JP5341949B2 - Solar cell - Google Patents

Description

  The present invention relates to a solar cell having a superlattice structure.

  Various research and development have been conducted on solar cells in order to increase the photoelectric conversion efficiency by using light in a wider wavelength range. For example, solar cells that use longer wavelength light by providing an intermediate band between a valence band and a conduction band using quantum dot technology and exciting electrons in two stages have been proposed ( For example, Non-Patent Document 1, Patent Document 1).

  A solar cell having such quantum dots is obtained by inserting a quantum dot layer having quantum dots into a base semiconductor constituting the i layer of a compound solar cell. By inserting a quantum dot layer into the base semiconductor, a superlattice miniband is formed as an intermediate band by electronic coupling between quantum dots, and light in the wavelength range that has not been used by two-stage photoexcitation via the miniband. Absorption (absorption of photons having energy smaller than the band gap of the base semiconductor material) becomes possible, and the photocurrent can be increased. Carriers generated by the quantum dots move in the miniband, move to the p-type and n-type base semiconductor regions by photoexcitation or thermal excitation, and are extracted from the outside.

Special table 2010-509772

PHYSICAL REVIEW LETTERS, 97, 247701, 2006

Currently, in a quantum dot solar cell using a mini-band, the photocurrent extraction efficiency from the quantum dot layer is limited to a maximum of several percent. The cause of this is not clear, but it is considered that the carriers generated by the quantum dots have a low probability of moving to the p-type and n-type host semiconductor regions by photoexcitation or thermal excitation.
The present invention has been made in view of such circumstances, and provides a solar cell having a superlattice structure capable of efficiently extracting carriers into p-type and n-type semiconductor regions.

  The present invention relates to a superlattice semiconductor sandwiched between a p-type semiconductor layer, an n-type semiconductor layer, the p-type semiconductor layer, and the n-type semiconductor layer, and in which a quantum layer and a barrier layer are alternately stacked a plurality of times. A superlattice semiconductor layer having a stacked structure in which a miniband is formed by a quantum level on a conduction band side of the quantum layer, and the miniband The energy level at the lower end of the barrier layer is lower than the energy level at the lower end of the conduction band of the barrier layer, and the energy level at the upper end of the miniband is lower than the energy level at the lower end of the conduction band of the barrier layer. Provided is a solar cell characterized by having an energy level higher than an energy level that is twice as much as (k: Boltzmann constant, T: absolute temperature).

According to the present invention, the superlattice semiconductor layer has a stacked structure in which a miniband is formed by a quantum level on the conduction band side of the quantum layer, and the energy level at the lower end of the miniband is It is lower than the energy level at the lower end of the conduction band of the barrier layer. Therefore, in addition to the optical transition corresponding to the band gap of the base semiconductor material, carriers generated with light energy less than the band gap of the base semiconductor material using the miniband are externally transmitted from the p-type semiconductor layer and the n-type semiconductor layer. The photocurrent can be increased.
According to the present invention, the energy level at the upper end of the miniband formed in the superlattice semiconductor layer is higher than the energy level at the lower end of the conduction band of the barrier layer by thermal energy kT (k: Boltzmann constant, T: absolute temperature). The energy level is higher than the energy level that is twice that of), so the probability that the miniband electrons are thermally excited in the conduction band of the barrier layer should be 10% or more from the Fermi distribution function at room temperature. The carriers generated in the superlattice semiconductor layer can be efficiently extracted to the outside, and the short-circuit current can be greatly increased. This makes it possible to obtain a solar cell having high photoelectric conversion efficiency.

It is a schematic sectional drawing which shows the structure of the solar cell of one Embodiment of this invention. FIG. 2 is a schematic band diagram showing energy levels of a conduction band of a superlattice semiconductor layer taken along one-dot chain line AA in FIG. 1. 4 is a graph showing a dispersion relation in a conduction band of a superlattice structure obtained by simulation of Experiment 1. FIG. 6 is a graph showing a dispersion relationship in a valence band (heavy holes) of a superlattice structure obtained by simulation of Experiment 1. FIG. 4 is a graph showing a dispersion relation in a valence band (light holes) of a superlattice structure obtained by simulation of Experiment 1. FIG. 6 is a graph showing a dispersion relation in a conduction band of a superlattice structure obtained by simulation of Experiment 2. FIG. 6 is a graph showing a dispersion relation in a conduction band of a superlattice structure obtained by simulation of Experiment 3. 6 is a graph showing a dispersion relation in a conduction band of a superlattice structure obtained by simulation of Experiment 4.

