layer deposition chamber.
[0019]
In addition, when the photoelectric conversion layer 105 is deposited on the silicon-based oxide thin film 116 formed on the surface of the one conductivity type layer 104 as described above, the crystal structure of the photoelectric conversion layer 105 is remarkably improved. The reason is not always clear at this time. Further, although the silicon-based oxide film is known as a typical insulating film, the present inventors have also empirically found that this oxide film does not inhibit the current in the photoelectric conversion device according to the present invention. This is because the oxide thin film 116 has a knitted structure after the photoelectric conversion layer 105 is deposited because the oxide film is very thin, or it is considered that current can flow or the oxide film is very thin. Although it can be considered that current can flow by the tunnel effect, the reason is not necessarily clear at this time.
[0020]
In the p-type layer deposition chamber, the surface of the photoelectric conversion layer 105 is vapor-phase etched before the p-type layer 106 is deposited. This is performed with the intention of preventing the performance degradation of the photoelectric conversion device due to the silicon-based oxide film formed on the surface of the photoelectric conversion layer 105 exposed to the atmosphere. The oxide film formed on the surface of the photoelectric conversion layer 105 is reduced or etched by being exposed to, for example, hydrogen plasma, and the fresh surface of the photoelectric conversion layer 105 is restored. Further, if this vapor phase etching is performed under appropriate conditions, the crystal grain boundary on the surface of the photoelectric conversion layer 105 is etched to produce fine surface irregularities, and the effect of confining light in the photoelectric conversion layer by the surface irregularities. It can be expected that the photoelectric conversion efficiency is improved by increasing the light absorption in the photoelectric conversion layer. As conditions for the vapor phase etching, for example, when hydrogen plasma is used, a pressure within a range of 0.1 to 10 Torr and 1 to 30 mW / cm. ² RF power within the range is used. In addition, the plasma irradiation time in etching is in the range of 1 to 20 min, preferably in the range of 3 to 10 min. As the vapor phase etching, another etching method such as sputter etching may be used.
[0021]
After such vapor phase etching, a p-type layer 106 is formed. As this p-type layer 106, for example, a p-type amorphous silicon thin film doped with 0.01 atomic% or more of boron, which is a conductivity determining impurity atom, can be used. However, these conditions for the p-type layer 106 are not limited, and the impurity atom may be, for example, aluminum, or a layer of an alloy material such as amorphous silicon carbide or amorphous silicon germanium is used. Also good. When an amorphous silicon thin film is used as the p-type layer 106, the thickness thereof is in the range of 1 to 50 nm, and more preferably in the range of 2 to 30 nm. Note that the p-type layer 106 is not limited to an amorphous thin film, and may be a microcrystalline silicon-based thin film, or may be a stack of a microcrystalline thin film and an amorphous thin film.
[0022]
On the photoelectric conversion unit 111, ITO, SnO ₂ Transparent conductive oxide film 107 composed of at least one layer selected from ZnO, etc., and at least one metal selected from Al, Ag, Au, Cu, Pt or the like as a grid electrode on the transparent conductive oxide film 107 The comb-shaped metal electrode 108 including the alloy layer is formed by sputtering or vacuum deposition, thereby completing the photoelectric conversion device as shown in FIG. In FIG. 1, the light 109 is drawn so as to be incident from above, but this may be incident from below, in which case the metal electrode 108 is not necessarily comb-shaped. Alternatively, the transparent conductive film 107 may be omitted and the p-type layer 106 may be covered.
[0023]
FIG. 3 is a schematic perspective view illustrating a tandem-type silicon-based thin film photoelectric conversion device manufactured according to the second embodiment of the present invention. In the manufacture of the tandem photoelectric conversion device of FIG. 3, the plurality of layers 302 to 306 on the substrate 301 correspond to the plurality of layers 102 to 106 on the substrate 101 of FIG. It is formed.
[0024]
However, in the tandem photoelectric conversion device in FIG. 3, a second photoelectric conversion unit 312 is further formed over the first photoelectric conversion unit 311. The second photoelectric conversion unit 312 includes an n-type microcrystalline or amorphous silicon-based thin film 313 sequentially stacked on the first photoelectric conversion unit 311 by a plasma CVD method, and is substantially an i-type amorphous. A silicon-based thin film photoelectric conversion layer 314 and a p-type microcrystalline or amorphous silicon-based thin film 315 are included. In this case, the n-type silicon thin film 313 and the i-type amorphous silicon photoelectric conversion layer 314 are continuously formed in a vacuum atmosphere, and the substrate 301 is formed after the amorphous silicon photoelectric conversion layer 314 is formed. It is taken out into the atmosphere and transferred into a film deposition chamber for depositing a p-type silicon thin film 315. Then, after the surface of the amorphous silicon photoelectric conversion layer 314 is vapor-phase etched by hydrogen plasma or the like in the p-type layer deposition chamber, the p-type amorphous silicon thin film 315 is formed.
