The present invention concerns a photoactive nanocomposite capable of being used in a solar cell to induce the photovoltaic effect, in a light emitter or in a photodetector.
This type of photoactive component conventionally comprises a donor-acceptor couple of semiconductor elements. It is known that to see a charge transfer between donor and acceptor, the respective energy levels of the former and the latter must be compatible.
Photovoltaic devices based on amorphous or thin film microcrystalline silicon are familiar. These devices deliver a significant output of 6 to 10%. However, they are not very stable (ageing). Materials of the interpenetrating network type—conjugated polymer and fullerene or its derivatives—are also familiar. The usefulness of these systems is limited in particular by the flow of charge in organic materials. Indeed, in most organic conductors, charge mobility is poor (less than 10−4 cm2Vs−1) because of the presence of charge traps such as oxygen. Furthermore, they are not very stable in air. A way of addressing this limitation in charge flow is to combine, for example, a conjugated polymer electron donor with an inorganic semi-conductor as the electron acceptor. The present invention concerns a new type of interpenetrating network including an organic compound and silicon nanowires. The organic compound may be an electron donor or acceptor and the silicon nanowires an electron acceptor or donor. The development of solar cells using such a material has not been considered to date.
Currently, entirely organic solar cells, which use an active material in interpenetrating networks, made of a mixture of conjugated polymer such as polyphenylenevinylene (donor), a fullerene derivative (acceptor), show photovoltaic conversion output of more than 3%, with a life of one hundred hours in controlled light and atmospheric conditions.
According to the invention, it is proposed to produce a photoactive nanocomposite comprising at least a donor-acceptor couple of semiconductor elements.
One of the elements is made of doped nanowires with sp3 structure.
The other of the elements is an organic compound.
These elements are supported by a device substrate.
In different preferred embodiments, each offering specific advantages, the said nanowires have the following characteristics:
The invention also concerns the production method for this photoactive nanocomposite component.
In general,
Different versions of this procedure, each with specific advantages, are proposed:
In the two aforementioned cases the nanowires are functionalised.
The substrate of the conductive device is either a silicon substrate or a glass substrate on which a conductive transparent oxide layer has been deposited.
Different versions of the device are proposed:
The growth substrate becomes the device substrate.
The invention will be precisely described with reference to drawings in which:
The photoactive nanocomposite 3 of the invention comprises a donor-acceptor couple of semiconductor elements. One of these elements is made of nanowires 7 with an sp3 structure, the other of these elements being a conjugated polymer 8.
More particularly it will describe such a photoactive nanocomposite 3 used to produce a photovoltaic cell.
In the
The nanowires 7 of nanocomposite 3 are electron acceptors (n Si) and the polymer element 8 is the electron donor (Regioregular polyhexylthiophene (P3HT)).
In a first embodiment, the data shown in
In a second embodiment, the active layer 3 is placed between a tin doped indium oxide (ITO) electrode 2 and a gold electrode 10,
To optimise output of the cell, the materials used must be optimised. The following parameters can be adjusted:
1°—Doping of the nanowires: knowing the HOMO (High Occupied Molecular Orbital) and LUMO (Low Unoccupied Molecular Orbital) levels of Regioregular P3HT, the Fermi level of the nanowires 7 is altered by determining the dopant concentration for the silicon. The silicon nanowires 7 must be doped p-type electron acceptors (since the P3HT is an n-type electron donor).
2°—The nanowire diameter: it is known that the energy band gap varies as a function of nanowire 7 diameter. For diameters of more than about 3 nanometres, the properties of the nanowires 7 are those of solid material. As the diameter decreases, the energy of the gap increases. It is more than 3 electron-volt/eV for a diameter less than 1 nm.
3°—Solubilisation and impregnation of nanowires: to guarantee good contact between the nanowires 7 and the polymer 8, it is preferable to functionalise the surface of the nanowires 7, which is achieved by surface treatment. This surface treatment can be electrograffing, or chemical or thermal or photochemical grafting.
In all embodiments, nanowires 7 are produced. To this end, as in the diagram shown in
The nucleation and growth of the silicon nanowires 7 is then achieved by a process of chemical deposition in the vapour phase. This bonding mechanism has temperatures higher than the gold-silicon eutectic temperature (375° C.). Indeed, under these conditions, when the deposited atoms of silicon hit the surface of the growth substrate 5 they diffuse across the gold and precipitate at the gold/substrate interface. The diameter of the nanowires 7 is determined by the size of the gold aggregates. So it is possible to make the nanowires 7 grow perpendicular to the surface of the growth substrate 5 and, when the substrate itself is composed of crystalline silicon, preferably in the same crystalline orientation. It is also possible to make nanowires 7 by filling a previously gold plated nanoporous aluminium oxide membrane; the membrane is then chemically dissolved.
After making the nanowires 7 the gold is dissolved.
In a first embodiment shown schematically in
The proportion by weight of nanowires 7 in the polymer 8 is optimised. The photo-induced absorption and luminescence quenching of the interpenetrating network mixtures at different ratios allows characterisation of the charge transfers produced in the material.
Regioregular P3HT is advantageously polymer 8.
In a second embodiment, drawn schematically in
Number | Date | Country | Kind |
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0451607 | Jul 2004 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR05/50605 | 7/21/2005 | WO | 3/26/2007 |