  The solar cell of the present invention is sandwiched between a p-type semiconductor layer, an n-type semiconductor layer, the p-type semiconductor layer and the n-type semiconductor layer, and a quantum layer and a barrier layer are alternately stacked several times. A solar cell including a superlattice semiconductor layer, wherein the superlattice semiconductor layer has a stacked structure in which a miniband is formed by a quantum level on a conduction band side of the quantum layer; The energy level of the lower end of the miniband is lower than the energy level of the lower end of the conduction band of the barrier layer, and the energy level of the upper end of the miniband is lower than the energy level of the lower end of the conduction band of the barrier layer at room temperature. It is characterized in that the energy level is higher than the energy level lower by twice the thermal energy kT (k: Boltzmann constant, T: absolute temperature).

Here, a brief explanation will be given for terms often used in this specification.
The superlattice structure is a structure in which a barrier layer and a quantum layer (including a quantum well layer and a quantum dot layer) that are both made of a semiconductor and have different band gaps are repeatedly stacked a plurality of times.
A miniband is a phenomenon in which the electron wave function of a quantum well or quantum dot in a superlattice structure interacts with the wave function of an adjacent quantum well or quantum dot, resulting in a resonant tunneling effect between the quantum levels of the quantum well or quantum dot. The band formed and formed. Note that the miniband is a band formed at least partially between the upper end of the valence band and the lower end of the conduction band of the barrier layer.
A quantum dot is a semiconductor fine particle having a particle size of 100 nm or less, and is a fine particle surrounded by a semiconductor having a larger band gap than the semiconductor constituting the quantum dot.
A quantum level means the discrete energy level of the electron of a quantum dot.
The barrier layer is made of a semiconductor having a larger band gap than the semiconductor constituting the quantum dots, and constitutes a superlattice structure.
The x direction is a direction parallel to the laminated surface as shown in FIG. 1, and the y direction is a direction parallel to the laminated surface and a direction perpendicular to the x direction. Further, the z direction is a direction perpendicular to the laminated surface as shown in FIG.

In the solar cell of the present invention, the energy level at the upper end of the miniband is preferably higher than the energy level at the lower end of the conduction band of the barrier layer.
According to such a configuration, the electrons in the miniband can easily move to the conduction band of the barrier layer, and carriers generated in the superlattice semiconductor layer can be efficiently extracted to the outside.
In the solar cell of the present invention, the superlattice semiconductor layer preferably has a stacked structure in which only one miniband is formed by a quantum level on the conduction band side of the quantum layer.
According to such a configuration, there is no relaxation between minibands generated when a plurality of minibands are formed, and carriers generated in the superlattice semiconductor layer are efficiently transferred to the p-type semiconductor layer or the n-type semiconductor layer. Can be taken out through.

In the solar cell of the present invention, it is preferable that the p-type semiconductor layer, the n-type semiconductor layer, and the superlattice semiconductor layer form a pn junction or a pin junction.
According to such a configuration, an electromotive force can be effectively generated when the pin junction or the pn junction receives light.
In the solar cell of the present invention, the quantum layer is preferably a quantum dot layer composed of a plurality of quantum dots.
According to such a configuration, due to the quantum effect of the quantum dots, the energy height of the miniband can be easily changed, the energy lower end of the miniband is an energy level lower than the energy of the barrier layer, and The energy top of the miniband is higher than the energy level at the bottom of the conduction band of the barrier layer or higher than the energy level at the bottom of the conduction band of the barrier layer by twice the thermal energy at room temperature Minibands that are energy levels can be easily formed.

In the solar cell of the present invention, the superlattice semiconductor layer is preferably made of a III-V group compound semiconductor, a II-VI group compound semiconductor, or a chalcopyrite type semiconductor.
According to such a configuration, a miniband is easily formed in the superlattice semiconductor layer, and the position of the miniband is easily adjusted.
In the solar cell of the present invention, the superlattice semiconductor layer contains at least one element of Al, Ga, and In and a III-V group compound containing at least one element of As, Sb, N, and P It is preferable to consist of a semiconductor.
According to such a configuration, a miniband is easily formed in the superlattice semiconductor layer, and the position of the miniband is easily adjusted.
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The configurations shown in the drawings and the following description are merely examples, and the scope of the present invention is not limited to those shown in the drawings and the following description.

Configuration of Solar Cell FIG. 1 is a schematic sectional view showing the configuration of a solar cell according to an embodiment of the present invention.
The solar cell 20 of the present embodiment is sandwiched between the p-type semiconductor layer 1, the n-type semiconductor layer 12, the p-type semiconductor layer 1 and the n-type semiconductor layer 12, and includes a plurality of quantum layers 6 and barrier layers 8. The superlattice semiconductor layer 10 includes superlattice semiconductor layers 10 that are alternately stacked, and the superlattice semiconductor layer 10 is stacked such that a miniband is formed by a quantum level on the conduction band side of the quantum layer 6. The energy level at the lower end of the miniband is lower than the energy level at the lower end of the conduction band of the barrier layer 8, and the energy level at the upper end of the miniband is lower than the conduction level of the barrier layer 8. The energy level is higher than the energy level that is lower than the energy level at the lower end by twice the thermal energy kT (k: Boltzmann constant, T: absolute temperature) at room temperature. 1 shows an embodiment in which the quantum layer 6 is a quantum dot layer, the quantum layer 6 may be a quantum well layer.

