KR102089612B1 - Perovskite-based solar cell of large area - Google Patents

Abstract

The present invention relates to a large area perovskite solar cell comprising an organic charge transport layer and a perovskite layer, by providing an amphiphilic material layer between the organic charge transport layer and the perovskite layer, the conventional hydrophobic organic charge It solves the problem that the efficiency decreases rapidly when the area of the perovskite solar cell increases due to insufficient surface coverage due to the phenomenon that the hydrophilic perovskite precursor solution is not evenly applied on the transport layer. As a result, a perovskite solar cell can be manufactured.

Description

Large area perovskite solar cell {PEROVSKITE-BASED SOLAR CELL OF LARGE AREA}

The present invention relates to a large area perovskite solar cell that solves the problem of rapidly decreasing efficiency when the area of a conventional perovskite solar cell increases.

With the development of modern society, various forms of energy consumption are rapidly increasing every year. For this reason, the depletion and environmental pollution of fossil raw materials, which are the main energy source of today's industry, is one of the most urgent tasks that humanity needs to solve, and is making continuous efforts to develop renewable eco-friendly energy worldwide.

Solar energy, which is an infinite source of clean energy, sends 3X10 ²¹ kJ of energy to the Earth, which is 10,000 times the world's energy consumption. Typical technologies for converting such enormous amounts of solar energy into required energy types such as electricity and heat include water decomposition using a photovoltaic effect and solar cells.

In particular, solar cells are being used to a large extent, accounting for 25% of the world's eco-friendly energy production. If 10% efficiency solar cells can be installed in an area corresponding to 0.1% of the earth's area through active development and utilization of solar cells, all the energy currently required can be produced. Humanity can get enough energy.

The perovskite solar cell is a solar cell device that uses an organic-inorganic composite material having a perovskite structure as a light absorber, and has the advantages of high efficiency, low material cost, and low-temperature process or low-cost solution process. Since it has most of the characteristics required for solar cells, it is spotlighted as a new solar cell to replace silicon solar cells.

One cause of the perovskite solar cell showing high photoelectric conversion efficiency is that the perovskite light absorbing layer has a high absorbance in the visible light region, absorbing sufficient light even at a thickness of 0.5 μm or less to generate a large amount of charge. Because.

In recent years, the wind of a big change is blowing in the study of solar cells. Next-generation solar cells that have been stagnant for 10 years, solid-state perovskite solar cells (SCs) using organic-inorganic composite perovskite light absorbers reported in 2012 recorded a high efficiency of 20.1% in 3 years It is a great vitality for research. The high efficiency is a performance close to that of a silicon solar cell.

Therefore, the recent research trend has rapidly shifted to the device life increase and the production of large-area devices, which are important for actual commercialization. Although recent research has resulted in a significant increase in device life, most of the high performance perovskite solar cells have been implemented in a small area due to the difficulty of obtaining a uniform perovskite film in a large area. Only a few studies have shown successful device realization of large areas in an area of 1 cm ² , but still porous and crystalline metal oxides, such as titanium dioxide and nickel oxide, require high process temperatures (above 450 ° C), making flexible plastics Inexpensive roll-to-roll printing processes using substrates cannot be applied.

Accordingly, there is a need for a new perovskite solar cell that can increase the lifespan while being able to manufacture a large area of perovskite solar cells.

Republic of Korea Patent Publication No. 10-2004-0079884

Hanyang University, 2016 Master Thesis, Hyewon Lee

An object of the present invention is to provide a large area perovskite solar cell having an interlayer material layer between the organic charge transport layer and the perovskite layer.

The large area perovskite solar cell of the present invention is a large area perovskite solar cell comprising an organic charge transport layer and a perovskite layer,

An interlayer material layer may be provided between the organic charge transport layer and the perovskite layer.

The interlayer material layer may include an amphiphilic polymer or a first metal oxide.

The amphiphilic polymer may be a combination of a hydrophobic skeleton and a hydrophilic functional group, preferably expressed by a compound of the following [Formula 1] to [Formula 4], more preferably the following [Formula 5] to [Formula 5] 7].