[0025]
A transparent electrode 307 and a comb-shaped metal electrode 308 are formed on the second photoelectric conversion unit 312 in the same manner as the corresponding elements 107 and 108 in FIG. 1, thereby completing the tandem photoelectric conversion device in FIG. To do.
[0026]
Further, a multi-stage tandem including a plurality of at least one of a photoelectric conversion unit including a crystalline photoelectric conversion layer and a photoelectric conversion unit including an amorphous photoelectric conversion layer by a manufacturing method according to another embodiment of the present invention. It goes without saying that it is also possible to manufacture a type photoelectric conversion device.
[0027]
【Example】
Below, the manufacturing method of the silicon-type thin film photoelectric conversion apparatus by some Example of this invention is demonstrated with the manufacturing method of the photoelectric conversion apparatus as a comparative example.
[0028]
(Comparative Example 1)
A polycrystalline silicon thin film solar cell as shown in FIG. 2 was produced by the production method as Comparative Example 1. First, an Ag film 202 having a thickness of 300 nm and a ZnO film 203 having a thickness of 100 nm thereon were formed as a back electrode 210 on the glass substrate 201 by sputtering. On the back electrode 210, a phosphorous-doped n-type microcrystalline silicon layer 204 having a thickness of 10 nm, a non-doped polycrystalline silicon photoelectric conversion layer 205 having a thickness of 3 μm, and a p-type microcrystalline silicon layer having a thickness of 10 nm and boron-doped. 206 were formed by the plasma CVD method, and the nip type photoelectric conversion unit 211 was formed. However, these semiconductor layers 204, 205, and 206 were formed by moving the substrate 201 between the film deposition chambers without exposing them to the atmosphere. On the photoelectric conversion unit 211, a transparent conductive ITO film having a thickness of 80 nm is deposited as a front electrode 207 by a sputtering method, and a comb-shaped Ag electrode 208 for current extraction is deposited thereon by a vacuum evaporation method. Been formed.
[0029]
The n-type microcrystalline silicon layer 204 was deposited by the RF plasma CVD method under the following conditions. That is, the flow rates of the reaction gas were 5 sccm for silane, 200 sccm for hydrogen, and 0.05 sccm for phosphine, and the reaction chamber pressure was set to 1 Torr. RF power density is 30mW / cm ² The film formation temperature was 200 ° C. The dark conductivity of the 300 nm thick n-type microcrystalline silicon film deposited directly on the glass substrate under the same film forming conditions was 10 S / cm. Further, the polycrystalline silicon photoelectric conversion layer 205 formed on the n-type microcrystalline silicon layer 204 was deposited by an RF plasma CVD method at a film forming temperature of 200 ° C. In the polycrystalline silicon photoelectric conversion layer 205, the hydrogen content obtained from secondary ion mass spectrometry is 5 atomic%, and the intensity ratio of the (111) diffraction peak to the (220) diffraction peak in X-ray diffraction is 1/4. Met.
[0030]
As the incident light 209 of the solar cell manufactured in Comparative Example 1, AM1.5 light is 100 mW / cm. ² In the output characteristics when irradiated with an amount of light, the open-circuit voltage is 0.472 V and the short-circuit current density is 26.8 mA / cm. ² The fill factor was 74.5% and the conversion efficiency was 9.4%.
[0031]
(Comparative Example 2)
As a solar cell by the manufacturing method of Comparative Example 2, a solar cell as shown in FIG. That is, in the method of manufacturing the solar cell of Comparative Example 2, when forming each semiconductor layer of the n-type microcrystalline silicon layer 204, the non-doped polycrystalline silicon photoelectric conversion layer 205, and the p-type microcrystalline silicon layer 206, The only difference from the manufacturing method of Comparative Example 1 is that the substrate 201 is moved through the atmosphere between the film deposition chambers.
[0032]
The solar cell obtained by the manufacturing method of Comparative Example 2 was supplied with AM1.5 light as incident light 209 of 100 mW / cm. ² In the output characteristics when irradiated with an amount of light, the open-circuit voltage is 0.484 V and the short-circuit current density is 26.0 mA / cm. ² The fill factor was 65.0% and the conversion efficiency was 8.2%.