Although the solar cell 20 of this embodiment should just have the above structure, the quantum layer 6 may be the quantum dot layer 6 comprised with the some quantum dot 7. FIG. Further, as shown in FIG. 1, the buffer layer 3, the base layer 4, the window layer 14, the contact layer 15, the p-type electrode 18, and the n-type electrode 17 may be included.
Hereinafter, the solar cell 20 of the present embodiment will be described.

1. The p-type semiconductor layer and the n-type semiconductor layer The p-type semiconductor layer 1 is made of a semiconductor containing a p-type impurity, and forms a pin junction or a pn junction together with the i-type semiconductor layer (superlattice semiconductor layer 10) and the n-type semiconductor layer 12. can do.
The n-type semiconductor layer 12 is made of a semiconductor containing an n-type impurity, and can form a pin junction or a pn junction together with the i-type semiconductor layer (superlattice semiconductor layer 10) and the p-type semiconductor layer 1.
When this pin junction or pn junction receives light, an electromotive force is generated.
One of the p-type semiconductor layer 1 and the n-type semiconductor layer 12 may be a substrate as shown in FIG. 1, or both may be thin films formed by a CVD method or the like.
The p-type semiconductor layer 1 and the n-type semiconductor layer 12 may be doped with impurities corresponding to the same semiconductor material as the barrier layer 8 or may be doped with impurities corresponding to a semiconductor material different from the barrier layer 8. Good.

2. Superlattice Semiconductor Layer The superlattice semiconductor layer 10 is sandwiched between the p-type semiconductor layer 1 and the n-type semiconductor layer 12 and can constitute a pin junction or a pn junction. The superlattice semiconductor layer 10 has a superlattice structure in which barrier layers 8 and quantum layers 6 are alternately and repeatedly stacked. The superlattice semiconductor layer 10 may be an i-type semiconductor, and may be a semiconductor layer containing a p-type impurity or an n-type impurity if an electromotive force is generated by receiving light. Typical quantum layers 6 include a quantum dot layer 6 and a quantum well layer. Below, although the case where it is the quantum dot layer 6 is demonstrated, it is the same also about another quantum layer.

Although the material which comprises the barrier layer 8 and the quantum dot layer 6 which comprise the superlattice semiconductor layer 10 is not specifically limited, For example, it can comprise from a III-V group compound semiconductor. The quantum dot layer 6 is made of a semiconductor material having a narrower band gap than the barrier layer 8.
The material constituting the barrier layer 8 and the quantum dot layer 6 constituting the superlattice semiconductor layer 10 is, for example, AlSb, InAs _x Sb _{1 -x} , AlSb _x As _{1 -x} , AlAs, GaAs, In _x Ga _{1- x As, Al x Ga 1-} x As, it is possible to use the In _x Ga _1-x P. Furthermore, for example, a group IV semiconductor of the periodic table, a compound semiconductor composed of group III and group V, a compound semiconductor composed of group II and group VI, or a mixed crystal material thereof may be used. Further, a chalcopyrite-based material may be used, or a semiconductor other than these may be used. For example, the barrier layer 8 is made of GaNAs, the quantum dot layer 6 is made of InAs, the barrier layer 8 is made of GaP, the quantum dot layer 6 is made of InAs, and the barrier layer 8 is made of GaN. Ga _x In _1-x N for the material of this, GaAs for the material of the barrier layer 8, GaSb for the material of the quantum dot layer 6, AlAs for the material of the barrier layer 8, InAs for the material of the quantum dot layer 6, and material for the barrier layer 8 In addition, CuGaS ₂ and CuInSe ₂ can be used as the material of the quantum dot layer 6.

  By reducing the thickness of the barrier layer 8, electronic coupling between two adjacent quantum layers 6 can be generated, and a superlattice miniband can be formed by the quantum levels of the quantum layer 6. When a superlattice structure using quantum dots confined in the xy direction is considered, it means that the wave function of the quantum dot structure is the same as the wave function of a quantum well confined only in the z direction. On the other hand, the energy value of the quantum dot structure may be considered as a value obtained by adding the energy value Ex in the x direction and the y direction (Ex, Ey) to the energy value Ez in the z direction. Ex and Ey are obtained from energy values obtained in a single quantum well in a state where no electric field is applied.