로 이루어진 군에서 서로 같거나 각각 독립적으로 선택되며; * 표시는 결합부위를 나타내고; 상기 R₃ 및 R₄는 OH, SH, NH2 및 COOH로 이루어진 군에서 선택되며; A₁ 내지 A₃는 N⁺, F^-, O^-로 이루어진 군에서 선택되고; n은 1 내지 100의 정수이다. In Formulas 1 to 4, R ₁ And R ₂ is hydrogen, a substituted or unsubstituted alkyl group having 1 to 10 carbon atoms, a substituted or unsubstituted allyl group having 1 to 60 carbon atoms,

Is selected from the group consisting of the same or independently of each other; * Indicates a binding site; R ₃ And R ₄ is selected from the group consisting of OH, SH, NH2 and COOH; A ₁ to A ₃ is N ^+, F ^- is selected from the group consisting of ^-, O; n is an integer from 1 to 100.

The compounds of Formulas 1 and 2, wherein A ₁ to A ₃ are ions, are present in the form of salts.

In formulas 5 to 7, n is an integer from 1 to 100.

The first metal oxide may be at least one selected from the group consisting of titanium oxide (TiOx), molybdenum oxide (MoO3), zinc oxide (ZnO), vanadium oxide (VOx), and tungsten oxide (WO3).

The organic charge transport layer may be an organic electron transport layer or an organic hole transport layer, and the organic charge transport layer in contact with the interlayer material layer is poly (N, N-bis (4-butylphenyl) -N, N-bis (phenyl) benzidine [ poly (N, N-bis (4-butylphenyl) -N, N-bis (phenyl) benzidine); PTPD], polythiophene derivative; P3HT, diketopyrrolopyrrole derivative; TT], poly (Thyeno [3,4-b] thiophene-alt-benzodithiophene derivative [poly (thieno [3,4-b] thiophene-alt-benzodithiophene) derivative; PTB7-Th], poly (phenylene vinyl Len) derivatives (poly (phenylene vinylene) derivative; MEH-PPV), polycarbazole derivatives (PCDTBT), poly [bis (4-phenyl) (2,4,6-trimethylphenyl) amine [poly [bis] (4-phenyl) (2,4,6-trimethylphenyl) amine; PTAA] and phenyl-C61-butyric acid methyl ester (PCBM).

The large area perovskite solar cell comprises a first electrode comprising a conductive transparent substrate; A first organic charge transport layer formed on the first electrode; An interlayer material layer selected from an amphiphilic polymer and a first metal oxide formed on the organic charge transport layer; A perovskite layer formed on the interlayer material layer; A second organic charge transport layer formed on the perovskite layer; And a second electrode formed on the second organic charge transport layer.

A second metal oxide layer may be added between the second organic charge transport layer and the second electrode, and the second metal oxide layer is made of titanium oxide (TiOx), molybdenum oxide (MoO3), and zinc oxide (ZnO). It may include a second metal oxide at least one selected from.

In the large-area perovskite solar cell of the present invention, the perovskite precursor solution is evenly coated on all surfaces by an interlayer material layer provided between the organic charge transport layer and the perovskite layer, and thus on a conventional hydrophobic organic charge transport layer. The problem that the efficiency decreases rapidly when the area of the perovskite solar cell is increased due to insufficient surface coverage due to the phenomenon in which the hydrophilic perovskite precursor solution is not evenly applied (dewetting) is solved.

In addition, even if the perovskite solar cell of the present invention is manufactured in a large area, performance is not degraded, reproducibility is improved, and life is improved.

