RU2453013C1 - Photoconverter - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: vertical multistage photoconverter consists of monocrystalline silicon crystals with flat diffusion p-n junctions stacked one on top of the other to form a light-receiving surface with alternating p and n regions, having the relief of the light-receiving surface in form of repeating longitudinal depressions lying such that the sectional plane of the relief, which defines its profile, is perpendicular to the direction of stacking p-n crystals. The profile of the depressions according to the invention has the shape of an open parallelogram in which the line corresponding to the bottom of the depression is parallel to the line L showing the virtual plane of the light-receiving surface - a surface without depressions, wherein the profile of depressions ensures a number of drops of the full light flux equal to 5.

EFFECT: high percentage of light absorption in depressions of the relief of the light-receiving surface and higher efficiency of the photoconverter overall.

2 cl, 3 dwg, 1 tbl

Description

The invention relates to the field of semiconductor photovoltaics, specifically to the field of direct conversion of light energy into electricity, to solar energy, to renewable energy sources.

A promising direction in the development of photoconverters (FP), or solar cells, is the creation of vertical multi-junction (HFM) FPs in which individual single-crystal silicon crystals with flat diffusion pn junctions are stacked one after the other, forming a flat light-receiving surface with alternating p- and n-regions (RF Patent No. 2127009, CL H01L 31/18 [1]). The light-receiving surface of the VMP FP, as well as the traditional FP (horizontal), should not contain a disturbed layer. This is achieved by polishing and / or chemical etching.

When a semiconductor absorbs light energy, the generation of electron-hole pairs - nonequilibrium charge carriers (NEC). Sunlight is absorbed by polished silicon to a depth of 5 microns. Further propagation of light-generated NSC deep into the semiconductor occurs due to diffusion. The density of the diffusion stream of the NNZ is equal to D * dn / dx, where D is the diffusion coefficient, n is the concentration of the NNZ. At the same time, the concentration of NNZ decreases in time due to their recombination with the characteristic time τ (lifetime of the NNZ). The diffusion coefficient is proportional to the carrier mobility µ.

The principal advantage of VMP FP over traditional ones, in which light is absorbed by the surface of a heavily doped region, is the substantially large values of τ and μ, which increase with decreasing degree of doping of semiconductors N. In VMP FP, light is directed, in particular, to a lightly doped n base and a weakly doped diffusion region p-layer. When N varies from 10 ¹⁸ cm ^-3 to 10 ¹⁶ cm ^{-3, the} electron mobility increases 10 times, holes - about 5 times (S.Zi. Physics of semiconductor devices. - M., "Mir", 1984, t .1, p. 34 [2]). The values of τ in the case of VMP FP can be higher by 1 ... 2 orders of magnitude, which allows a much larger number of carriers to reach pn junctions. High values of τ and µ are factors that significantly increase the efficiency of the phase transition (efficiency).

The real depth of propagation of nonequilibrium carriers perpendicular to the surface in the high-frequency magnetic field is several hundred microns.

The known design of the PMF FP [1] with a flat light receiving surface. The disadvantage of this design is that the working (surface) region of silicon is small. The disadvantage is also a high percentage of sunlight reflection. For air-polished silicon media in the range of incidence angles from about 10 ° to 90 °, the reflection coefficient to _OTR for visible light is about 33%, for ultraviolet radiation (UV) - over 60% (http://www.Dpva.info/ Guide / Guide Physics [3]). Transparent (antireflective) coatings for the full solar spectrum must be multilayer, which presents additional complexity in the manufacture and increases the cost of phase transitions.

In VMP FP with "textured", i.e. the relief surface can significantly increase the region of NNZ generation.

It is also important that an increase in the area of the light receiving surface due to the relief leads to an increase in the values of μ and τ, especially at high irradiation intensities corresponding to high values of the concentration of low-voltage supercritical n. The mobility of the carriers µ decreases with increasing concentration due to the dispersion of the carriers on the media. With increasing n, the value of τ also decreases significantly due to an increase in the contribution to the recombination process of Auger recombination (zone – zone) (S.Zi, Physics of Semiconductor Devices. Moscow, Mir, 1984, vol. 1, p. 153-154 [4]).

Thus, a decrease in the surface density of a given light flux due to a relief for a given sample and, accordingly, a decrease in the concentration of generated carriers significantly increase the efficiency FP.

Closest to the proposed solution is the design of the PMF FP (US Patent No. 2010/0037943, class H01L 31/0236 [5]), where the relief of the light-receiving surface is made in the form of repeating longitudinal recesses, while it is essential that the relief cross-section plane revealing its profile is perpendicular to the direction of folding pn-elements sequentially one above the other in the foot. Specifically, in [5], the profile of the relief of the V form is patented (repeating equilateral triangular teeth, can be in a rounded form) (Figure 1).

Denote by K a coefficient showing how many times the area of the light receiving surface of the recess is greater than the corresponding flat surface. Obviously, in [5], K = 1 / cosα, where α is the angle between the wall of the recess and the virtual flat surface (without relief).

However, the relief profile [5] is not optimal in all cases. Let us consider the design [5] (Figure 1).

At α = 45 °, the incident flux of visible light absorbed by each side of the recess by 67% is reflected horizontally on the opposite side with absorption of 33% * 67% = 22.11% of energy and then goes into the environment. Thus, here, due to 2 drops, 67% + 22.11% = 89.11% of visible light is absorbed.

For UVI, we take to _otp = 60%. In the same way, we get that 40% + 60% * 40% = 64% UVR is absorbed.