FIG. 2 is a schematic band diagram showing the energy level of the conduction band of the superlattice semiconductor layer 10 along the one-dot chain line AA in FIG. By controlling the size d _{a of} the superlattice semiconductor layer 10 in the thickness direction of the quantum dot 7 of FIGS. 1 and 2, the distance d _b between two adjacent quantum dots, the material of the quantum dot 7, and the material of the barrier layer 8. A miniband can be formed as shown in FIG.
The energy level at the lower end of the miniband formed in the superlattice semiconductor layer 10 is lower than the energy level at the lower end of the conduction band of the barrier layer 8 as shown in FIG. As a result, the energy difference between the upper end of the valence band of the barrier layer 8 or quantum dot 7 and the lower end of the miniband is the difference between the upper end of the valence band of the barrier layer 8 or quantum dot 7 and the lower end of the conduction band of the barrier layer 8. It becomes smaller than the energy difference, and it becomes possible to photoexcite electrons in the valence band to the miniband by longer wavelength light.

As shown in FIG. 2, the energy level at the upper end of the mini-band formed in the superlattice semiconductor layer 10 is the thermal energy kT (k: Boltzmann constant) at room temperature from the energy level E _c at the lower end of the conduction band of the barrier layer 8. , T: absolute temperature) higher than the energy level (E _c −2 kT) (E _c −52 meV) which is twice as much as (26 meV). With this configuration, the probability that miniband electrons are thermally excited into the conduction band of the barrier layer 8 can be made 10% or more from the Fermi distribution function at room temperature, and carriers generated in the superlattice semiconductor layer 10 can be obtained. Can be taken out efficiently.
Further, the energy level at the upper end of the miniband formed in the superlattice semiconductor layer 10 may be higher than the energy level at the lower end of the conduction band of the barrier layer 8. This allows the miniband electrons to move to the conduction band of the barrier layer 8 more easily.

  In addition, in the solar cell which introduced the conventional superlattice structure, the extraction efficiency of the carrier produced | generated by the quantum layer is low. It is necessary to excite carriers in the quantum level or miniband to the energy level at the bottom of the conduction band of the barrier layer, but the probability of photoexcitation is low, and in thermal excitation, the energy generated for the carriers generated in the quantum layer Since the barrier is sufficiently larger than the thermal energy, carrier excitation is difficult.

Further, only one miniband may be formed in the superlattice semiconductor layer 10 by the quantum level on the conduction band side of the quantum dots 7 as shown in FIG. Thus, the generated carriers can be efficiently extracted from the pn electrode without any relaxation between minibands.
In addition, when forming multiple minibands by the quantum level on the conduction band side of the quantum dots, the carriers generated in the second and subsequent high-energy minibands also become the first miniband (base energy) in a short time. There is a high rate of transition and extinction by recombination without being able to escape the quantum dot layer.

As a method of manufacturing the superlattice semiconductor layer 10 so that a miniband as shown in FIG. 2 is formed, for example, a method of adjusting the quantum dot size d _a of the quantum dot layer 6 and the thickness d _{b of the} barrier layer There is. Alternatively, there is a method of changing the quantum dot material of the quantum dot layer or the material of the barrier layer. For example, if In _x Ga _1-x As (0 ≦ x ≦ 1), changing the mixed crystal ratio x changes the band gap, effective mass of carriers, valence band, and conduction band barrier height. Can be made. Therefore, by this method, the position and width of the miniband can be adjusted.

  The above structure is also possible in a quantum well solar cell in which a quantum well layer capable of forming a miniband is inserted. However, a quantum dot that is confined in the three-dimensional direction is more preferable because the energy position of the miniband tends to be higher than a quantum well that is confined only in the one-dimensional direction.

In addition, the solar cell which has the same structure as this embodiment can also be combined with a condensing system. In this case, the solar cell 20 is sandwiched between the p-type semiconductor layer 1, the n-type semiconductor layer 12, the p-type semiconductor layer 1 and the n-type semiconductor layer 12, and the quantum layer 6 and the barrier layer 8 are plural times. A solar cell 20 including superlattice semiconductor layers 10 stacked alternately, and the superlattice semiconductor layer 10 is stacked such that a miniband is formed by a quantum level on the conduction band side of the quantum layer 6. The energy level at the lower end of the miniband is lower than the energy level at the lower end of the conduction band of the barrier layer 8, and the energy level at the upper end of the miniband is lower end of the conduction band of the barrier layer 8. The energy level is higher than the energy level lower than the energy level by two times the thermal energy kT (k: Boltzmann constant, T: absolute temperature) at the temperature at the time of condensing.
This makes it possible to increase the probability that miniband electrons are thermally excited into the conduction band of the barrier layer by 10% or more from the Fermi distribution function at the temperature at the time of condensing, and to generate carriers generated in the superlattice semiconductor layer. It can be efficiently taken out and the short-circuit current can be greatly increased.

