This invention relates to a solar cell with a discontinuous or reduced thickness window layer.
Photovoltaic devices can include transparent thin films that are also conductors of electrical charge. For example, a photovoltaic device can include a semiconductor window layer and a semiconductor absorber layer to convert solar power into electrical power. Photovoltaic devices can be inefficient at converting solar power to electrical power.
A solar cell device can include various layers, including, for example, barrier layer, a layer of transparent conductive oxide (TCO)/buffer, a semiconductor window layer, a semiconductor absorber layer, and a back contact, all deposited adjacent to a substrate. Each layer can include one or more deposits of suitable material. For example, a photovoltaic device can include a semiconductor layer including two layers of semiconductor, a semiconductor window layer and a semiconductor absorber layer. A photovoltaic device layer can cover a portion or all of the area on which it is deposited. General experience suggests that the semiconductor window layer can be continuous for good solar cell performance. For example, in the current technology device design, the semiconductor window layer is typically thicker than 750 angstroms and highly continuous providing 80-90% coverage of the underlying TCO.
A high performing solar cell device can include a semiconductor window layer that can be thin, or non-conformal, or discontinuous, and can provide only 30 to 70% coverage of the underlying TCO layer. The reduction of the semiconductor window layer's thickness can improve the quantum efficiency in the blue spectrum of light and hence increase the short circuit current density of the solar cell or photovoltaic module. This device design can also achieve a reduction in the cost of production since less semiconductor window layer material is utilized and the overall improvement in the quantum efficiency and conversion efficiency of the solar cell. This design can also include a method of improving the conversion efficiency of a thin film photovoltaic device by inducing openings in the window layer while avoiding issues of TCO/absorber shunting.
Absorption of light by the window layer can be one of the phenomena limiting the conversion efficiency of a photovoltaic device. Generally, it is desirable to keep the window layer as thin as possible to allow a higher fraction of photons with energy above its band gap to reach the absorber. However, for most thin-film photovoltaic devices, if the window layer is too thin, a loss in performance can be observed due to lower open circuit voltage (Voc)/fill factor (FF).
A photovoltaic device can include a substrate, a transparent conductive oxide layer adjacent to the substrate, a discontinuous semiconductor window layer adjacent to the transparent conductive oxide layer, a semiconductor absorber layer adjacent to the semiconductor window layer, and a junction formed between the semiconductor absorber layer and the transparent conductive oxide layer. The discontinuous semiconductor window layer can provide 20 to 80% or 30 to 70% coverage of the adjacent transparent conductive oxide layer. The semiconductor absorber layer can absorb 5% to 45% more photons with a wavelength of less than 520 nm than the same absorber layer without any junctions to the transparent conductive oxide layer. The semiconductor absorber layer can absorb at least 10% more blue light than the same absorber layer without a junction to the transparent conductive oxide layer. The equivalent uniform thickness of the semiconductor window layer can be any suitable thickness. The equivalent uniform thickness of the semiconductor window layer can be less than 2500 angstroms, for example in the range 200 angstroms to 2500 angstroms. The equivalent uniform thickness of the semiconductor window layer can be less than 1200 angstroms. The equivalent uniform thickness of the semiconductor window layer can be in the range of 150 angstroms to 1200 angstroms, or 400 angstroms to 1200 angstroms or any other suitable thickness. The equivalent uniform thickness of the semiconductor window layer can be less than 750 angstroms. The equivalent uniform thickness of the semiconductor window layer can be in the range of 150 angstroms to 500 angstroms or 250 angstroms to 400 angstroms.
The substrate can include glass. The semiconductor window layer can include cadmium sulfide, zinc sulfide, or an alloy of cadmium sulfide and zinc sulfide, or any other suitable material. The semiconductor absorber layer can include cadmium telluride or cadmium zinc telluride, or any other suitable material. The transparent conductive oxide layer can include zinc oxide, tin oxide, or cadmium stannate, or any other suitable material.
