An apparatus for converting infrared radiation into electric current
1. Field of the Invention
The invention relates to an apparatus for converting infrared radiation into electric current with a photodiode which comprises two semiconductor layers with a heterojunction which are each connected to an electrode and of which one consists of a doped inorganic semiconductor.
2. Description of the Prior Art
Photodiodes for converting infrared radiation into electric current are known in different embodiments. Indium-gallium-arsenide detectors are characterized for example by a comparatively high sensitivity in the infrared range, whereas platinum-silicide detectors are especially suitable for local resolution of infrared radiations in a two-dimensional arrangement, as is demanded in infrared cameras. The disadvantageous aspect in indium-gallium-arsenide detectors is especially the need for space, and in platinum-silicide detectors the low sensitivity.
The invention is thus based on the object of arranging an apparatus of the kind mentioned above for converting infrared radiation into electric current in such a way that the requirements both concerning a compact two-dimensional arrangement and concerning high sensitivity can be combined with one another advantageously.
This object is achieved by the invention in such a way that the inorganic semi-conductor layer forms the heterojunction with an organic semiconductor layer and a cooling device is associated with the two semiconductor layers.
As a result of this measure, it is surprisingly possible to ensure a high sensitivity of the photocurrent in relation to the exciting radiation despite the simple compact configuration of the photodiode, especially in the middle infrared range, which is only possible however when the photodiode is cool in a respective fashion. Photodiodes with the heterojunction between an inorganic semiconductor and an organic semiconductor have already been proposed for photovoltaic purposes (JP 06244440 A). However, it is not possible to determine any dependence on infrared radiation for the photocurrent of these voltaic photodiodes. This is surprisingly only possible when the semiconductor layers are cooled. The photocurrent which is based on an absorption of the radiation in the infrared range will rise with increasing cooling and can be utilized for detecting infrared radiation. At room temperature, only the photocurrent is measured which is excited directly by the radiation absorption in the inorganic semiconductor layer and thus dependent on the band gap of the inorganic semiconductor, whereas at low temperatures the charge carriers excited by the infrared radiation pass increasingly from the valence band of the inorganic semiconductor to the conduction band organic semiconductor and from the bound state in the organic semiconductor into its conduction band and are discharged via the connected electrode as a result of the effective electric field.
Although different inorganic and organic semiconductors can be used for arranging a photodiode in accordance with the invention, since especially the relationship of the band gap of the doped inorganic semiconductor to the energy barrier between the valence band of the inorganic semiconductor and the conduction band of the organic semiconductor and the electronic structure of the organic semiconductor is relevant, especially simple constructional conditions are obtained when the inorganic semiconductor layer consists of a p-doped silicon layer which preferably forms a heterojunction with an organic semiconductor layer on the basis of a fullerene. If a fullerene derivative such as a soluble PCBM is used in this context as an organic semiconductor for example, the fullerene derivative can be applied in a spin coating as a thin film on a p-doped silicon substrate in a simple manner.
In order to cool the photodiode in accordance with the invention, different measures can be taken. If direct cooling is to be provided, the use of Peltier elements is recommended.
The subject matter of the invention is shown by way of example in the drawings, wherein:
As can be seen from
It is thus clear that following a cooling of the photodiode in accordance with the application the infrared range can be detected with a high sensitivity, which occurs with a simple diode configuration, preferably on a silicon substrate.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/AT2007/000402 | 8/23/2007 | WO | 00 | 2/17/2010 |