3. Manufacturing Method of Solar Cell The superlattice semiconductor layer 10 can be formed by a technique such as a molecular beam epitaxy (MBE) method or a metal organic chemical vapor deposition (MOCVD) method. The quantum dot layer 6 can be grown by a method called Stranski-Krastanov (SK) growth. The mixed crystal ratio of the quantum dot 7 or quantum well can be adjusted by changing the material composition ratio of the above method, and the size or quantum well width of the quantum dot 7 can be adjusted by changing the raw material, growth temperature, pressure, deposition time, etc. Can be adjusted.

In manufacturing the solar cell 20 of the present embodiment, for example, a quantum dot solar cell is manufactured using a molecular beam epitaxy (MBE) method or a metal organic chemical vapor deposition method (MOCVD) that is excellent in film thickness control. Can do. In the solar cell 20 of the present embodiment, for example, GaAs is used as the base semiconductor material (material of the barrier layer 8), and the band gap is about 1.43 eV (GaAs) to 0.36 eV depending on the mixed crystal ratio x as the material of the quantum dots 7. It can be manufactured using indium gallium arsenide (In _x Ga _1-x As) that can be easily changed to (indium arsenide: InAs). Hereinafter, the manufacturing method of such a solar cell 20 is demonstrated in detail.

First, a p-GaAs substrate, which is the p-type semiconductor substrate 1, is cleaned with an organic cleaning solution, etched with a sulfuric acid-based etching solution, washed with running water for 10 minutes, and then supported in an MOCVD apparatus. A p ⁺ -GaAs layer having a thickness of 300 nm is formed as a buffer layer 3 on the p-type semiconductor substrate 1. The buffer layer 3 is a layer for improving the crystallinity of the light absorption layer to be formed thereon. Subsequently, a p-GaAs base layer as a base layer 4 with a thickness of 300 nm and a GaAs layer as a barrier layer 8 with a thickness of 1 nm are crystal-grown on the p ⁺ -GaAs layer as a buffer layer 3. Then, the quantum dot layer 6 made of InAs (x = 1) is formed using a self-organization mechanism. The quantum dot layer 6 is stacked by repeating the crystal growth of the barrier layer 8 and the quantum dot layer 6.

After crystal growth of the quantum dot layer 6, a GaAs cap layer (not shown) is grown to a thickness of about 4 nm in order to restore the flatness of the crystal surface, thereby completing the superlattice semiconductor layer 10. Subsequently, an n-GaAs layer, which is the n-type semiconductor layer 12, is grown on the cap layer with a thickness of 250 nm to form a pin structure, and then the window layer 14 is formed with n-Al _0.75 with a thickness of 50 nm. A Ga _0.25 As layer is formed. Next, a p ⁺ -GaAs layer having a thickness of 100 nm is formed as a contact layer 15 by crystal growth. Next, after taking out from the MOCVD apparatus, the p-type electrode 18 is formed on the entire back surface of the substrate. Next, a comb-shaped electrode is formed on the contact layer 15 by photolithography and lift-off technology, and the n-type electrode 17 is formed by selectively etching the contact layer 15 using the comb-shaped electrode as a mask. Can be formed.

For example, the substrate processing temperature can be set to 520 ° C. only when the superlattice semiconductor layer 10 including the quantum dot layer 6 is manufactured in order to prevent re-desorption of In, and the other layers can be grown to 590 ° C. for crystal growth.
Further, for example, Si can be used as the n-type dopant, and Be can be used as the p-type dopant. For example, Au can be used as the electrode material, and the electrode material can be formed by vacuum vapor deposition using a resistance heating vapor deposition method.
In addition, the example shown here is an example, each material, such as a board | substrate used for the solar cell of this invention, a buffer layer, a quantum dot, a dopant, an electrode, a cleaning agent used at each process, a substrate processing temperature, and a manufacturing apparatus Etc. are not limited to the examples shown here.

Evaluation experiment
Using MATLAB software, a simulation (including a simulation to solve the Schrödinger equation) was performed to solve the one-dimensional Kronig-Penny model.
By solving the Kronig Penny model, the dispersion relation (Ek dispersion) between the conduction band and the valence band can be calculated, and the miniband position and the miniband width can be obtained. (See, eg, JOURNAL OF APPLIED PHYSICS, 89, 5509, 2001). The parameters contributing to the miniband position and miniband width are mainly quantum dot size or quantum well thickness, barrier layer thickness, quantum layer material and conduction band or valence band (heavy holes, light Hole) effective mass, conduction band or valence band barrier height, and by substituting these values into the Kronig-Penny model, the miniband position and miniband width can be determined.