A photovoltaic device can include a substrate, a transparent conductive oxide layer adjacent to the substrate, a discontinuous semiconductor window layer adjacent to the transparent conductive oxide layer, and a semiconductor absorber layer including a dopant. The dopant can be capable of interacting with and fluxing the adjacent semiconductor window layer. The dopant can include silicon, germanium, chlorine, or sodium, or any other suitable material. The semiconductor absorber layer can include a dopant concentration in the range of 1015 to 1018 atoms/cm3 or 1016 to 1017 atoms/cm3, or any other suitable range or value. The semiconductor absorber layer can be annealed. The dopant can accumulate at an absorber layer/window layer interface. The photovoltaic device can include one or more junctions between the semiconductor absorber layer and the transparent conductive oxide layer. The semiconductor window layer can provide 20 to 80% coverage of the adjacent transparent conductive oxide layer. The dopant can electrically passivate the transparent conducting oxide layer /absorber layer junction to maintain open circuit voltage (Voc) and fill factor (FF). Improvements in carrier collection efficiency and/or reduction in open circuit resistance are responsible for improved FF.
The semiconductor absorber layer can absorb 5% to 45% more photons with a wavelength of less than 520 nm than the same absorber layer without a junction to the transparent conductive oxide layer. The semiconductor absorber layer can absorb at least 10% more blue light than the same absorber layer without a junction to the transparent conductive oxide layer. The thickness of the semiconductor absorber layer can be in the range of 0.5 micron to 7 microns. The equivalent uniform thickness of the semiconductor window layer can be less than 1200 angstroms.
The semiconductor window layer can include cadmium sulfide, zinc sulfide, or an alloy of cadmium sulfide and zinc sulfide, or any other suitable material. The semiconductor absorber layer can include cadmium telluride, or cadmium zinc telluride, or any other suitable material. The transparent conductive oxide can include zinc oxide, tin oxide, or cadmium stannate, or any other suitable material.
A method of manufacturing a photovoltaic device can include depositing a transparent conductive oxide layer adjacent to a substrate, forming a discontinuous semiconductor window layer adjacent to the transparent conductive oxide layer, and depositing a semiconductor absorber layer adjacent to the window layer, and forming one or more than one junction between the absorber layer and transparent conductive oxide layer. The step of forming a junction can include forming a plurality of junctions between the absorber layer and transparent conductive oxide layer.
A method of manufacturing a photovoltaic device can include depositing a transparent conductive oxide layer adjacent to a substrate, forming a semiconductor window layer adjacent to the transparent conductive oxide layer. The semiconductor window layer can include and/or provide spotty coverage of the adjacent transparent conductive oxide layer. This can result in increased efficiency. The method can include depositing a semiconductor absorber layer adjacent to the semiconductor window layer. The semiconductor window layer can provide 20 to 80% coverage of the adjacent transparent conductive oxide layer. The window layer's irregular or spotty coverage of the adjacent transparent conductive oxide layer can be formed by doping the semiconductor absorber layer with a dopant and diffusing the dopant to an interface between the window layer and the absorber layer flux the window layer away. The window layer can be partially fluxed away. The spotty coverage of the adjacent transparent conductive oxide layer can result in junctions between the transparent conducting oxide layer and the absorber layer which can allow more photons with energy above the window layer material's band gap to be absorbed.
The diffusion of the dopant can electrically passivate the junction between the transparent conducting oxide layer and the absorber layer to maintain open circuit voltage (Voc) and/or fill factor (FF), respectively. Improvements in carrier collection efficiency and/or reduction in open circuit resistance are responsible for improved fill factor. The window layer's spotty coverage of the adjacent transparent conductive oxide layer can increase the absorption of the blue spectrum of light in the absorber and hence increase the short circuit current of the photovoltaic device.
The dopant can include silicon, germanium, chlorine, or sodium, or any other suitable material. The step of doping the semiconductor absorber layer can include doping the semiconductor absorber layer to a dopant concentration in the range of 1015 to 1018 atoms/cm3 or 1016 to 1017 atoms/cm3, or any other suitable range or value. The semiconductor absorber layer can be doped by injecting a powder in a vapor transport deposition process, wherein the powder can include a blend of cadmium telluride powder and silicon powder with a dopant/absorber ratio anywhere up to 10,000 ppma. The semiconductor absorber layer can be doped after forming the semiconductor absorber layer. The thickness of the semiconductor absorber layer can be in the range of 0.5 micron to 7 microns. The method can further include an annealing step to promote the dopant diffusion. The anneal temperatures can be in the range of about 300 to about 500 degree C., for example about 400 to about 450 degree C., or any other suitable temperature or range. The step of annealing can include annealing the substrate in an environment including cadmium chloride. Alternatively, the semiconductor absorber layer can be doped by a suitable material after forming the semiconductor absorber layer. For example, the semiconductor absorber layer can be doped during annealing of the semiconductor absorber layer. The doping can occur at any suitable anneal temperature, for example in the range of about 300 to about 500 degree C.
