JP3206350B2 - Solar cell - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar cell using a pn junction of a semiconductor, and more particularly to a structure capable of improving conversion efficiency.

[0002]

2. Description of the Related Art Conventionally, various types of solar cells have been known, and with the advance of semiconductor technology, relatively inexpensive and small-sized cells have been developed and widely used as various power sources. In this solar cell, an important issue is how to efficiently convert incident light into electric power.

For this purpose, it is necessary to suppress the recombination of carriers caused by the incidence of light. In other words, positive and negative carriers (holes and electrons) are ionized by the incidence of light, and are collected in the p diffusion layer (positive electrode) and the n diffusion layer (negative electrode), respectively. When the carriers disappear by recombination, the photoelectric conversion efficiency decreases.

Therefore, in Japanese Patent Application Laid-Open No. 4-27169, recombination of carriers is suppressed by reducing the impurity concentration in the semiconductor substrate. That is, by reducing the impurity concentration, defects in the crystal structure serving as recombination centers inside the substrate can be reduced, and recombination of carriers can be reduced. In Japanese Unexamined Patent Publication No. Hei 4-27169, the emitter and collector regions functioning as electrodes are buried in the base region (substrate region), and even if the impurity concentration in the base region is set to be low, the series resistance between the electrodes can be reduced. Is reduced.

[0005]

However, in the above-mentioned conventional example, there is a problem that the diffusion potential at the pn junction decreases with a decrease in the impurity concentration of the substrate, which causes a decrease in the output voltage. That is, the electromotive force of a solar cell (solar cell) is greatly affected by the diffusion potential φ at the pn junction, and it is desired to increase the diffusion potential φ in order to increase the output voltage.

The diffusion potential φ is represented by φ = (kT / q) ln (NA · ND / ni ² ). Here, q is the electron charge, k is the Boltzmann constant, T is the absolute temperature, NA is the acceptor concentration, ND is the donor concentration, and ni is the intrinsic carrier concentration.

Thus, when a p-type substrate is used for a solar cell, the diffusion potential φ is proportional to the logarithm of the impurity concentration in the p substrate (acceptor concentration NA) and the impurity concentration in the n diffusion layer (donor concentration ND). You can see that.

Therefore, the impurity concentration (NA) of the p-type substrate where the generated carriers are likely to move is reduced, the impurity concentration (ND) of the n-type diffusion layer is increased accordingly, and the diffusion is performed while reducing the recombination. It is conceivable to keep the potential high.

However, actually, the impurity concentration N of the n-diffusion layer
Even if D was increased from 1 × 10 ¹⁹ to 1 × 10 ²⁰ cm ⁻³ , no increase in output voltage was obtained. The reason is that, when the impurity concentration is 1 × 10 ¹⁹ cm ⁻³ or more, the energy band gap of silicon constituting the substrate is reduced, and as a result, the intrinsic carrier concentration ni in the substrate is increased. It is considered that since the heat diffusion is performed, the temperature increases in high concentration diffusion, crystal defects occur, and recombination is likely to occur.

As described above, in the conventional solar cell, it has been difficult to obtain a sufficient output voltage while sufficiently reducing the recombination of carriers.

The present invention has been made to solve the above problems, and has as its object to provide a solar cell capable of obtaining a sufficient diffusion potential even when the impurity concentration of a substrate is reduced. And

[0012]

According to the present invention, there is provided a solar cell in which a p-type diffusion layer serving as a positive electrode and an n-type diffusion layer serving as a negative electrode are formed on a p-type substrate. A p + diffusion layer having a higher impurity concentration than the p-type substrate is interposed on the entire surface between the substrate and the substrate.

The present invention also provides a solar cell in which a p-type diffusion layer serving as a positive electrode and an n-type diffusion layer serving as a negative electrode are formed on an n-type substrate. Characterized in that an n + diffusion layer having a higher impurity concentration than the n-type substrate is interposed on the entire surface of the substrate.

