KR102105092B1 - Photoelectric devices using organic materials and porous nitrides and method for manubfacturing the same - Google Patents

Abstract

Disclosed is a photoelectric device using an organic material and a porous nitride, a substrate; A group III nitride-based compound layer grown on the substrate; A first electrode formed on the group 3 nitride-based compound layer; A porous layer in which at least part of the group 3 nitride-based compound layer is formed by wet etching; A light absorption layer formed on the porous layer and provided with an organic material or a perovskite compound; A hole transport material layer formed on the light absorption layer and provided as a p-type semiconductor layer; And a second electrode provided on the hole transport material layer.

Description

{Photoelectric devices using organic materials and porous nitrides and method for manubfacturing the same}

The present invention (Disclsoure) relates to an optoelectronic device, and specifically to an optoelectronic device using an organic material and porous nitride having improved electron collection capability (Electron collection) excited by solar absorption and a method for manufacturing the same.

Here, the background arts of the present invention are provided, and they do not necessarily mean the prior art.

Currently, a solar cell using a perovskite compound (hereinafter referred to as a 'perovskite solar cell') has been highlighted as a next generation solar cell with a high power conversion efficiency of 20.1%.

In addition, since perovskite solar cells are theoretically capable of 31% device efficiency, research into improving efficiency has been actively conducted worldwide.

The perovskite solar cell basically consists of a perovskite material that is a light absorber, an electron transfer layer (ETL), and a hole transfer layer (HTL).

In particular, since the device performance of the electron transport layer and the hole transport layer is highly dependent on the material selection and deposition process, consideration for this is essential in manufacturing solar cells.

The electron transport layer must have a wide band gap energy where light is not absorbed, and excellent charge transfer (High Carrier Mobility and High Diffusion Length) characteristics are required.

Conventional perovskite solar cells used zinc oxide (ZnO) or titanium dioxide (TiO ₂ ) as the electron transport layer.

The electron transport layer material exhibits excellent properties in collecting electrons excited by light absorption (Electron Collection) or transferring them to an electrode (Electron Transfer).

However, as the demand for improving device efficiency is increasing day by day, research on new electron transport layer materials to replace existing materials is necessary.

As the electron transport layer, TiO ₂ is one of the highest efficiency electron transport layer materials.

However, TiO ₂ During production, a high temperature process temperature of 500 ℃ is required and ITO should be used as a transparent electrode.

In addition, since the perovskite material is decomposed by a photocatalytic reaction caused by ultraviolet rays or a problem of interfacial resistance due to surface modification, stability and reliability of the device are impaired.

ZnO as an electron transport layer also requires an ITO transparent electrode, and has problems in device stability and reliability.

ZnO is susceptible to moisture, and its device performance deteriorates rapidly with time exposed to air.

The ZnO used in the perovskite solar cell is usually produced by spin coating, but has a large degree of non-uniformity in crystallinity and thin film thickness in a large area process.

1. Korea Registered Patent Publication No. 10-1810155

An object of the present invention (Discloure) is to provide a photoelectric device using an organic material and porous nitride with improved electron collection capability (electron collection) excited by solar absorption and a method of manufacturing the same.

Here, an overall summary of the present invention is provided, which should not be understood as limiting the periphery of the present invention (This section provides a general summary of the disclosure and is not a comprehensive disclosure of its full scope or all of its features).

In order to solve the above problems, the photoelectric device using an organic material and a porous nitride according to an aspect of the present invention, the substrate; A group III nitride-based compound layer grown on the substrate; A first electrode formed on the group 3 nitride-based compound layer; A porous layer in which at least part of the group 3 nitride-based compound layer is formed by wet etching; A light absorption layer formed on the porous layer and provided with an organic material or a perovskite compound; A hole transport material layer formed on the light absorption layer and provided as a p-type semiconductor layer; And a second electrode provided on the hole transport material layer.

In a photoelectric device using an organic material and a porous nitride according to an aspect of the present invention, the group 3 nitride-based compound layer is provided with n-type In (x) Ga (1-x) N (0≤x <1) It is characterized by being.

In a photoelectric device using an organic material and a porous nitride according to an aspect of the present invention, the first electrode and the second electrode are in the group consisting of Au, Ag, Cr, Ni, Mo, Pt, Al and Cu. It is characterized by being provided with at least one selected material and these alloys.