Referring to
Window layer 131 can include a semiconductor material and absorber layer 132 can include a semiconductor material. Window layer 131 of semiconductor layer 130 can be deposited adjacent to transparent conductive oxide layer 120. Window layer 131 can include any suitable window material, such as cadmium sulfide, zinc sulfide, an alloy of cadmium sulfide and zinc sulfide, or any other suitable material. Window layer 131 can be deposited by any suitable deposition method, such as sputtering or vapor transport deposition. Absorber layer 132 can be deposited adjacent to window layer 131. Absorber layer 132 can be deposited on window layer 131. Absorber layer 132 can be any suitable absorber material, such as cadmium telluride, or cadmium zinc telluride, or any other suitable material. Absorber layer 132 can be deposited by any suitable method, such as sputtering or vapor transport deposition. TCO layer can include any suitable TCO material, including zinc oxide, tin oxide, cadmium stannate, or any other suitable material.
Window layer 131 can be thin, and/or non-conformal, and/or discontinuous, and can provide only 20 to 80% or 30 to 70% coverage of the underlying TCO layer, or any other suitable percentage of coverage of the TCO layer. The reduction of the window layer's thickness can improve the device quantum efficiency in the blue spectrum of light and hence increase its short circuit current. In some embodiments, the conversion efficiency of photovoltaic device 100 can be improved by doping the absorber layer with the intention to modify the morphology of the window layer. The increase in conversion efficiency can be driven by the simultaneous increases in short circuit current (Isc), fill factor (FF) and/or open circuit voltage (Voc). Change in the microstructure of window layer 131 from continuous to irregular or spotty can be made by doping absorber layer 132 with a dopant and diffusing the dopant to the absorber layer/window layer interface to partially flux the window layer away. The consumption of window layer 131 can result in junctions between the transparent conducting oxide layer 120 and absorber layer 132 allowing more photons with energy above the semiconductor window layer material's band gap to be absorbed. Diffusion of the dopant to the p-n heterointerface is necessary to electrically passivate the TCO/absorber junction to maintain Voc. Improvements in carrier collection efficiency and/or reduction in open circuit resistance result in higher fill factor. The dopant can include any suitable material. For example, the dopant can include silicon, germanium, chlorine, or sodium.
Back contact 140 can be deposited adjacent to absorber layer 132. Back contact 140 can be deposited adjacent to semiconductor layer 130. A back support 150 can be positioned adjacent to back contact 140. A photovoltaic device can have a cadmium sulfide (CdS) layer as a semiconductor window layer and a cadmium telluride (CdTe) layer as a semiconductor absorber layer. Window layer 131 can also include zinc sulfide (ZnS) or a ZnS/CdS alloy. Absorber layer 132 can include a cadmium-zinc-telluride (Cd—Zn—Te) alloy, a copper-indium-gallium-selenium (Cu—In—Ga—Se) alloy, or any other suitable material. The dopant can also be any suitable element known to interact and flux the window material.
In some embodiments, photovoltaic device 100 can also include a barrier layer between substrate 110 and transparent conductive oxide layer 120. The barrier layer can include silicon oxide or any other suitable material. In some embodiments, photovoltaic device 100 can also include a buffer layer between transparent conductive oxide layer 120 and window layer 131. The buffer layer can include tin oxide, zinc oxide, zinc tin oxide, cadmium zinc oxide, or any other suitable material.
In some embodiments, the disclosed invention can include a process depositing a thin film solar cell stack on a substrate configuration and where the absorber layer can be doped with a dopant such as Si, an annealing process that can drive the impurity toward the absorber/window interface, a reaction between the window and the dopant resulting in partial fluxing of the window layer material by the dopant, and a passivation mechanism for the TCO/absorber contacts.
If every incident photon on a solar cell generated an electron-hole pair, each of the photo carriers would make it to the depletion region where they could be separated and collected. Photons with energy less than the bandgap have insufficient energy to generate photo-carriers. Even if it has the sufficient energy, it need not contribute to the photocurrent. Quantum efficiency of a photon of certain wavelength is the probability that the photon contributes an electron to the photocurrent. It is the measure of the effectiveness of a device to produce electronic charge from incident photons. Quantum efficiency is expected to be zero for photons with energy less than the absorber bandgap. For photons with a larger energy, quantum efficiency can be as large as 100% but is often lower. One reason can be many photons that enter the top of the cell get adsorbed in the upper layers, never reaching the absorber layer below. This is true for heterojunctions and photons with energy larger than the bandgap of the TCO and window layer.