[0033]
Example 1
A polycrystalline silicon thin film solar cell as Example 1 was produced by the manufacturing method corresponding to the first embodiment of FIG. Also in Example 1, as in Comparative Example 1, after the back electrode 110 including the Ag film 102 and the ZnO film 103 and the n-type microcrystalline silicon layer 104 were formed on the glass substrate 101, the substrate 101 Was transferred into the i-layer deposition chamber via the atmosphere. At this time, the surface of the n-type layer 104 was exposed to the atmosphere for about 1 minute, and a silicon-based oxide thin film 116 was formed on the surface.
[0034]
In the polycrystalline silicon photoelectric conversion layer 105 deposited on the silicon-based oxide thin film underlayer 116 under the same CVD conditions as in Comparative Example 1, the hydrogen content obtained by secondary ion mass spectrometry was compared. Although it was 5 atomic%, which was almost the same as in Example 1, the intensity ratio of the (111) diffraction peak to the (220) diffraction peak in X-ray diffraction was reduced to 1/10.
[0035]
After the photoelectric conversion layer 105 was formed, the substrate 101 was transferred into the p-layer deposition chamber through the atmosphere. In the p-layer deposition chamber, the surface of the photoelectric conversion layer 105 was first vapor-phase etched using hydrogen plasma. In this gas phase etching by hydrogen plasma, the hydrogen flow rate is 500 sccm and the RF power is 30 mW / cm ² The plasma irradiation time was 10 minutes. Thereafter, a p-type microcrystalline silicon layer 106, a transparent electrode 107, and a comb-shaped metal electrode 108 were formed under the same conditions as in Comparative Example 1.
[0036]
AM1.5 light is applied as 100 mW / cm as incident light 109 to the solar cell manufactured by the manufacturing method of Example 1 as described above. ² In the output characteristics when irradiated with an amount of light, the open-circuit voltage is 0.531 V and the short-circuit current density is 27.4 mA / cm. ² The fill factor was 72.3% and the conversion efficiency was 10.5%.
[0037]
(Comparative Example 3)
A tandem solar cell as shown in FIG. 4 was produced by the manufacturing method as Comparative Example 3. In the solar cell according to the manufacturing method of Comparative Example 3, the elements 401 to 406 were formed in the same manner as the corresponding elements 201 to 206 of Comparative Example 2. That is, the substrate 401 was transferred between the semiconductor layer deposition chambers in the atmosphere. However, in Comparative Example 3, an amorphous silicon photoelectric conversion unit 412 was further stacked on the first photoelectric conversion unit 411. The second photoelectric conversion unit 412 includes an n layer 413, an i layer 414, and a p layer 415, each of which is amorphous. The movement of the substrate 401 between the film deposition chambers during the formation of these amorphous semiconductor layers was also performed in the atmosphere. Note that the thickness of the amorphous photoelectric conversion layer 414 was set to 0.4 μm.
[0038]
After that, by forming the transparent electrode 407 and the comb-shaped metal electrode 408 on the second photoelectric conversion unit 412 like this in the same manner as the corresponding elements 207 and 208 of Comparative Example 1, as shown in FIG. A tandem solar cell according to Comparative Example 3 was prepared.
[0039]
With respect to the amorphous / polycrystalline tandem solar cell manufactured by the manufacturing method of Comparative Example 3 as described above, AM1.5 light is used as incident light 409 at 100 mW / cm. ² In the output characteristics when irradiated with a light amount of 1.33 V, the open circuit voltage is 1.33 V and the short-circuit current density is 13.0 mA / cm. ² The fill factor was 64.7% and the conversion efficiency was 11.1%.
[0040]
(Example 2)
Corresponding to the second embodiment of FIG. 3, a tandem solar cell by the manufacturing method of Example 2 was produced. In Example 2, the elements 301 to 306 were formed in the same manner as the corresponding elements 101 to 106 of Example 1. However, in Example 2, an amorphous silicon photoelectric conversion unit 312 was further stacked on the first photoelectric conversion unit 311. The second photoelectric conversion unit 312 includes an n layer 313, an i layer 314, and a p layer 315, each of which is amorphous.
[0041]
Among these amorphous semiconductor layers, the n layer 313 is formed on the p-type microcrystalline silicon layer 306 which is the base layer without being exposed to the atmosphere, and the i layer 314 is also exposed to the atmosphere. Formed on it without. However, after the i-layer 314 was formed, the substrate 301 was transferred through the atmosphere into the p-layer deposition chamber. Then, the p-layer 315 was formed after the surface of the i-layer 314 was vapor-phase etched with hydrogen plasma in Example 1.
[0042]
Thereafter, as in Comparative Example 3, a transparent electrode 307 and a comb-shaped metal electrode 308 were formed.