The angle of the protruding teeth of the relief β (Figure 1) here is 90 °. The value of K = 1 / cos45 ° ≈1.4.

If α = 60 °, the light flux completely passes 3 drops (Figure 1). Visible light at the third drop is additionally absorbed by another (100-89.11)% * 67% ≈ 7.3%. A total of 96.41% of the visible light is absorbed.

For UVI, only 64% + (100-64)% * 40% = 78.4% is absorbed.

The angle β is 60 °. The value of K = 2.

With a further increase in the angle α, the angle β becomes smaller, and the mechanical strength of the teeth decreases significantly. In [5], examples are given only for α = 45 ° and 60 °.

Thus, the relief [5] does not provide a sufficiently high percentage of light absorption in the recesses of the relief, especially in the UV range.

The technical result of the proposed solution is to increase the percentage of light absorption in the recesses of the relief and increase the efficiency VMP AF as a whole.

This goal is achieved by the fact that in a high-frequency magnetic field phase transition consisting of monocrystalline silicon crystals with flat diffusion pn junctions (pn crystals) stacked one after the other one above the other with the formation of a light-receiving surface with alternating pn n-regions having a light-receiving surface relief in the form repeating longitudinal recesses arranged so that the plane of the relief cross section revealing its profile is perpendicular to the direction of folding of pn crystals, the recesses have parallel lateral sides rons. The profile of the recesses may be in the form of an open parallelogram in which the line corresponding to the bottom of the recess is parallel to the line L representing a virtual flat light receiving surface (without recesses). Moreover, one diagonal of the parallelogram can be perpendicular to the line L.

Distinctive features of the proposed solution are the parallelism of the lateral sides of the recesses, the possible form of the recesses in the form of an open parallelogram with the possible perpendicularity of one of the diagonals of the parallelogram of the line L, which displays a virtual flat light receiving surface.

Known solutions with the indicated features were not found.

The invention is illustrated in the drawings.

Figure 1 shows the profiles of the recesses and the path of the light flux for α = 45 ° and 60 ° of the prototype.

Figure 2 shows the profiles of the recesses and the path of the light flux for α = 45 ° and 60 ° according to the invention.

Figure 3 shows the profile of the recesses and the path of the light flux for α = 75 ° according to the invention.

From figure 1 and 2 it is clear that the values of K at equal angles α are the same for the proposed solution and for the prototype.

A significant difference in the proposed profile of the recesses is the number of drops of the total luminous flux N = 5 (Figure 2) both at α = 45 ° and α = 60 °, which corresponds to the absorption of 99.6% of visible light and 92.22% of UVI ( numbers are obtained from the continuation of the above calculation of percent absorption).

Indeed, according to the proposed solution at α = 45 ° (FIG. 2), the light flux falling on the side of the recess is reflected at an angle of 45 ° horizontally and completely falls on the opposite side at an angle of 45 ° to it (second drop). Here, reflection occurs in the vertical direction, and light falls on the bottom of the recess at an angle of 90 ° (third drop). The incident of light at an angle of 90 ° then means the light repeating the path in the opposite direction: the fourth incident on the side and the fifth on the region of the first incident with reflection into the environment.

For the profile according to the proposed solution at α = 60 ° (Figure 2), it is seen that the light flux, falling on the side at an angle of 30 ° and reflected at the same angle, partly falls to the bottom of the recess (solid lines), and partly to half of the opposite side (dashed lines). It is seen that in both cases the third drop in the light flux occurs at an angle of 90 °, which returns the light in the opposite direction to the fourth and fifth drops.

The above profiles of the recesses for the proposed solution can be called "traps for the light." By their effectiveness, they can be compared with antireflection coatings.

The data obtained are summarized in a table.

α = 45 ° α = 60 ° N % light absorption N % light absorption Visible spectrum UVI Visible spectrum UVI According to the prototype 2 89.11 64 3 96.41 78,4 According to the proposed solution 5 99.6 92.22 5 99.6 92.22

At a high radiation density, as mentioned above, the carrier mobility µ and their lifetime τ sharply fall. Reduce the reduction in efficiency AF with increasing radiation intensity is possible only by increasing the area of the light receiving surface.

Figure 3 shows the proposed profile of the relief at α = 75 °, where the light receiving surface in the region of the recesses is increased almost 4 times (K = 3.86), the number of drops of the total light flux N = 5. The percent absorption of energy of visible light and UVI for N = 5 are given in the Table. Part of the luminous flux is reflected 6 times, that is, the absorption is even higher.

At α = 80 °, the light receiving surface increases by 5.76 times.

Any depth can be made by changing the scale of the profile. The values of N, K and the influence of the relief profile on µ, τ and, as a result, on the efficiency AF do not depend on scale.

To realize the phase transition according to the invention, after the p-n crystals are joined into the stack, it is possible to make indentations by the group method, as when cutting silicon ingots into wafers by wire.

Claims (2)

1. Vertical multi-junction photoconverter, consisting of monocrystalline silicon crystals with flat diffusion pn junctions, stacked one after the other in succession with the formation of a light-receiving surface with alternating p- and n-regions, having a light-receiving surface in the form of repeating longitudinal recesses located so that the plane of the cross-section of the relief, revealing its profile, is perpendicular to the direction of folding pn crystals, characterized in that the profile of the recesses has id of an open parallelogram, in which the line corresponding to the bottom of the recess is parallel to the line L, which displays a virtual flat light receiving surface — a surface without recesses, while the profile of the recesses provides the number of drops of the total light flux equal to 5. 2. The photoconverter according to claim 1, characterized in that one diagonal of the parallelogram is perpendicular to the line L.

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