1 is a view showing an ITO / organic hole transport layer / PFN / CH3NH3PbI3 (Perovskite) / electron transport layer / aluminum perovskite solar cell device manufactured according to Example 5 of the present invention.
Figure 2a is a schematic diagram showing the formation of a perovskite layer depending on the presence of an amphiphilic polymer layer between the organic charge transport layer and the perovskite layer, Figure 2b is an amphiphilic polymer provided between the organic charge transport layer and the perovskite layer It is a diagram showing the interaction of layers.
3A is a photograph showing the contact angle of water on the hole transport layer / PFN prepared according to Examples 1 to 6 and Comparative Examples 1 to 6, and FIG. 3B is on the hole transport layer / PFN prepared according to Examples 1 to 6 The perovskite precursor solution is a photograph showing the coated form, Figure 3c is a graph analyzing the hole transport layer / PFN / perovskite layer prepared according to Examples 1 to 6 by XRD.
Figure 4a is a graph showing the current-voltage curve of the perovskite solar cell prepared according to Examples 1 to 6, Figure 4b is a series of perovskite solar cells prepared according to Examples 1 to 6 ( Rs ) And Shunt ( Rsh ).
Figure 5a is a graph showing the current-voltage curve according to the area size of the perovskite solar cell prepared according to Comparative Example 5, Figure 5b is an area size of the perovskite solar cell prepared according to Example 5 It is a graph showing the current-voltage curve, Figure 5c is a graph showing the efficiency according to the area size of the perovskite solar cell prepared according to Example 5 and Comparative Example 5, Figure 5d is Example 5 and Comparative Example 5 is a photograph showing the formation of the perovskite layer according to the area size of the perovskite solar cell manufactured according to 5 (the region of the brown system corresponds to the PCBM layer deposited on the perovskite layer), and FIG. 4.6X4 cm2) is a photograph of the perovskite solar cell produced, and FIG. 5F is a graph showing the current-voltage curve of the perovskite solar cell manufactured in FIG. 5E.
Figure 6a is a graph measuring the power conversion efficiency (PCE) of the perovskite solar cell prepared according to the control group, Example 5 and Example 7, Figure 6b is a perovskite solar cell prepared according to the control group A graph showing the current-voltage curve, and FIG. 6C is a graph showing the current-voltage curve of the perovskite solar cell manufactured according to Example 5, and FIG. 6D is a perovskite solar prepared according to Example 7 It is a graph showing the current-voltage curve of the battery.
Figure 7a is a photo showing the contact angle of water on the hole transport layer / amphiphilic polymer prepared according to Examples 8 and 9, Figure 7b is a current-voltage curve of the perovskite solar cell prepared according to Examples 8 and 9 It is a graph showing.
8A is a photograph showing the contact angle of water on the hole transport layer / affinity polymer prepared according to Example 10 and the contact angle of water on the hole transport layer prepared according to Comparative Example 7, FIG. It is a graph showing the current-voltage curve of a lobsky solar cell.
9A is a photograph showing the contact angle of water on the electron transport layer / affinity polymer prepared according to Example 11 and the contact angle of water on the electron transport layer prepared according to Comparative Example 8, and FIG. It is a graph showing the current-voltage curve of a lobsky solar cell.
10A is a photograph showing a contact angle of water on an electron transport layer / metal oxide prepared according to Example 12, and FIG. 10B is a graph showing a current-voltage curve of a perovskite solar cell prepared according to Example 12.
FIG. 11A is a photograph showing the contact angle of water on the electrotransport layer / metal oxide prepared according to Example 13, and FIG. 11B is a graph showing the current-voltage curve of the perovskite solar cell prepared according to Example 13.

The present invention is to provide a large area perovskite solar cell that solves the problem of rapidly decreasing efficiency when the area of the conventional perovskite solar cell is increased by providing an interlayer material layer between the organic charge transport layer and the perovskite layer. It is about.

The flat type perovskite solar cell incorporating the organic charge transport layer is a promising structure to replace the metal oxide based device structure. The planar device structure incorporating the organic charge transport layer has various advantages such as the ability to approximate the current porous metal oxide-based device structure and has little hysteresis, the low temperature process, and the applicability to roll-to-roll processes capable of mass production. have. Despite these advantages, the perovskite solar cell based on the organic charge transport layer has been manufactured only in a small area (0.1 cm ² or less) but not in a large area.