[0043]
With respect to such an amorphous / polycrystalline tandem solar cell according to Example 2, AM1.5 light is used as incident light 309 at 100 mW / cm. ² The output characteristics when irradiated with a light amount of 1.41 V are the open-circuit voltage, and the short-circuit current density is 13.5 mA / cm. ² The fill factor was 73.9% and the conversion efficiency was 14.1%.
[0044]
【The invention's effect】
As described above, when the substrate is moved to the next film deposition chamber after the substantially i-type photoelectric conversion layer that requires a longer deposition time than the conductive type layer is formed, the substrate can be transported or waited in the atmosphere. Therefore, the silicon-based thin film photoelectric conversion device can be efficiently manufactured at a low cost without deteriorating its performance. According to the present invention, since fine irregularities can be formed on the surface of the photoelectric conversion layer by vapor phase etching, it contributes to the performance improvement of the photoelectric conversion device by improving the light confinement effect in the photoelectric conversion layer. be able to.
[Brief description of the drawings]
FIG. 1 is a schematic perspective view for explaining a method for manufacturing a crystalline silicon-based thin film photoelectric conversion device according to a first embodiment of the present invention.
FIG. 2 is a schematic perspective view for explaining a method for manufacturing a crystalline silicon-based thin film photoelectric conversion device as Comparative Examples 1 and 2 according to the prior art.
FIG. 3 is a schematic perspective view for explaining a method of manufacturing an amorphous / crystalline tandem silicon thin film photoelectric conversion device according to a second embodiment of the present invention.
FIG. 4 is a schematic perspective view for explaining a manufacturing method of an amorphous / crystalline tandem silicon thin film photoelectric conversion device as Comparative Example 3 according to the prior art.
[Explanation of symbols]
101, 201, 301, 401: substrate such as glass
102, 202, 302, 402: films such as Ag
103, 203, 303, 403: films of ZnO, ITO, etc.
104, 204, 304, 404: for example, n-type microcrystalline silicon layer
105, 205, 305, 405: crystalline silicon photoelectric conversion layer
106, 206, 306, 406: for example, p-type microcrystalline silicon layer
107, 207, 307, 407: Transparent conductive film such as ITO
108, 208, 308, 408: Comb electrodes such as Ag
109, 209, 309, 409: Irradiation light
110, 210, 310, 410: electrode
111, 211, 311, 411: crystalline silicon photoelectric conversion unit
312, 412: Amorphous silicon photoelectric conversion unit
313, 413: n-type silicon-based layer
314, 414: i-type amorphous silicon photoelectric conversion layer
315, 415: p-type silicon-based layer
116, 316: Silicon-based oxide thin film

Claims (6)

Including at least one photoelectric conversion unit formed on a substrate, wherein the photoelectric conversion unit is sequentially stacked by a plasma CVD method, an n-type silicon-based semiconductor layer, a silicon-based thin film photoelectric conversion layer containing a crystalline material, and a p-type A method for manufacturing a photoelectric conversion device including a silicon-based semiconductor layer,
Forming the photoelectric conversion layer so as to cover the surface after forming a surface oxide thin film by oxidizing the surface of the n-type semiconductor layer;
After the surface of the photoelectric conversion layer is once exposed to the atmosphere, the surface is vapor-phase etched,
A method of manufacturing a silicon-based thin film photoelectric conversion device, wherein the p-type semiconductor layer is formed continuously without exposing the vapor-etched surface to the atmosphere. The photoelectric conversion layer has (110) preferential crystal orientation plane parallel to the film surface, and the intensity ratio of (111) diffraction peak to (220) diffraction peak in X-ray diffraction is 1/5 or less. The manufacturing method of the photoelectric conversion apparatus of Claim 1 characterized by these. The photoelectric conversion layer is formed under a base temperature of 400 ° C., has a volume crystallization fraction of 80% or more, a hydrogen content in the range of 0.1 to 30 atomic%, and 0.5 to 10 μm. The method for manufacturing a photoelectric conversion device according to claim 1, wherein the thickness of The method for manufacturing a photoelectric conversion device according to any one of claims 1 to 3, wherein the gas used for the vapor phase etching contains hydrogen or an inert gas. 5. The method for manufacturing a photoelectric conversion device according to claim 1, wherein an electric power used for activating the etching gas in the vapor phase etching is in a range of 1 to 30 mW / cm ^2. . In addition to the at least one photoelectric conversion unit, at least one other photoelectric conversion unit including an n-type silicon-based semiconductor layer, an amorphous silicon-based thin film photoelectric conversion layer, and a p-type silicon-based semiconductor layer, which are sequentially stacked, The method for manufacturing a photoelectric conversion device according to claim 1, wherein the photoelectric conversion device is laminated.

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