WO2012028137A2 - Double-sided solar cell - Google Patents

Abstract

In the case of a double-sided solar cell, which has at least a transparent substrate (1) on which a TCO layer is arranged as first contact (2), on which there is located an active layer (4) which is provided with a further TCO layer as second contact (5), metal oxide nanorods (3) having a cross section tapering in the direction of the second contact (5) are arranged according to the invention in the active layer (4), wherein the base area of the metal oxide nanorods (3) with the larger cross section rests directly against the first contact (2) and the active layer (4) covers the entire height of the metal oxide nanorods (3), wherein the tips of the metal oxide nanorods (3) form point contacts.

Description

 description

Two-sided solar cell

description

The invention relates to a two-sided solar cell, at least comprising a transparent substrate, on which a TCO layer is arranged as the first contact, on which there is an active layer, which is provided with a further TCO layer as a second contact.

Such a two-sided solar cell is described in GB 2 405 030 A.

Adjacent to a pn junction, on the one side, a TCO layer is arranged as a front contact, which is arranged on a transparent substrate. On the other side of the pn junction another TCO layer is arranged, which forms the back contact. Thus, this solar cell can also be irradiated from the back with light. The two-sided irradiation of light improves the efficiency of the solar cell. The reflectivity at the interface TCO layer / absorber layer is still very high.

Applied Physics Letters 93, 053113 (208) reports on the investigation of ZnO nanorod device arrangements with a well-defined morphology as a substrate for solar cells with extremely thin absorber layer (eta solar cells). In this case, the ZnO nanorods are covered with ln ₂ S3 as the absorber material, on which CuSCN is then located as a hole conductor.

An improved light coupling in silicon thin-film solar cells by textured ZnO is described in FVS Themen 2000, p. 97 ff. The texturing increases the optical light path and the absorption, which is necessary in particular for a superstrate solar cell in addition to the transparency and high conductivity of the TCO layer. The textured surface the sputtered ZnO layers are produced in a wet chemical etching step.

In dye-sensitized solar cells known since 1991 in which a transparent conductive oxide whose bandgap is too large to absorb visible light is sensitized by a dye absorbing in the visible wavelength range, nanostructures such as .alpha. Are used to improve charge transport in the photoelectrode z. ZnO nanorods and filaments and TiO ₂ nanotubes. In Appl. Phys. Lett. 96, 073115 (2010) describes a hybrid photoanode in which ZnO nanofibers act as a direct pathway for fast electron transport and ZnO nanoparticles fill in the voids between the filaments, forming a larger surface area for sufficient dye adsorption. 21-23 November 2006, Bangkok, Thailand, B-024 (O) describes a dye-sensitized solar cell based on ZnO nanorod arrays - without nanoparticles - in The 2nd Joint International Conference on Sustainable Energy and Environment (SEE 2006) For example, the ZnO nanorods with a hexagonal cross-section are grown very close to a fluorine-doped SnO ₂ substrate, and as the length of the ZnO nanorods increases, the surface area increases, more dye is adsorbed, and the efficiency of the solar cell is increased

International Journal of Photoenergy, Volume 2010, Article ID 497095 has no TCO layer on which the ZnO nanorods are grown. Rather, these are now deposited directly on a ZnO film. This is intended to reduce the disadvantages caused by the formation of interfaces between the nanorod and the TCO layer.

In Nano Lett., Vol. 8, no. 5, 2008, 1501-1505, ZnO nanostructures are described as efficient antireflection layers. The ZnO nanostructures are needle-shaped, ie they have a tip. By defined parameters when growing the nanorods their length and shape becomes influenced their peak, which is to reduce the reflection. The ZnO nanorods are applied, for example, on silicon, between them is air. In the photovoltaic cell described in WO 2009/116018 A2-both in substrate and in superstrate arrangement-a first transparent conductive layer of this layer has protruding structures of the material of the first-mentioned layer. An Si absorber layer is deposited thereon in accordance with the structure.