[Experiment 1]
In Experiment 1, gallium arsenide (GaAs) was used as the base semiconductor material constituting the barrier layer, n-type semiconductor layer, and p-type semiconductor layer, and indium gallium arsenide (In _0.2 Ga _0.8 As) was used as the quantum dot material constituting the quantum dot layer. A simulation was performed to calculate the dispersion relation of the superlattice structure used.
The quantum dot is assumed to be a rectangular parallelepiped, and the size (height) in the stacking direction is 6 nm, and the size in the in-plane direction is 10 nm. The thickness of the barrier layer was 1 nm. Effective mass of electrons, gallium arsenide and (GaAs) 0.067 m _0, indium gallium arsenide (In _0.2 Ga _0.8 As) was 0.058m _0. Heavy effective mass of a hole is a gallium arsenide (GaAs) 0.349m _0, indium gallium arsenide (In _0.2 Ga _0.8 As) was 0.346m _0. Light effective mass of a hole is a gallium arsenide (GaAs) 0.090m _0, indium gallium arsenide (In _0.2 Ga _0.8 As) was 0.077 _0. The barrier height of the conduction band between gallium arsenide and indium gallium arsenide was 0.189 eV, and the barrier height of the valence band was 0.101 eV. Here, m ₀ is an electron mass of 9.11 × 10 ⁻³¹ kg.

  3 shows the dispersion relationship in the conduction band of the superlattice structure calculated by Experiment 1, FIG. 4 shows the dispersion relationship in the valence band (heavy holes), and FIG. 5 shows the dispersion relationship in the valence band (light holes). The dispersion relation is shown. In these graphs, the horizontal axis indicates the wave number, and the vertical axis indicates the energy. The energy value indicates that the position of the energy level at the lower end of the conduction band or the upper end of the valence band in the bulk of the material constituting the quantum dot is zero. In addition, the energy level at the lower end of the conduction band of the barrier layer or the upper end of the valence band of the barrier layer is indicated by a dotted line.

  Under such a condition, only one miniband is formed in the conduction band, the energy lower end of the miniband is lower than the energy level of the lower end of the conduction band of the barrier layer, and the energy upper end of the miniband in the conduction band. However, it was found that a miniband higher than the energy level at the lower end of the conduction band of the barrier layer was formed. Hereinafter, it demonstrates more concretely with reference to FIGS.

From FIG. 3, only one miniband is formed in the conduction band, the lower energy level (0.087 eV) of the miniband is lower than the lower energy level (0.189 eV) of the conduction band of the barrier layer, and the miniband. It can be seen that the upper energy level (0.193 eV) is higher than the lower energy level (0.189 eV) of the conduction band of the barrier layer. This indicates that the generated electrons are thermally excited in the miniband and can be easily extracted from the n-type semiconductor layer.
4 and 5, in the valence band, a plurality of minibands (heavy hole first miniband: −0.025 to −0.037 eV, heavy hole second miniband: −0.060 to valence electron). The barrier height of the band is -0.101 eV or less, the light first hole mini-band: -0.056 to the barrier height of the valence band is -0.101 eV or less), When the energy is smaller than the energy top of the valence band miniband at the highest energy position, the miniband is formed almost continuously, and the generated holes are easily extracted from the p-type semiconductor layer by phonon scattering or the like. Show.

  From the above, in this quantum dot structure, in addition to optical transition corresponding to the band gap of the parent semiconductor material, carriers generated with light energy less than the band gap of the parent semiconductor material using minibands can be efficiently extracted. And the short circuit current increases.

[Experiment 2]
In Experiment 2, gallium arsenide (GaAs) was used as the base semiconductor material constituting the barrier layer, n-type semiconductor layer, and p-type semiconductor layer, and indium gallium arsenide (In _0.2 Ga _0.8 As) was used as the quantum dot material constituting the quantum dot layer. A simulation was performed to calculate the dispersion relation of the superlattice structure used. Experiment 2 is an example of a quantum dot solar cell in which the position and width of the miniband are adjusted by changing the quantum dot size of the quantum dot layer and the thickness of the barrier layer from Experiment 1.
The quantum dots are assumed to be rectangular parallelepiped, and the size (height) in the stacking direction is 8 nm, and the size in the in-plane direction is 6 nm. The thickness of the barrier layer was 2 nm. Effective mass of electrons, gallium arsenide and (GaAs) 0.067 m _0, indium gallium arsenide (In _0.2 Ga _0.8 As) was 0.058m _0. The barrier height of the conduction band between gallium arsenide and indium arsenide was 0.189 eV. Here, m ₀ is an electron mass of 9.11 × 10 ⁻³¹ kg.