Further, the present invention provides a solar cell in which a p-type diffusion layer serving as a positive electrode and an n-type diffusion layer serving as a negative electrode are formed on a p-type substrate. A first solar cell part in which a p-type diffusion layer serving as a positive electrode and an n-type diffusion layer serving as a negative electrode are formed, and an n-type diffusion layer serving as a negative electrode is formed on the light-receiving surface side of the p-type substrate. A second solar cell part on which a p-type diffusion layer serving as a positive electrode is formed, and at least the entire surface between the n-type diffusion layer of the first solar cell part and the p-type substrate has a higher impurity than the p-type substrate. A p + diffusion layer having a concentration is interposed.

[0015]

In order to increase the photoelectric conversion efficiency of a solar cell, the impurity concentration of the p-type substrate is reduced, thereby reducing crystal defects here, reducing Auger recombination and extending the carrier lifetime. is necessary. However, when the impurity concentration of the p-type substrate is reduced, the diffusion voltage at the pn junction composed of the p-type substrate and the n-type diffusion layer decreases. If the diffusion voltage is low, the output voltage of the solar cell will also be low.

According to the present invention, the p-type substrate having a higher impurity concentration than the p-type substrate is provided between the n-type diffusion layer functioning as a negative electrode and the p-type substrate.
+ A diffusion layer is interposed. Therefore, the diffusion voltage of the pn junction can be increased by the n diffusion layer and the p + diffusion layer, and a large output voltage can be obtained. Since the impurity concentration of the p-type substrate itself is set low, the carrier lifetime can be improved. Therefore, a large output voltage can be obtained while maintaining a large carrier lifetime.

Also, when an n-type substrate is used, n +
By adding the diffusion layer, the diffusion potential can be increased, and the same operation and effect as in the above case can be obtained.

Further, in order to increase the photoelectric conversion efficiency of the solar cell, it is preferable to increase the light receiving area. Therefore, it is conceivable to form the electrode on the back surface side. Also,
Sunlight includes a relatively large amount of light having a relatively short wavelength in the daytime, and a large amount of light having a relatively long wavelength in the morning and evening. And short wavelength light is p
It is absorbed in the surface layer in the mold substrate and generates carriers,
Long-wavelength light is absorbed in a deep place in the p-type substrate to generate carriers.

In the present invention, an n-diffusion layer and a p-diffusion layer functioning as electrodes are arranged on the back surface of the first solar cell portion. Therefore, the light receiving area can be increased in the first solar cell portion. In particular, in the first solar cell portion, since the electrode was provided only on the back surface side, p
It is preferable to reduce the thickness of the mold substrate and shorten the moving distance of the carrier to the electrode. If daytime light is received in this portion, sufficient light absorption can be achieved, and efficient photoelectric conversion can be performed.

On the other hand, the second solar cell portion is n
It has a diffusion layer and a p diffusion layer on the back side. Therefore, by increasing the thickness of the p-type substrate, it is possible to absorb the morning and evening light and move the generated carriers to the n diffusion layer and the p diffusion layer.

In particular, according to the present invention, since the p + diffusion layer is provided, as described above, the p +
The carrier lifetime in the mold substrate can be lengthened, and the photoelectric conversion efficiency can be increased.

[0022]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a diagram showing a basic configuration of an embodiment of the present invention. An n + diffusion layer is provided on the surface side of a high-resistance p-type substrate 10 having a relatively low impurity concentration. A negative electrode 14 is provided via the reference numeral 12. On the back surface of the p-type substrate 10, a positive electrode 18 is provided via a p + diffusion layer 16. In this embodiment, the n + diffusion layer 12
A p + diffusion layer 20 in which impurities are diffused at a higher concentration than the p-type substrate 10 is formed between the p-type substrate 10 and the p-type substrate 10.

The p-type substrate 10 is formed of silicon single crystal, mixed with a small amount of boron (B), and has a specific resistance of 10 to 1
It is set to about 00 Ωcm. Then, the n + diffusion layer 12, the negative electrode 14, and the p + diffusion layer 1
6. The formation of the positive electrode 18 is usually performed by thermal diffusion. Generally, boron (B) is used as the p-type impurity, and phosphorus (P) is used as the n-type impurity. Also,
Aluminum (Al) is usually used for the negative electrode and the positive electrodes 14 and 18.

