The present invention relates generally to solar cells, and more particularly, to a solar cell for increasing power conversion efficiency and fabrication method thereof.
In recent years, human beings are facing the crisis of energy shortage and global warming, and the development of solar power are getting more and more attention. At present, solar cells are primarily composed of single crystalline silicon and polysilicon, and the energy is mainly generated based on the photo-conductive effect and the internal electric field, in which the photo-conductive effect refers to a phenomenon of the light facilitating the electric conductivity.
When an electron acquires enough energy to break away from its atom, the electron becomes a free electron and leaves behind a vacancy what is called a hole. In general, the more the number of free electrons and holes, the better the electric conductivity, which increases an output current. Therefore, when the sunlight is stronger, the more number the free electrons and holes are formed, and the output current thus becomes larger.
If there are merely the free electrons and holes being produced, they will lose the energy owing to factors, such as collision, and recombine with each other with no use. By introducing an electric field, the free electrons and holes can be separated and electric current can be generated, so as to effectively take advantage of the free electrons and holes. There are numerous ways of generating the electric field, such as: a PN junction, or metal semiconductor junction, and the like, in which the most commonly method is the PN junction.
An n-type semiconductor is produced when a pentavalent impurity is added into a silicon crystal, and a p-type semiconductor is produced when a trivalent impurity is added into a silicon crystal. If the n-type and p-type semiconductors contact with each other and form the PN junction, the diffusion occurs across the junction since the concentrations of these two semiconductors are different. In other words, the free electrons diffuse from the n-type semiconductor to the p-type semiconductor, and the holes diffuse from the p-type semiconductor to n-type semiconductor, such that the n-type semiconductor near the junction losing electrons becomes positively charged, and the p-type semiconductor gaining electrons becomes negatively charged.
As the charge density is not uniform, the electric field occurs near the PN junction. If the free electrons or holes are generated in the electric field due to the electric field, the free electrons move toward the n-type semiconductor, while the holes move toward the p-type semiconductor. As such, there will be a region called a depletion zone because of depleting free charge carriers.
The photoelectric effect refers to a principle of photoelectric power conversion. While the light is incident upon the depletion zone and exciting electrons of the silicon atom to generate free electrons and holes, the charges in the solar cell will move towards to two ends away from the junction under the electric field; therefore, energy in the cell can be used by connecting a circuit to the ends.
In the art as disclosed in U.S. Pat. No. 4,281,053, an organic solar cell with two layers PN junction structure is fabricated by vapor deposition. However, the area of the PN junction is not large enough to effectively increase the output current.
Therefore, a solar cell has been developed in the art, referring to
However, in the conventional solar cell 1, since the p-type semiconductor layer 13 is required to have the capability of both high carrier mobility and strong light-absorbing capability, the probability of carrier recombination cannot be reduced which significantly causes loss in power conversion, but also the difficulty of the material design and synthesis is still introduced.
Furthermore, an organic solar cell has been developed using bulk heterojunction structure (referring to High-efficiency solution processable polymer photovoltaic cells by self-organization of polymer blends, vol. 4, the Natural Materials, November 2005), in which the components of the n-type and p-type semiconductor layers are uniformly combined to overcome the complexity in material design and synthesis issues, and thus to improve the power conversion efficiency. Nevertheless, since the p-type semiconductor layer is still required to have the capability of both high carrier mobility and strong light-absorbing capability, the carriers will still tend to recombine after the separation of electrons and holes during the conduction, and thereby to result in energy loss.
Afterwards, an organic solar cell has been developed (referring to
However, since the p-type semiconductor layer is required to have the capability of both high carrier mobility and strong light-absorbing capability, the carriers will still recombine, after their separation, during the conduction and leading to energy loss.
From the foregoing, although either scholars or industry are constantly looking for ways to enhance power conversion efficiency, the problem of “the carriers recombine after their separation during the conduction and leading to energy loss” are not resolved, and thus are incapable of significantly enhancing the power conversion efficiency of the solar cell. In this regard, it has become an important issue in effectively improving the energy loss of the solar cell for enhancing the conversion efficiency of the solar cell.