Conventional flat-type perovskite solar cells have an inherent problem called a surface coverage issue that is the biggest obstacle to the production of large-area perovskite solar cells. This problem is due to the extreme surface energy difference between the hydrophobic organic charge transport layer and the precursor solution of an ionic material-based hydrophilic perovskite consisting of organic / inorganic cations and halogen anions. For this reason, the manufactured perovskite film shows many pinholes and random surface coverage. Although the doped wettability and hydrophilic organic charge transport layer can alleviate this problem, these polymers have hygroscopic properties and may adversely affect the device life of the perovskite solar cell. The perovskite solar cell employing the transport layer has a problem of poor performance. Therefore, the development of a new method that facilitates the production of a high-quality perovskite film on a hydrophobic organic charge transport layer is essential for achieving stable, large-area, and high-performance perovskite solar cells.

The present invention can produce a high quality large area perovskite layer on all hydrophobic organic charge transport layers. An amphiphilic polymer electrolyte or metal oxide is introduced as an interfacial compatibilizer to control the surface energy of the organic charge transport layer, thereby improving the wettability of the perovskite precursor solution on the organic charge transport layer and pinhole-free film through the solution process. Produced. This interfacial engineering technology enables precise energy level matching between the perovskite layer and the organic charge transport layer through the introduction of various organic charge transport layers, making it possible to fabricate high-efficiency solar cells of 18 to 22% without hysteresis. The fabricated solar cell shows long-term stability, and exhibits performance of 75 to 85% of its initial efficiency even when stored in the air for 15 to 20 days without encapsulation. This figure is the highest value in a printable perovskite solar cell without a metal oxide based charge transport layer that requires a high temperature process.

Hereinafter, the present invention will be described in detail.

The large area perovskite solar cell of the present invention is composed of a plurality of layers in addition to the organic charge transport layer and the perovskite layer. Specifically, an interlayer material layer is provided between the organic charge transport layer and the perovskite layer.

The interlayer material layer includes an amphiphilic polymer or a first metal oxide.

The amphiphilic polymer is a material having an amphiphilic property having a structure in which a hydrophobic skeleton and a hydrophilic functional group are combined, and is provided between a hydrophobic organic charge transport layer and a hydrophilic perovskite layer, which is excellent in both layers. It is possible to provide a large area perovskite thin film by dramatically improving the wettability of the hydrophobic organic charge transport layer showing adhesive properties.

The amphiphilic polymer may include a conjugated polymer electrolyte (CPE) or a non-conjugated polymer electrolyte (NPE), and may be preferably represented by the following compounds of [Formula 1] to [Formula 4].

[Formula 1]

[Formula 2]

[Formula 3]

[Formula 4]

로 이루어진 군에서 서로 같거나 각각 독립적으로 선택되며; * 표시는 결합부위를 나타내고; 상기 R₃ 및 R₄는 OH, SH, NH2 및 COOH로 이루어진 군에서 선택되며; A₁ 내지 A₃는 N⁺, F^-, O^-로 이루어진 군에서 선택되고; n은 1 내지 100의 정수이다. In Formulas 1 to 4, R ₁ And R ₂ is hydrogen, a substituted or unsubstituted alkyl group having 1 to 10 carbon atoms, a substituted or unsubstituted allyl group having 1 to 60 carbon atoms,

Is selected from the group consisting of the same or independently of each other; * Indicates a binding site; R ₃ And R ₄ is selected from the group consisting of OH, SH, NH2 and COOH; A ₁ to A ₃ is N ^+, F ^- is selected from the group consisting of ^-, O; n is an integer from 1 to 100.

The compounds of Formulas 1 and 2, wherein A ₁ to A ₃ are ions, are present in the form of salts.

In addition, the amphiphilic polymer may be more preferably represented by the compounds of [Formula 5] to [Formula 7].

[Formula 5]

[Formula 6]

[Formula 7]

In formulas 5 to 7, n is an integer from 1 to 100.