In this embodiment, the p + diffusion layer 20 is formed on the surface of the p-type substrate 10 by boron diffusion. This diffusion of boron is usually performed by thermal diffusion. The p + diffusion layer 16 on the back side is replaced with the p + diffusion layer 20 on the front side.
It may be formed at the same time. The p + diffusion layer 16 is set to have a higher impurity concentration than the p + diffusion layer 20.

Here, the surface side p + diffusion layer 20 has a surface impurity concentration of about 1 × 10 ¹⁷ to 1 × 10 ¹⁹ and a depth of 1 to 3 μm.
m. The n + diffusion layer 12 is formed by forming a p + diffusion layer 20 and then introducing a normal impurity.

As described above, the solar cell of this embodiment has n +
Diffusion layer 12 is in contact with p-type substrate 10 via p + diffusion layer 20. Therefore, the p-side impurity concentration NA in the pn junction
Becomes the acceptor concentration of the p + diffusion layer 20, which is higher than the impurity concentration NA in the p-type substrate 10. Therefore, the diffusion potential φ can be increased, and the output voltage of the solar cell can be increased.

In this embodiment, the acceptor concentration N
Since A can be increased, there is no need to increase the donor concentration ND. Therefore, both the impurity concentrations NA and ND are 1 × 10
It can be ¹⁹ cm ⁻³ or less, and recombination here can be suppressed. Since the impurity concentration of the p-substrate 10 itself can be as low as about 1 × 10 ¹⁵ to 1 × 10 ¹⁶ cm ^−3, Auger recombination during carrier (electron) movement inside the p-type substrate 10 is effectively performed. Can be prevented. In particular, among the incident sunlight, the short-wavelength light generates carriers in the n + diffusion layer 12 on the front surface, whereas the long-wavelength light having a wavelength of 1120 nm or more is generated inside the p-type substrate 10 or on the rear surface. And carriers are generated here. When the electrons generated in this way move toward the negative electrode 14 on the surface, they must move inside the p-type substrate 10, and by increasing the resistance of the p-type substrate 10,
The probability of occurrence of Auger recombination can be greatly reduced. For example, when a relatively low-resistance substrate of about 0.2 to 10 Ωcm is used, the carrier lifetime here is about 10 μsec, but a high-resistance substrate of about 10 to 30 Ωcm as in this embodiment is used. If used, the carrier lifetime can be on the order of several hundred to 1000 μsec. From this, it is understood that Auger recombination can be effectively prevented. If the specific resistance of the p-type substrate 10 is further increased, the internal resistance increases and the voltage drop cannot be ignored. Therefore, the specific resistance of the p-type substrate 10 is preferably as described above.

With the solar cell of this embodiment,
An increase of about ²⁰ to 30 mV in open-circuit voltage (voltage obtained between the positive and negative electrodes in an open state) and about 1 to ² mA / cm ² in short-circuit current (current obtained by short-circuiting between positive and negative electrodes) was obtained.

In the above description, the p-type substrate 1 is used as the substrate.
Although 0 is used, the same effect can be obtained by using an n-type substrate as the substrate. That is, when an n-type silicon substrate is used, a positive electrode is provided on the front surface via a p + diffusion layer, and a negative electrode is provided on the rear surface via an n + diffusion layer.
An n + diffusion layer is inserted between the mold substrates. As a forming method, after forming an n + diffusion layer, a p + diffusion layer and a positive electrode are formed thereon.

As described above, by providing the n + diffusion layer between the p + diffusion layer and the n-type substrate, the diffusion potential at the pn junction can be increased, and the substrate itself can have a high resistance. By preventing the coupling, an efficient solar cell can be obtained.

In the above description, the solar cell is described as a single solar cell. However, usually, about 50 to 80 sets of such solar cells are provided, and these are connected to obtain a desired output. ing.