In view of the above-mentioned disadvantages of the prior techniques, an embodiment of the present invention is to provide a solar cell having a first electrode layer; a n-type semiconductor layer; a light absorber; a p-type semiconductor layer, and a second electrode layer. The light absorber is disposed between the n-type semiconductor layer and the p-type semiconductor layer for absorbing light energy, so that the p-type semiconductor layer is not required to absorb light, that is, the p-type semiconductor layer is only required to have the high carrier mobility without having strong light-absorbing capability. As such, the probability of carrier recombination during conduction can be avoided and energy loss can be reduced.
In the aforementioned solar cell, the thickness of the light absorber is less than the thickness of the n-type semiconductor layer and the thickness of the p-type semiconductor layer. The n-type semiconductor layer is made of an inorganic material and the p-type semiconductor layer is made of an organic material, or the n-type semiconductor layer is made of an organic material and the p-type semiconductor layer is made of an inorganic material.
Furthermore, to increase the area of the PN junction, a plurality of recesses, such as a porous structure, are formed on a surface of the n-type semiconductor layer contacting the light absorber, and the light absorber is formed in the recesses.
Also, the dopant can be added to the n-type semiconductor layer or the p-type semiconductor layer for enhancing the conductivity.
In addition, the invention provides a fabrication method of a solar cell, which will be described as follows.
The following illustrative embodiments are provided to illustrate the present invention, and these and other advantages and effects can be apparently understood by those in the art after reading the present invention. The present invention can also be performed or applied by other different embodiments. The details of the specification may be carried out based on different points and applications, and numerous modifications and variations can be devised without departing from the spirit of the present invention.
Furthermore, the present invention of the instructions are simplified schematic diagram, only indicate the basic technical idea of the present invention, so the actual implementation of each component type, quantity and proportion of visual implementation of the requirements change.
Referring to
In an embodiment of the present invention as shown in
Since the solar cell 2 mainly absorbs solar energy by the light absorber 25, and the p-type semiconductor layer 23 and the n-type semiconductor layer 22 are not necessarily to absorb light, as far as the material is considered, a significant difference in capability of absorbing solar light between the p-type semiconductor layer 23 (and n-type semiconductor layer 22) and the absorber 25 is required. For example, the light absorptance of the light absorber 25 is at least about 100 times greater than the p-type semiconductor layer 23 and the n-type semiconductor layer 22, so as to prevent the p-type semiconductor layer 23 and the n-type semiconductor layer 22 from absorbing solar energy. Furthermore, the equation of light absorption A=α·L shows that (where A is intensity, α is absorb coefficient, and L is thickness) the light absorber 25 may choose a material with α much larger than those of the p-type semiconductor layer 23 and the n-type semiconductor layer 22.
Typically, the n-type semiconductor layer 22 of the solar cell 2 may be made of an inorganic material and the p-type semiconductor layer 23 may be made of an organic material, or the n-type semiconductor layer 22 may be made of an organic material and the p-type semiconductor layer 23 may be made of an inorganic material. For example, in the manufacture, because zinc oxide (ZnO) and TFB material (poly(9,9′-dioctylfluorene-co-N (4-butylphenyl)diphenylamine) both have the feature of insignificantly absorption of solar light with a wavelength above 400 nm, each of them can be used for forming the n-type semiconductor layer 22 and p-type semiconductor layer 23, respectively, As such, the n-type semiconductor layer 22 and p-type semiconductor layer 23 do not significantly absorb solar energy, and, when the thicknesses of the ZnO layer and the TFB layer are larger than 400 nm, the feature of insignificant absorption of solar light with the wavelength above 400 nm becomes even more obvious.
Furthermore, in an embodiment of the present invention, since the poly(3-hexylthiophene) (P3HT) or the lead phthalocyanine (PbPC) has the feature of significantly absorbing solar light, both of them can be used as the material of the light absorber 25 for significantly absorbing solar energy.
Therefore, as the material of both the p-type semiconductor layer 23 and the n-type semiconductor layer 22 is different from that of the light absorber 25, the p-type semiconductor layer 23 and the n-type semiconductor layer 22 only absorb relatively a small amount of light, and most of the light is absorbed by the light absorber 25.