FIG. 6 shows the dispersion relation in the conduction band of the superlattice structure calculated in Experiment 2. The horizontal axis indicates the wave number, and the vertical axis indicates energy. The energy value indicates energy with the energy position at the lower end of the conduction band in the bulk of the material constituting the quantum dot being zero. In addition, energy levels E _c and (E _c −2 kT) at the lower end of the conduction band of the barrier layer are indicated by dotted lines. FIG. 6 corresponds to FIG. 3 in Experiment 1.
Under such conditions, only one miniband is formed in the conduction band, the lower energy of the miniband in the conduction band is lower than the energy of the barrier layer, and the upper energy of the miniband in the conduction band is the barrier layer. The energy level is higher than the energy level (Ec-2kT) which is lower than the energy level at the lower end of the conduction band of the thermal energy kT (k: Boltzmann constant, T: absolute temperature) (26 meV) at room temperature. I understood it. Hereinafter, a more specific description will be given with reference to FIG.

  From FIG. 6, only one mini-band is formed in the conduction band, the energy lower end (0.150 eV) of the mini-band is lower than the energy position (0.189 eV) of the conduction band lower end of the barrier layer, and the energy of the mini-band. The energy level (0.137 eV) whose upper end (0.188 eV) is lower than the energy level at the lower end of the conduction band of the barrier layer by twice the thermal energy kT (k: Boltzmann constant, T: absolute temperature) (26 meV) at room temperature. It can be seen that the energy level is higher than. This indicates that the generated electrons are thermally excited in the miniband and can be easily extracted from the n-type semiconductor layer. In the valence band, as in Experiment 1, a plurality of minibands are formed, and the generated holes are easily extracted from the p-type semiconductor layer by phonon scattering or the like.

In this quantum dot structure, in addition to optical transition corresponding to the band gap of the base semiconductor material, it is possible to efficiently extract carriers generated with light energy less than the band gap of the base semiconductor material using the miniband. Short circuit current increases.
From the above, it can be seen that the position and width of the miniband can be adjusted by changing the quantum dot size of the quantum dot layer and the thickness of the barrier layer, which indicates that a superlattice structure matching the solar spectrum can be produced.

[Experiment 3]
In Experiment 3, gallium arsenide (GaAs) was used as the base semiconductor material constituting the barrier layer, n-type semiconductor layer, and p-type semiconductor layer, and indium gallium arsenide (In _0.5 Ga _0.5 As) was used as the quantum dot material constituting the quantum dot layer. A simulation was performed to calculate the dispersion relation of the superlattice structure used. Experiment 3 is an example of a quantum dot solar cell in which the position and width of the miniband are adjusted with respect to a quantum dot material different from Experiments 1 and 2.
Assuming that the quantum dot is a rectangular parallelepiped, the size (height) in the stacking direction was 6 nm, and the size in the in-plane direction was 4 nm. The thickness of the barrier layer was 1 nm. Effective mass of electrons, gallium arsenide and (GaAs) 0.067 m _0, indium gallium arsenide (In _0.5 Ga _0.5 As) was 0.045 m _0. The barrier height of the conduction band between gallium arsenide and indium arsenide was 0.426 eV. Here, m ₀ is an electron mass of 9.11 × 10 ⁻³¹ kg.

FIG. 7 shows the dispersion relation in the conduction band of the superlattice structure calculated in Experiment 3. The horizontal axis indicates the wave number, and the vertical axis indicates energy. The energy value indicates energy with the energy position at the lower end of the conduction band in the bulk of the material constituting the quantum dot being zero. The energy position at the lower end of the conduction band of the barrier layer is indicated by a dotted line. FIG. 7 corresponds to FIG. 3 in Experiment 1.
Under such conditions, only one miniband is formed in the conduction band, the energy lower end of the miniband is lower than the energy level of the lower end of the conduction band of the barrier layer, and the energy upper end of the miniband is the barrier layer. It was found to be higher than the energy at the bottom of the conduction band. Hereinafter, a more specific description will be given with reference to FIG.

  From FIG. 7, only one miniband is formed in the conduction band, the energy lower end (0.335 eV) of the miniband is lower than the energy level (0.426 eV) of the lower end of the conduction band of the barrier layer, and the miniband. It can be seen that the energy upper end (0.451 eV) of the barrier layer is higher than the energy (0.426 eV) of the lower end of the conduction band of the barrier layer. This indicates that the generated electrons are thermally excited in the miniband and can be easily extracted from the n-type semiconductor layer. In the valence band, as in Experiments 1 and 2, a plurality of minibands are formed, and the generated holes are easily extracted from the p-type semiconductor layer by phonon scattering or the like.

In this quantum dot structure, in addition to optical transition corresponding to the band gap of the base semiconductor material, it is possible to efficiently extract carriers generated with light energy less than the band gap of the base semiconductor material using the miniband. Short circuit current increases.
From the above, it was found that the position and width of the miniband can be arbitrarily adjusted even in quantum dot structures composed of different quantum dot materials.