Referring to
Absorber layer 132 to include an amount of a dopant sufficient to increase the efficiency of the photovoltaic cell in absorbing photons, which can lead to a higher electrical power output. Any suitable dopant can be included in absorber layer 132, including silicon, germanium, chlorine, or sodium, or any other suitable dopant. The dopant material can be included in absorber layer 132 in any suitable amount. For example, the dopant material can be present in a concentration of in the range of 1015 to 1018 atoms/cm3 or 1016 to 1017 atoms/cm3, or any other suitable range or value.
Referring to
The photovoltaic device with reduced thickness window layer can have about 6 percent efficiency increase and 8 percent short circuit current (Isc) increase respectively compared to the control group. The equivalent uniform thickness of the semiconductor window layer can be less than 2500 angstroms, for example in the range of 200 angstroms to 2500 angstroms. The equivalent uniform thickness of the semiconductor window layer can be less than 1200 angstroms, for example in the range of 150 angstroms to 1200 angstroms, or 400 angstroms to 1200 angstroms. The equivalent uniform thickness of the semiconductor window layer can be less than 750 angstroms, for example in the range of 150 angstroms to 500 angstroms, 200 angstroms to 400 angstroms, or 300 angstroms to 350 angstroms, or any other suitable thickness.
In some embodiments, the conversion efficiency of a thin film photovoltaic device can be improved by doping the absorber layer with the intention to modify the morphology of the window layer. Change in the microstructure of the semiconductor window layer from continuous to irregular or spotty can be done by doping the absorber layer with a dopant and diffusing the dopant to the absorber/window layer interface to partially flux the window layer away. The consumption of the semiconductor window layer can result in junctions between the TCO and absorber allowing more photons with energy above the semiconductor window layer material's band gap to be absorbed. Diffusion of the dopant to the p-n heterointerface is necessary to electrically passivate the TCO/absorber junction to maintain Voc.
Improvements in carrier collection efficiency \and/or reduction in open circuit resistance result in higher fill factor. The dopant can include silicon. The dopant can include chlorine. The dopant can also be any suitable element known to interact and flux the window material. The step of doping the semiconductor absorber layer can include doping the semiconductor absorber layer to a dopant concentration in the range of 1015 to 1018 atoms/cm3 or 1016 to 1017 atoms/cm3, or any other suitable range or value. The absorber can be doped by injecting a powder in a vapor transport deposition or closed space sublimation system. The powder can include of a blend of CdTe powder and silicon powder. The dopant to absorber ratio can be up to 10,000 ppma, or 200 to 2,000 ppma, or any suitable ratio.
In some embodiments, a desired dopant depth profile in the absorber layer can have the dopant piling up deep into the absorber layer. The thickness of the absorber layer can be in the range of 0.5 micron to 7 microns. The thickness of the absorber layer can be about 2.6 microns. The dopant concentration can be in the range of 5×1016 to 5×1018 cm−3 in the bulk of the absorber further from the window layer. The dopant concentration can be in the range of 1017 to 1019 cm−3 in the bulk of the absorber layer closer to the window layer. A following annealing process can promote the diffusion and accumulation of the dopant near the CdS layer. The anneal temperatures can be any suitable temperature or range. For example, the anneal temperature can be in the range of 300 to 500 degree C. The anneal temperature can be in the range of 400 to 450 degree C. The anneal can be carried out in a suitable environment. For example, the anneal can be carried out in a cadmium chloride (CdCl2) environment.
The effect of absorber doping on the quantum efficiency (QE) can be clear. Improvements in blue (400-500 nm) and red (600-750 nm) absorption are visible in the cell having a doped absorber. The deposited CdS window layer thickness is the same in both the photovoltaic device with doped absorber layer and the control group. The most sizeable improvement can be in blue absorption (up to 30%) while the red absorption can increase by at most 5%. Both of these numbers depend on the silicon concentration in CdTe absorber. The device short circuit current (Isc) and efficiency can increase resulting from structural modifications brought to the CdS window layer as an effect of Si doping of CdTe absorber layer.
Referring to
A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. It should also be understood that the appended drawings are not necessarily to scale, presenting a somewhat simplified representation of various preferred features illustrative of the basic principles of the invention.
This application claims priority to U.S. Provisional Patent Application No. 61/286,630, filed on Dec. 15, 2009, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61286630 | Dec 2009 | US |