In the photoelectric device using an organic material and a porous nitride according to an aspect of the present invention, the substrate is provided with any one selected from sapphire (Al ₂ O ₃ ) substrate, silicon substrate, glass substrate, metal and synthetic resin substrate It is characterized by.

A method of manufacturing an optoelectronic device using an organic material and a porous nitride according to an aspect of the present invention, a first step of growing the group III nitride-based compound layer on the substrate; A second step of forming the first electrode on the group 3 nitride-based compound layer and depositing SiO ₂ on the first electrode; A third step of etching the group 3 nitride-based compound layer by an electrochemical wet etching method to form the porous layer; A fourth step of forming the light absorption layer on the group 3 nitride-based compound layer including the first electrode; A fifth step of forming the hole transport material layer on the light absorption layer; A sixth step of exposing the first electrode by removing SiO ₂ from the light absorbing layer; And a seventh step of forming the second electrode on the hole precursor material layer.

In a method of manufacturing an optoelectronic device using an organic material and a porous nitride according to an aspect of the present invention, the light absorbing layer is provided with a perovskite compound, and is characterized in that it is formed by spin coating.

According to the present invention, since the specific surface area of the group 3 nitride layer is increased by the porous layer, electron collection by the group 3 nitride layer is improved, thereby improving the performance of the photoelectric device.

In addition, as the electron transport layer, unlike the conventional TiO ₂ or ZnO, an ITO transparent electrode is not required, and thus has a process advantage.

1 is a view showing an embodiment of a photoelectric device using an organic material and a porous nitride according to the present invention.
Figure 2 is a flow chart showing a method of manufacturing a photoelectric device using an organic material and a porous nitride according to the present invention.
3 to 6 are views showing the manufacturing method of FIG. 2 step by step.

Hereinafter, embodiments of the photoelectric device using the organic material and the porous nitride according to the present invention and a method of manufacturing the same will be described in detail with reference to the drawings.

However, the spirit of the present invention cannot be said to be limited by the embodiments described below, and those skilled in the art who understand the spirit of the present invention are included within the scope of the same technical spirit as the present disclosure. Although embodiments can be easily proposed as a method of substitution or modification, it is revealed that this is also included in the technical spirit of the present invention.

In addition, the terms used hereinafter are selected for convenience of explanation, and in grasping the technical contents of the present invention, it should not be limited to the dictionary meaning and should be interpreted appropriately in accordance with the technical spirit of the present invention.

First, a photoelectric device using an organic material and a porous nitride according to the present invention will be described.

1 is a view showing an embodiment of a photoelectric device using an organic material and a porous nitride according to the present invention.

Referring to FIG. 1, a photoelectric device 100 using an organic material and a porous nitride according to the present embodiment includes a substrate 110, a group 3 nitride-based compound layer 120, a first electrode 130, and a porous layer 121 ), A light absorbing layer 140, a hole transport material layer 150 and a second electrode 160.

As the substrate 110, a flexible substrate including a sapphire substrate, a silicon substrate, a glass substrate, and a metal and plastic substrate may be used, and the shape or type of the substrate is not specifically limited.

The group 3 nitride-based compound layer 120 is provided by being grown on the substrate 110 and has n-type conductivity.

The group 3 nitride-based compound layer 120 may be grown on the undoped GaN having no n-type conductivity and a buffer layer (or a defect mitigating layer) first grown to mitigate defects generated during growth.

The group 3 nitride-based compound layer 120 is preferably provided with n-type In (x) Ga (1-x) N (0≤x <1), and can be grown by MOCVD or MBE.

Meanwhile, the group 3 nitride-based compound layer 120 may be formed by repeatedly stacking n-type GaN and n-type In (x) Ga (1-x) N (0 <x <1). At this time, it may be formed of a superlattice structure.

In addition, the group 3 nitride-based compound layer 120 may be formed of a material having the same composition, but may be provided in a form in which the n-type doping concentration is sequentially changed.

The thickness of the group 3 nitride-based compound layer 120 may be 1 nm to several hundred um.

The first electrode 130 is made of at least one material selected from the group consisting of Au, Ag, Cr, Ni, Mo, Pt, Al, and Cu and these alloys.

This is the same in the second electrode 160.

The porous layer 121 is preferably formed by an electrochemical etching method, but does not exclude dry etching through patterning.

The light absorbing layer 140 is formed on the porous layer 121 and is formed of an organic material or a perovskite compound.