Further, concerning the band of energy, after the light absorber 25 absorbs the carrier, the electrons and holes can effectively get into the n-type semiconductor layer 22 and p-type semiconductor layer 23, respectively. That is, there should be no energy barrier between the conduction band of the light absorber 25 and the conduction band of the n-type semiconductor layer 22 or the energy barrier between the conduction band of the light absorber 25 and the conduction band of the n-type semiconductor layer 22 should not be too high, same as that between the light absorber 25 and the p-type semiconductor layer 23.
In this regard, the thickness of the light absorber 25 should not be too thick, in order to avoid recombination after generating the photons (or the photons can not be moved to the n-type semiconductor layer 22 and p-type semiconductor layer 23). Therefore, the thickness of the light absorber 25 is required to be less than the mean free path length of the electron and hole in the light absorber 25, for example, the thickness of the light absorber 25 is less than 30 nm.
If the thickness of the light absorber 25 is too small, e.g., less than the diffusion length thereof, a large number of photons will directly penetrate through the entire structure of the solar cell 2 and reduce the power conversion efficiency. Therefore, when the thickness of the light absorber 25 is approximately equal to the diffusion length of the excitons (i.e., 17 nm), the power conversion efficiency of the solar cell 2 is optimized, such that the thickness of the light absorber 25 is preferred to be about 16 nm. The thickness of the light absorber 25 may be adjusted depending on the material selected and is not limited to the above; however, the thickness of the light absorber 25 is extremely thin relative to the thickness of the n-type semiconductor layer 22 and p-type semiconductor layer 23.
In addition, in terms of energy level, a lowest unoccupied level (i.e., the lowest unoccupied molecular orbital, LUMO) of the light absorber 25 is positioned between a conduction band of the n-type semiconductor layer 22 and a conduction band of the p-type semiconductor layer 23, and a highest occupied level (i.e., the highest occupied molecular orbital, HOMO) of the light absorber 25 is positioned between the conduction band of the n-type semiconductor layer 22 and the conduction band of the p-type semiconductor layer 24, in order to reduce the obstacles of the mobility of the electrons and holes upon the light absorber 25 absorbing the carrier.
Also, the n-type semiconductor layer 22 and p-type semiconductor layer 23 can enhance the conductivity, and the mobility of the carriers, by adding dopants. For example, aluminum (Al) can be added into ZnO as the dopant, while tetrafluorotetracyanoquinodimethane (F4-TCNQ) can be added into the p-type organic semiconductors as the dopant. There are a wide variety of materials capable of enhancing the conductivity and is not limited to the above.
In addition, the thickness of the p-type semiconductor layer 23 can be greater than the thickness of the n-type semiconductor layer 22, but is not limited thereto. The material of forming the second electrode layer 24 may be molybdenum trioxide (MoO3)/aluminum, but the material of the electrode layer is well-known in the art and thus the selection is not limited to the above.
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Later, as mentioned above, the light absorber 25 is formed on the surface of the n-type semiconductor layer 22, so as for the light absorber 25 to be thereby formed in the recesses 220 of the surface of the n-type semiconductor layer 22.
In summary, the solar cell and fabrication method according to the embodiments of the present invention provides a light absorber between an n-type semiconductor layer and a p-type semiconductor layer, such that the light absorber absorbs solar energy while the p-type and n-type semiconductor layers transfer carriers. Accordingly, the carriers will not be recombined with each other in conduction upon the separation, so as to avoid energy loss therein and to thereby achieve the purpose of enhancing the conversion efficiency.
Furthermore, by controlling the conduction band and the valence band of the material of the light absorber, there is no energy barrier between the light absorber and the n-type and the p-type semiconductor layers, or the barrier is reduced, so that the electron and hole can be moved into the n-type and the p-type semiconductor layers.
Also, since the plurality of recesses are formed on an exposed surface of the n-type semiconductor layer, the area of the PN junction is increased and so the absorption area.
Furthermore, the mobility of the carriers and carrier concentration of the n-type and the p-type semiconductor layers are enhanced by adding dopants.
While the present invention has been described in terms of what are presently considered to be the most practical and preferred embodiments, it is to be understood that the present invention need not limit to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.