In US 2009/0242029 A1 is a photovoltaic device in

Substrate arrangement described in which the absorber layer of

Semiconductor material of group II-VI and / or the interface layer between absorber and window layer nanoparticles or sintered

Contains nanoparticles. The nanoparticles can be shaped differently, for example spherically, as nanofilaments or rods, and made of different materials, such as. B. materials of groups M-Vl or NINA exist. The object of the invention is now to provide a further two-sided solar cell, which has an improved compared to the prior art or at least comparable efficiency, but less

Absorbermate rial needed and less expensive to manufacture. According to the invention this object is achieved in a two-sided solar cell of the type mentioned in that in the active layer

Metal oxide nanorods are arranged with tapered cross section in the direction of the second contact, wherein the base of the metal oxide nanorods with the larger cross section is applied directly to the first contact, and the active layer completely covers the height of the metal oxide nanorods. By arranging the nanorods in the active layer, the latter is textured, which allows a finely adjustable change in the refractive index of the active layer over its thickness, reduces the unwanted reflection at the TCO layer / active layer interface, and improves the efficiency. The result is a so-called sub-wavelength structure. With this arrangement - in comparison to the prior art - absorber material is saved. The hitherto customary buffer layer between the conductive transparent layer and the active layer, which in one

Superstrate arrangement to reduce the reflection between the TCO layer and the active layer, so that is no longer necessary. The tips of the metal oxide nanorods in the active layer form point contacts. These are closely adjacent to the region of the array in which the charge carriers are generated, thereby improving charge transport. The arrangement according to the invention also enables the two-sided irradiation of light into the solar cell.

In one embodiment, it is intended to form the metal oxide nanorods of ZnO or T1O2 or MgO or ZnMgO.

A further embodiment provides for forming the conductive transparent layer and the further transparent layer from one of the following materials FTO or ITO or AZO. Both contact materials should have one

Resistance of about 10 Ω to some 10 Ω have.

In another embodiment, the active layer is formed of Si or a chalcogenide semiconductor material (such as CdTe, CIGS) or an organic material. This may be a p-Si layer or a pn junction forming p and n-Si layer.

Depending on the application, the cross section of the nanorods, which tapers in the direction of the metal contact, can change continuously or stepwise. The nanorods have a length of a few hundred nm to a few μιη, a Diameter of several tens nm to several hundred nm and a distance from each other from 50 to 2,000 nm.

Furthermore, it is provided in the arrangement of metal oxide nanorods that there is an additional seed layer for the application of the metal oxide nanorods on the conductive transparent layer, by which the growth of the metal oxide nanorods is supported.

An additional layer may be located on the TCO layer for the first contact as a template for the application of the metal oxide nanorods. This can be formed, for example, of anodic aluminum oxide (AAO) or a structured photoresist and on the one hand affects the density of the metal oxide nanorods to be applied and, on the other hand, their vertical alignment during growth.

The next embodiments relate to further optional layers which, by virtue of their special function, are intended to bring about a further improvement in the effect of the active layer comprising metal oxide nanorods according to the invention.

Thus, an insulating layer is disposed between metal oxide nanorods and active layer formed of, for example, anodic aluminum oxide (AAO) or Al 2 O ₃ or a patterned photoresist or MgO, exposing the tip of the metal oxide nanorods. This layer should avoid a short circuit between the first contact and the active layer.

A passivation layer, for example Al ₂ O ₃ , arranged between metal oxide nanorods and active layer is intended to passivate the surface states of the metal oxide nanorods. The same result can be achieved with a plasma treatment of the grown metal oxide nanorods. Another additional layer disposed between metal oxide nanorods and active layer, a buffer layer, serves for better band matching of these two layers, in particular when the active layer is formed from a chalcogenide semiconductor material. This layer may vary depending on the materials for the metal oxide nanorods and the active Layer be for example Al ₂ 0 ₃ or ZnMgO or CdS.

Depending on the material of the active layer, this can with the

Metal oxide nanorods form a Schottky contact. To form an ohmic contact between metal oxide nanorods and active layer, a functional layer is provided, for example, the metal oxide nanorods arranged in a CIGS absorber are covered with a Mo-NaF layer.

Of course, one of these optionally provided additional layers can fulfill several functions.

The nanorods can be applied by known methods according to the prior art. Examples are the following

Publications mentioned: Appl. Phys. Lett. 92, 161906 (2008) and WO 2009/103286 A2 concerning electrochemical deposition and Chem. Mater. 2005, 17, 1001 -1006, where further possibilities for the growth of nanorods are mentioned.

The invention will be described in more detail in the following Ausführungsbetspiel reference to figures.