[Experiment 4]
In Experiment 4, gallium arsenide (GaAs) was used as the base semiconductor material constituting the barrier layer, n-type semiconductor layer, and p-type semiconductor layer, and indium gallium arsenide (In _0.2 Ga _0.8 As) was used as the quantum well material constituting the quantum well layer. A simulation was performed to calculate the dispersion relation of the superlattice structure used. Experiment 4 is an example of a quantum well solar cell by configuring a quantum layer having a superlattice structure with a quantum well and changing the quantum well width.
The thickness of the quantum well was 4 nm, and the thickness of the barrier layer was 2 nm. Effective mass of electrons, gallium arsenide and (GaAs) 0.067 m _0, indium gallium arsenide (In _0.2 Ga _0.8 As) was 0.058m _0. The barrier height of the conduction band between gallium arsenide and indium arsenide was 0.189 eV. Here, m ₀ is an electron mass of 9.11 × 10 ⁻³¹ kg.

FIG. 8 shows the dispersion relation in the conduction band of the superlattice structure calculated in Experiment 4. The horizontal axis indicates the wave number, and the vertical axis indicates energy. The energy value indicates energy with the energy position at the lower end of the conduction band in the bulk of the material constituting the quantum well being zero. Further, the energy position at the lower end of the conduction band of the barrier layer and the energy level of (E _c −2 kT) are indicated by dotted lines. FIG. 8 corresponds to FIG. 3 in Experiment 1.

  Under such conditions, only one miniband is formed in the conduction band, the lower energy of the miniband in the conduction band is lower than the energy of the barrier layer, and the upper energy of the miniband in the conduction band is the barrier layer. The energy level is higher than the energy level (Ec-2kT) which is lower than the energy level at the lower end of the conduction band of the thermal energy kT (k: Boltzmann constant, T: absolute temperature) (26 meV) at room temperature. I understood it. Hereinafter, a more specific description will be given with reference to FIG.

  From FIG. 8, only one mini-band is formed in the conduction band, the lower energy level (0.050 eV) of the mini-band is lower than the lower energy level (0.189 eV) of the conduction band of the barrier layer, and the mini-band. Energy level (0,176 eV) is lower than the energy level at the bottom of the conduction band of the barrier layer by two times the thermal energy kT (k: Boltzmann constant, T: absolute temperature) (26 meV) at room temperature (0 It can be seen that the energy level is higher than (.137 eV). This indicates that the generated electrons are thermally excited in the miniband and can be easily extracted from the n-type semiconductor layer. In the valence band, as in Experiments 1 and 2, a plurality of minibands are formed, and the generated holes are easily extracted from the p-type semiconductor layer by phonon scattering or the like.

In this quantum well structure, in addition to optical transition corresponding to the band gap of the base semiconductor material, it is possible to efficiently extract carriers generated with light energy less than the band gap of the base semiconductor material using the miniband. Short circuit current increases.
From the above, it was found that the position and width of the miniband can be arbitrarily adjusted even in a quantum well structure in which a quantum layer having a superlattice structure is formed of quantum wells.

    1: p-type semiconductor substrate (p-type semiconductor layer) 3: buffer layer 4: base layer 6: quantum dot layer (quantum layer) 7: quantum dot 8: barrier layer 10: superlattice semiconductor layer 12: n-type semiconductor layer 14 : Window layer 15: contact layer 17: n-type electrode 18: p-type electrode 20: solar cell

Claims (6)

a p-type semiconductor layer; an n-type semiconductor layer; and a superlattice semiconductor layer sandwiched between the p-type semiconductor layer and the n-type semiconductor layer and having a quantum layer and a barrier layer alternately stacked a plurality of times A solar cell,
The superlattice semiconductor layer has a stacked structure in which a miniband is formed by a quantum level on the conduction band side of the quantum layer,
The energy level at the lower end of the miniband is lower than the energy level at the lower end of the conduction band of the barrier layer,
The solar cell according to claim 1, wherein the energy level at the upper end of the miniband is higher than the energy level at the lower end of the conduction band of the barrier layer . The solar cell according to claim 1, wherein the superlattice semiconductor layer has a stacked structure in which only one miniband is formed by a quantum level on the conduction band side of the quantum layer. The p-type semiconductor layer, the n-type semiconductor layer and the superlattice semiconductor layer, a solar cell according to claim 1 or 2 to form a pn junction or pin junction. The solar cell according to the quantum layer has any one of claims 1 to 3 is a quantum dot layer including a plurality of quantum dots. The solar cell according to any one of claims 1 to 4 , wherein the superlattice semiconductor layer is made of a III-V group compound semiconductor, a II-VI group compound semiconductor, or a chalcopyrite type semiconductor. The superlattice semiconductor layer is made of a III-V group compound semiconductor containing at least one element of Al, Ga and In and containing at least one element of As, Sb, N and P. The solar cell according to any one of 5 .