The Perovskite compound is a crystal structure having ABX3 formula (A, M is a cation, X is an anion) and is defined as a metal oxide having a special structure that shows not only the properties of the non-conductor, semiconductor, and conductor, but also superconductivity.

The hole transport material layer 150 is stacked on the light absorbing layer 140 and is provided as a p-type semiconductor layer, and may be provided as a spiro-MeOTAD.

In the photoelectric device 100 using the organic material and the porous nitride according to the present embodiment, the porous n-type In (x) Ga (1-x) N (0≤x <1) is applied to the perovskite or organic photoelectric device. It is proposed as a necessary electron transport layer.

The n-type In (x) Ga (1-x) N (0≤x <1) has a wide energy bend and high electron mobility.

This high electron mobility not only helps to alleviate the hysteresis caused by the imbalance of the existing hole-electron separation, but also reduces the recombination rate of electrons, thereby improving device performance.

In addition, since the electron diffusion coefficient has a much larger value than that of the existing ZnO or TiO ₂ , it can be said that GaN is highly replaceable as the next-generation electron transport layer of the perovskite solar cell.

In particular, the porous layer has an advantage of improving the fill factor (the ratio of the maximum power to the product of the open voltage (Voc) and the short circuit current (Isc)).

Next, a method of manufacturing the photoelectric device using the organic material and the porous nitride according to the present embodiment will be described.

2 is a flow chart showing a method of manufacturing a photoelectric device using an organic material and a porous nitride according to the present invention, FIGS. 3 to 6 are views showing the manufacturing method of FIG. 2 step by step.

2 to 7, a method for manufacturing an optoelectronic device using an organic material and a porous nitride according to the present embodiment includes a nitride growth step (S100), a first electrode formation step (S200), and a porosity step (S300), It includes a light absorption layer deposition step (S400), a hole transport material layer forming step (S500), and a second electrode forming step (S600).

The nitride growth step (S100) is a step of growing the group III nitride-based compound layer 120 on the substrate 110.

As the substrate 110, a flexible substrate including a sapphire substrate, a silicon substrate, a glass substrate, and a metal and plastic substrate may be used, and the shape or type of the substrate is not specifically limited.

The group 3 nitride-based compound layer 120 is preferably provided with n-type In (x) Ga (1-x) N (0≤x <1), and can be grown by MOCVD or MBE.

The first electrode forming step (S200) is made of at least one material selected from the group consisting of Au, Ag, Cr, Ni, Mo, Pt, Al, and Cu and these alloys, and SiO ₂ is disposed on the first electrode 130. Is preferably deposited.

The porous step (S300) is a step of forming the porous layer 121 by etching the group 3 nitride-based compound layer 120 by an electrochemical wet etching method.

The light absorption layer deposition step (S400) is a step of forming the light absorption layer 140 on the group III nitride-based compound layer 120 including the first electrode 130.

The light absorbing layer 140 is formed of a perovskite compound, and is formed by spin coating.

The hole transport material layer forming step (S500) is formed by spin coating a spiro-MeOTAD as the hole transport material layer 150.

The second electrode forming step (S600) is made of at least one material selected from the group consisting of Au, Ag, Cr, Ni, Mo, Pt, Al and Cu and alloys similar to the first electrode forming step (S200). It is provided.

On the other hand, by removing the SiO ₂ formed on the top of the first electrode 130 before or after the second electrode forming step (S600), the light absorbing layer 140 surrounding the first electrode 130 and the hole transport material layer The first electrode 130 can be exposed by removing the 150.

Claims (6)

Board;
A group III nitride-based compound layer grown on the substrate and provided with n-type In (x) Ga (1-x) N (0 <x <1);
A first electrode formed on the group 3 nitride-based compound layer;
A porous layer in which at least part of the group 3 nitride-based compound layer is formed by wet etching;
A light absorption layer formed on the porous layer and provided with an organic material or a perovskite compound;
A hole transport material layer formed on the light absorption layer and provided as a p-type semiconductor layer; And
It includes; a second electrode provided on the hole transport material layer;
The first electrode and the second electrode are characterized by being provided with at least one material selected from the group consisting of Au, Ag, Cr, Ni, Mo, Pt, Al and Cu and these alloys,
The substrate is a sapphire (Al ₂ O ₃ ) substrate, a silicon substrate, a glass substrate, a photoelectric device using an organic material and a porous nitride, characterized in that provided with any one selected from a metal and synthetic resin substrate.

delete delete delete delete delete

Images