Batteries: thermoelectric and photoelectric – Photoelectric – Cells
Reexamination Certificate
2000-09-15
2002-01-22
Diamond, Alan (Department: 1753)
Batteries: thermoelectric and photoelectric
Photoelectric
Cells
C136S255000, C136S261000, C136S256000, C257S040000, C257S431000, C257S458000, C438S082000, C438S089000, C438S057000, C438S099000
Reexamination Certificate
active
06340789
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to optically absorptive photonic devices and in particular photovoltaic and photoconductive devices and their formation. Embodiments of the invention relate particularly to devices formed from multiple semiconducting layers, preferably composed of organic semiconducting polymers.
BACKGROUND OF THE INVENTION
Semiconductive photovoltaic devices are based on the separation of electron-hole pairs formed following the absorption of a photon. An electric field is generally used for the separation. The electric field may arise from a Schottky contact where a built-in potential exists at a metal-semiconductor interface or from a pn junction between p-type and n-type semiconductive materials. Such devices are commonly made from inorganic semiconductors especially silicon which is used in monocrystalline, polycrystalline or amorphous forms. Silicon is normally chosen because of its high conversion efficiencies and the large industrial investments which have already been made in silicon technology. However, silicon technology has associated high costs and complex manufacturing process steps resulting in devices which are expensive in relation to the power they produce.
“Two-layer organic photovoltaic cell”, Applied Physics Letters 48(2), Jan. 13, 1986, C. W. Tang, U.S. Pat. No. 4,164,431 and U.S. Pat. No. 4,281,053 describe multi-layer organic photovoltaic elements. These devices are formed in a layer by layer fashion. A first organic semiconductive layer is deposited on an electrode, a second organic semiconductive layer is deposited on the first organic layer and an electrode is deposited on the second organic layer. The first and second organic semiconductive layers are electron acceptors and hole acceptors. In the following, an “electron accepting material” refers to a material which due to a higher electron affinity compared to another material is capable of accepting an electron from that material. A “hole accepting material” is a material which due to a smaller ionisation potential compared to another material is capable of accepting holes from that other material. The absorption of light in organic photoconductive materials results in the creation of bound electron-hole pairs, which need to be dissociated before charge collection can take place. The material considerations for organic devices are different compared to inorganic devices, where the electron and holes created by the absorption of a photon are only weakly bound. The dissociation of the bound electron-hole pair is facilitated by the interface between the layer of material which acts as a hole acceptor and the layer of semiconductive material which acts as an electron acceptor. The holes and electrons travel through their respective acceptor materials to be collected at the electrodes.
The designing of photovoltaic devices which are fabricated in a layer by layer fashion is limited. When one organic layer is deposited on top of another organic layer, the second layer must be added in such a way that the previously deposited layer is not affected in a detrimental way. Consequently solvents used for subsequent layers are limited in order not to dissolve the previous layer completely or destroy it in other ways. “Efficient photodiodes from interpenetrating polymer networks”, Nature, vol 376, Aug. 10, 1995, page 498-500, J. J. M. Halls et al, and U.S. Pat. No. 5,670,791 describe the formation of a photovoltaic device by depositing a single layer comprising a blend of first and second semiconductive polymers and the deposition of a second electrode on top of that layer. The first semiconductive polymer acts as a electron acceptor and the second semiconductive polymer acts as a hole acceptor. The first and second semiconductive polymers form respective continuous networks that interpenetrate so that there is a continuous path through each of the semiconductive polymers and a charge carrier within one of the first and second semiconductive polymers can travel between the first and second electrodes without having to cross into the other semiconductive polymer. However, these devices do not show the high efficiency that would be expected if the devices worked as ideally envisaged. This may be due to the fact that it is likely that at least one of the polymers can extend through the whole device, thereby creating a parallel system of single material diodes.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide an improved photovoltaic device.
According to a first aspect of the invention there is provided a method of forming a photovoltaic or photoconducting device comprising the laminating together of a first component having a first electrode and a first semiconductive layer predominantly comprising a first semiconductive material, and a second component having a second electrode and a second semiconductive layer predominantly comprising a second semiconductive material, wherein the laminating step involves the controlled joining of said first semiconductive layer and said second semiconductive layer to form a mixed layer comprising proportionally less of said first semiconductive material than said first semiconductive layer and proportionally less of said second semiconductive material than said second semiconductive layer while retaining said first and second semiconductive layers with a reduced thickness.
According to another aspect of the invention there is provided a method of designing and creating a photovoltaic or photoconducting device comprising the steps of: choosing first and second semiconductive materials on the basis of their electronic properties so that said first semiconductive material acts as an electron donor and said second semiconductive material acts as an electron acceptor; forming a first component comprising a first electrode and a first semiconductive layer predominantly comprising said first semiconductive material; forming a second component comprising a second electrode and a second semiconductive layer predominantly comprising said second semiconductive material; and joining the first component to the second component by laminating said first semiconductive layer to said second semiconductive layer. The laminating step may involve the controlled joining of said first semiconductive layer and said second semiconductive layer to form a mixed layer comprising proportionally less of said first semiconductive material than said first semiconductive layer and proportionally less of said second semiconductive layer while retaining said first and second semiconductive layers with a reduced thickness.
Laminating may comprise the application of pressure or heat or pressure and heat. If heat is applied it may involve heating one or both of the semiconductive layers above their glass transition temperatures. The semiconductive layers may be individually treated before lamination, for example by organic or inorganic doping. Such treatment may vary the morphology, the light-absorption characteristics, the transport properties or the injection properties of one or both semiconductive layers. The thickness of the semiconductive layers before lamination may be controlled, for example by spin coating a solution of semiconductive material. Furthermore the thickness of the mixed layer and/or the thickness of the first and second semiconductive layers remaining may be controlled, for example by annealing.
According to a further aspect of the invention there is provided a photovoltaic or photoconducting device comprising: a first electrode; a first semiconductive layer, predominantly comprising a first semiconductive material, over at least part of said first electrode; a mixed layer over said first semiconductive layer; a second semiconductive layer, predominantly comprising a second semiconductive material,over said mixed layer; and a second electrode over at least part of said second semiconductive layer, wherein said mixed layer is connected with the first and second semiconductive layers and has proportionally less of said first semico
Granstrom Magnus
Petritsch Klaus
Cambridge Display Technology Limited
Diamond Alan
Finnegan Henderson Farabow Garrett & Dunner L.L.P.
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