Further, in this embodiment, since a high output voltage can be secured, the thickness of the p-type substrate 10 (silicon wafer) can be increased. Thereby, the incident light confinement effect can be increased, and a solar cell (solar cell) having a higher current density can be obtained. In conventional solar cells, in order to increase the output voltage, the carrier density is increased and the substrate thickness is reduced, the effect of containing incident light is small, and the photoelectric conversion efficiency cannot be increased. It is known that the following relationship exists between the carrier density and the open circuit voltage Voc.

Voc = (nkT / q) · ln {Jsc / J0 + 1} “Second Embodiment” The first embodiment described above is applied to a non-concentrating solar cell (solar cell). Further, the present invention can be more suitably applied to a concentrating solar cell. FIG.
Shows an example of this configuration. Above the solar cell 100, a condensing optical system 200 is provided. The light condensed (for example, about 100 times) by the optical system 200 is applied to the solar cell 100.

The center of the p-type substrate 10 of the solar cell 100 is cut out from the back side in a trench shape. Therefore, the central portion 10a of the p-type substrate 10 made of silicon single crystal is thin and the end portion 10b is thick. The p + diffusion layer 22 is formed on the cut back surface. The positive electrode 18 is connected to the p + diffusion layer 22, and the n +
The negative electrode 14 is connected via the diffusion layer 12. This p +
The diffusion layer 22 makes contact with the positive electrode 18 and
A pn junction is formed with n + diffusion layer 12. Note that p
The surface of the central portion 10a of the mold substrate 10 has a pyramid-shaped texture structure so that the efficiency of use of incident light can be increased.

In this embodiment, the n + diffusion layer 12 is formed by p +
A point is formed in the diffusion layer 22. In this example, the n + diffusion layer 12 of 20 to 50 μm square is
It is formed at a pitch of 0 μm (interval between adjacent ones).

The solar cell 100 is manufactured in the same manner as in the first embodiment, except that the rear surface of the plate-shaped silicon substrate is cut out to have the shape described above.

The solar cell 100 has an optical system 20
When sunlight enters through 0, strong short-wavelength light in the daytime enters the central portion 10a, and weak long-wavelength light in the morning and evening enters the end portion 10b. This is because the probability of morning and evening light being obliquely incident is high, and considering the efficiency of the solar cell, the solar cell 100 is arranged to receive strong daylight. It should be noted that even when a tracking device is provided and the mode is tracked, the tendency of light on the long wavelength side to enter the end remains unchanged.
The short-wavelength light is absorbed by the surface layer in the p-type substrate 10, and the resulting negative carriers (electrons) are n
It is extracted to the negative electrode 14 through the + diffusion layer 12. Positive carriers (holes) pass through the p + diffusion layer 22 to form the positive electrode 1
It is taken out to 8. Since the thickness of the p-type substrate 10 is small, carriers can be efficiently taken out.

On the other hand, light of a long wavelength is absorbed by a relatively deep portion of the end 10b of the p-type substrate 10, and is extracted from the positive electrode 18 and the negative electrode 14, as in the case described above.

As described above, by changing the thickness of the p-type substrate 10 between the central portion 10a and the end portion 10b, more efficient photoelectric conversion efficiency can be obtained.

In the solar cell 100 of the present embodiment, both the positive electrode 18 and the negative electrode 14 are provided on the back side. Therefore, the electrode does not block light incident from the front side, and the amount of incident light can be made sufficient. That is, in a concentrating solar cell, the output increases in proportion to the degree of condensing. Therefore, the resistance of the extraction electrode becomes a problem, and the problem is dealt with by increasing the electrode area or increasing the thickness of the electrode. However, when the area of the surface electrode is increased, the light receiving area is correspondingly reduced, and the efficiency of the solar cell is reduced. On the other hand, when the thickness of the electrode is increased, the electrode cannot be formed by a lithography process (for example, a lift-off method) used for forming an ordinary electrode. Therefore, electrodes will be formed using screen printing technology, but this method cannot form a sufficiently fine pattern,
There is a problem that the effective light receiving area cannot be sufficiently secured. In this embodiment, since the electrodes are provided on the back surface, the effective light receiving area can be made 100%. In addition, since both the positive electrode 18 and the negative electrode 14 can be widened, a lift-off method or a general vapor deposition method can be used, and the formation is simple and the resistance can be easily reduced.