Show

Fig. 1: a SEM image of a ZnO-Nanstäbchen arrangement on a ZnO-AI surface in cross section; Fig. 2: a schematic representation of the invention

 Arrangement also in cross section.

The ZnO nanorods in the photograph shown in Fig. 1 were by means of an electrode position method - as already mentioned in the

WO 2009/103286 A2 - produced, wherein the production of nanostructured ZnO with a high internal quantum efficiency (IQE) without additional annealing step takes place. In this electro-deposition process, an aqueous solution of a Zn salt, such as Zn (N0 _3> 2, and a dopant, for example, HNO ₃ or NH ₄ NO _3, is used.

An arrangement of ZnO nanorods in cross-section shown in FIG. 1 serves as the basis for the production of the superstrate solar cell arrangement according to the invention in cross section, as shown in FIG.

In this case, on a glass substrate 1, a conductive transparent layer as the first contact 2, here ZnO: AI with a thickness of 800 nm, arranged. On this layer 2 there are ZnO nanorods 3 with a length of 400 nm, which were produced as described above. These ZnO nanorods 3 have a cross section tapering in the direction of the second contact 5 (from 300 nm to 40 nm). The ZnO nanorods 3 are completely filled with a Si

Layer 4 covered, which has a thickness of 500 nm. The back contact 5 is formed of AZO with a thickness of 800 nm.

The reflection index of the textured Si absorber layer 4 in this superstrate arrangement changes from about 2 at the interface ZnO: Al layer 2 and Si absorber layer 4 to approximately 3.2 at the interface Si absorber layer 4 and second contact 5.

A two-sided solar cell according to the invention can be used in a tandem arrangement and in a stacked structure for solar cells.

Claims

claims 1. Two-sided solar cell, at least comprising a transparent substrate, on which a TCO layer is arranged as a first contact, on which there is an active layer, which is provided with a further TCO layer as a second contact, characterized in that in the active layer (4) metal oxide nanorods (3) are arranged in the direction of the second contact (5) of tapered cross-section, wherein the base of the metal oxide nanorods (3) with the larger cross-section directly against the first contact (2), and the active layer (4) completely covers the height of the metal oxide nanorods (3), the tips of the metal oxide nanorods (3) forming point contacts. 2. Two-sided solar cell according to claim 1, characterized in that the metal oxide nanorods (3) are formed of ZnO or T1O2 or MgO or ZnMgO. 3. Two-sided solar cell according to claim 1, characterized in that the TCO layer for the first contact (2) or the second contact (5) is formed from one of the following materials FTO or ITO or AZO. 4. Two-sided solar cell according to claim 1, characterized in that the active layer (4) is formed of Si or a Chalcogenide semiconductor material or an organic material. 5. Two-sided solar cell according to claim 1, characterized in that the continuously tapering cross section of the metal oxide nanorods (3) in the direction of the second contact (5). 6. Two-sided solar cell according to claim 1, characterized in that the step of tapering in the direction of the second contact (5) cross section of the metal oxide nanorods (3). 7. Two-sided solar cell according to claim 1, characterized in that the metal oxide nanorods (3) have a length of a few hundred nm to a few μm, a diameter of several tens nm to several hundreds nm, and a distance from each other of 50 to 2,000 nm. 8. Two-sided solar cell according to claim 1 and 2, characterized in that on the TCO layer for the first contact (2) is a seed layer for the deposition of the metal oxide nanorods (3). 9. Two-sided solar cell according to claim 1, characterized in that on the TCO layer for the first contact (2) is an additional layer as a template for the application of the metal oxide nanorods (3). 10. Two-sided solar cell according to claim 1, characterized in that between metal oxide nanorods (3) and active layer (4) a Insulation layer is arranged, wherein the tip of the metal oxide nanorods (3) is exposed. 11. Two-sided solar cell according to claim 1, characterized in that between metal oxide nanorods (3) and active layer (4) a Passivation layer is arranged. 12. Two-sided solar cell according to claim 1, characterized in that between metal oxide nanorods (3) and active layer (4) a buffer layer for improving the band matching of these two layers is arranged. 13. Two-sided solar cell according to claim 1, characterized in that between metal oxide nanorods (3) and active layer (4) a layer for forming an ohmic contact is arranged.