In this embodiment, a high-resistance substrate (about 100 to 500 Ωcm) is used in which the impurity concentration of the p-type substrate 10 is low as in the first embodiment. Therefore, recombination of electrons passing through the p-type substrate 10 is suppressed,
The photoelectric conversion efficiency can be increased.

In order to reduce the total amount of recombination, it is desirable to make the thickness of the p-type substrate 10 as thin as possible within a range where the irradiation light can be absorbed. In this embodiment, the central portion 10a
Has a thickness of 50 to 100 μm. In addition, end 1
The thickness of Ob is set to 200 to 300 μm, which is the limit of manufacturing a single crystal silicon wafer. Thus, end 1
0b, the solar cell 100
Has sufficient strength as a whole structure. In particular, since the process can be configured based on a normal silicon wafer, the end 10b having a large thickness is reinforced, and a process with a high yield can be achieved.
In addition, since the back surface of the central portion 10a serves as a fin for heat dissipation, a solar cell (solar cell) having a high heat dissipation effect can be obtained, and efficient operation at lower temperature is possible.

"Performance of First and Second Embodiments" Table 1 shows an example of the performance of the first and second embodiments. This is an experimental result when the light concentration is 100 times (100 SUN) and the temperature is maintained at 20 ° C. As a comparative example, a configuration similar to that of the second embodiment except that the p + diffusion layer 22 is not provided and a p + diffusion layer for contact is provided only near the positive electrode is shown. From this, it can be seen that the open-circuit voltage Voc can be increased in the configurations of the first and second embodiments. In particular, in the first embodiment, when applied to the condensing type, a sufficient value for the short-circuit current cannot be obtained due to an increase in the internal resistance, but it is understood that the short-circuit current can be increased in the second embodiment. .

[0045]

Table 1 First Embodiment Equivalent to Second Embodiment Second Embodiment (without p + diffusion layer) Open circuit voltage Voc (mV) 605 to 610 594 to 603 638 to 650 Short circuit current (mA / cm ² ) 0.61 to 0.68 0.76 0.70.78 0.75 0.70.78 Efficiency (%) 12.5 114.5 15.8 116.2 8.018.0 119.2 "Third Embodiment" In this embodiment, as shown in FIG. 3, the configuration of the central portion 10a is the same as that of the above-described second embodiment. The p + diffusion layer 22 is provided on the back surface side, the positive electrode 18 is provided via the p + diffusion layer, and the negative electrode 14 is provided via the n + diffusion layer 12 provided in the p + diffusion layer 22. On the other hand, the end 10b of the p-type substrate 10 has the same configuration as in the first embodiment. That is, the negative electrode 14 is provided on the surface of the end 10 b via the p + diffusion layer 20 and the n + diffusion layer 12. The p-type substrate 10 has a high resistance. In this embodiment, the central portion 10
The width of a is about 5 to 20 mm, and the width of the end 10b is 2 to
It is set to about 5 mm, whereby the strength of the solar cell becomes sufficient. The optical system 200 for condensing light is not shown.

Further, in this embodiment, the p + diffusion layer 22
However, a relatively large area positive electrode 18 is mounted on the flat portion and the slope portion on the back surface side of the end portion 10b, which is located on the entire back surface side of the solar cell including the slope portion. In addition,
This embodiment is suitably used as a condensing type, like the second embodiment.

Accordingly, the short-wavelength light in the daytime is efficiently photoelectrically converted in the central portion 10a, as in the second embodiment, and the output from the positive electrode 18 and the negative electrode 14 provided on the back side of the central portion 10a. can get.

On the other hand, the long wavelength light in the morning and evening enters the end 10b as in the second embodiment. Since the end portion 10b is thick, it effectively absorbs light of a long wavelength, and positive and negative carriers are generated here. Then, due to the electric field in the p substrate 10, the electrons reach the negative electrode 14 provided on the surface via the p + diffusion layer 20 and the n + diffusion layer 12. On the other hand, holes reach the positive electrode 18 via the p + diffusion layer 22. Although the moving distance of the carrier at the end 10b is relatively long, the p-type substrate 1
Since the impurity concentration of 0 is set to be low, the carrier lifetime is long, and efficient photoelectric conversion can be performed particularly in the morning and evening sunlight. In this embodiment, as in the above-described embodiment, the carrier lifetime can be increased while the diffusion voltage of the pn junction is increased by the presence of the p + diffusion layer, and efficient photoelectric conversion can be performed.

FIG. 4 shows output characteristics according to time in the solar cells of the second and third embodiments. Thus, according to the third embodiment, the output in the morning and evening can be improved. This example is an experimental result under the conditions that the light concentration is 20 SUN (20 times light collection), the temperature is controlled at 25 ° C. by a cooling device, and a mechanical tracking device is provided.

[0050]

As described above, according to the present invention,
A p + diffusion layer having a higher impurity concentration than the p-type substrate is interposed between the n-type diffusion layer functioning as a negative electrode and the p-type substrate. Therefore, the diffusion voltage of the pn junction can be increased by the n diffusion layer and the p + diffusion layer, and a large output voltage can be obtained. Since the impurity concentration of the p-type substrate itself is set low, the carrier lifetime can be improved. Therefore, a large output voltage can be obtained while maintaining a large carrier lifetime.

When an n-type substrate is used, n +
By adding the diffusion layer, the diffusion potential can be increased, and the same operation and effect as in the above case can be obtained.

Further, according to the present invention, in the first solar cell portion, an n-diffusion layer functioning as an electrode and a p-type
A diffusion layer is arranged. Therefore, the light receiving area can be increased in the first solar cell portion. In particular, in the first solar cell portion, since the electrode is provided only on the back surface side, it is preferable to reduce the thickness of the p-type substrate and shorten the moving distance of the carrier to the electrode. If daytime light is received in this portion, sufficient light absorption can be achieved, and efficient photoelectric conversion can be performed. On the other hand, the second solar cell part has an n diffusion layer on the front side and a p diffusion layer on the back side. Therefore, increasing the thickness of the p-type substrate to absorb the morning and evening light,
The generated carriers can be moved to the n diffusion layer and the p diffusion layer.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a first embodiment.

FIG. 2 is a diagram showing a configuration of a second embodiment.

FIG. 3 is a diagram showing a configuration of a third embodiment.

FIG. 4 is a characteristic diagram showing outputs of the second and third embodiments.

[Explanation of symbols]

10 p-type substrate, 12 n + diffusion layer, 14 negative electrode, 16
p + diffusion layer, 18 positive electrodes, 20, 22 p + diffusion layer.

Claims (3)

(57) [Claims] 1. A solar cell in which a p-type diffusion layer serving as a positive electrode and an n-type diffusion layer serving as a negative electrode are formed on a p-type substrate, wherein a p-type substrate is formed on the entire surface between the n-type diffusion layer and the p-type substrate. A solar cell comprising a p + diffusion layer having a higher impurity concentration than a mold substrate. 2. A solar cell in which a p-type diffusion layer serving as a positive electrode and an n-type diffusion layer serving as a negative electrode are formed on an n-type substrate, wherein n is provided on the entire surface between the p-type diffusion layer and the n-type substrate. A solar cell comprising an n + diffusion layer having a higher impurity concentration than a mold substrate. 3. A solar cell in which a p-type diffusion layer serving as a positive electrode and an n-type diffusion layer serving as a negative electrode are formed on a p-type substrate, and a positive electrode is provided on a back surface opposite to the light receiving surface of the p-type substrate. a first solar cell part on which a p-diffusion layer and an n-diffusion layer serving as a negative electrode are formed; an n-diffusion layer serving as a negative electrode is formed on the light-receiving surface side of the p-type substrate; A second solar cell part formed with a diffusion layer, and at least the n diffusion layer of the first solar cell part and the p
P + with a higher impurity concentration than the p-type substrate
A solar cell having a diffusion layer interposed.