The hydrophobic organic charge transport layer is an organic electron transport layer or an organic hole transport layer, and the type thereof is not particularly limited as long as it can be used as an organic electron transport layer or an organic hole transport layer, but is preferably the following [Formula 8] to [Formula 8] 15] Poly (N, N-bis (4-butylphenyl) -N, N-bis (phenyl) benzidine [poly (N, N-bis (4-butylphenyl) -N, N-bis (phenyl) benzidine); PTPD], polythiophene derivative; P3HT, diketopyrrolopyrrole derivative; TT], poly (thieno [3,4-b] thiophene-alt-benzodithiophene derivative) [poly (thieno [3,4-b] thiophene-alt-benzodithiophene) derivative; PTB7-Th], poly (phenylene vinylene) derivative; MEH-PPV], polycarbazole derivative [ polycarbazole derivative; PCDTBT], poly [bis (4-phenyl) (2,4,6-trimethylphenyl) amine [poly [bis (4-phenyl) (2,4,6-trimethylphenyl) amine; PTAA] It may be at least one selected from the group consisting of; [PCBM phenyl-C61-butyric acid methyl ester] phenyl -C61- acid methyl ester.

[Formula 8] PTPD

[Formula 9] P3HT

[Formula 10] TT

[Formula 11] PTB7-Th

[Formula 12] MEH-PPV

[Formula 13] PCDTBT

[Formula 14] PTAA

[Formula 15] PCBM

In Formulas 8 to 14, n is an integer from 1 to 100.

In addition, the first metal oxide is not particularly limited as long as it is in the form of an oxide of a dislocation metal, but is preferably titanium oxide (TiOx), molybdenum oxide (MoO3), zinc oxide (ZnO), vanadium oxide (VOx), and tungsten oxide (WO3). ).

In one example, the titanium oxide (TiOx) precursor may be represented by the following [Formula 16].

[Formula 16]

In Formula 16, R is selected from the group consisting of hydrogen, a substituted or unsubstituted alkyl group having 1 to 10 carbon atoms, a substituted or unsubstituted allyl group having 1 to 60 carbon atoms, and CH2CH2OCH3.

The structure of the large area perovskite solar cell of the present invention is not particularly limited as long as it is a structure in which an interlayer material layer is provided between the organic charge transport layer and the perovskite layer, but is preferably a first electrode including a conductive transparent substrate; A first organic charge transport layer formed on the first electrode; An interlayer material layer formed on the organic charge transport layer; A perovskite layer formed on the interlayer material layer; A second organic charge transport layer formed on the perovskite layer; And a second electrode formed on the second organic charge transport layer.

The precursor solution forming the first and second electrodes and the perovskite is not particularly limited as long as it is a material generally used in the field of perovskite solar cells and can be used.

In addition, the present invention provides a second metal oxide layer including a second metal oxide between the second organic charge transport layer and the second electrode to extend the life of the perovskite solar cell and further maintain initial performance for a long time. To add.

The second metal oxide may include at least one selected from the group consisting of titanium oxide (TiOx), molybdenum oxide (MoO3), and zinc oxide (ZnO).

Hereinafter, a preferred embodiment is provided to help the understanding of the present invention, but the following examples are merely illustrative of the present invention, and it is apparent to those skilled in the art that various changes and modifications are possible within the scope and technical scope of the present invention. It is no wonder that such variations and modifications fall within the scope of the appended claims.

Manufacturing example  One. Perovskite  Precursor solution

A CH3NH3PbI3 solution of 1.5 molar concentration was prepared by dissolving a mixture of PbI2 (Alfa Aesar) and CH3NH3I (Dyesol) in a 1: 1 molar ratio in a N, N-dimethylformamide / dimethylsulfoxide (9: 1 volume ratio) mixed solvent.

Manufacturing example  2. Titanium oxide precursor solution

The titanium oxide precursor solution was prepared by mixing 0.1 ml of titanium isopropoxide (Sigma Aldrich), 0.05 ml of ethanol amine, and 30 ml of isopropanol solvent.

Control. PEDOT : PSS / CH3NH3PbI3

The solar cell device was fabricated in an ITO / organic hole transport layer / CH3NH3PbI3 (Perovskite) / electron transport layer / aluminum structure.

After spin-coating PEDOT: PSS (poly (3,4-ethylenedioxythiophene): poly (styrenesulfonate), AI 4083 grade) on UV-ozone treated ITO substrate at 5000 rpm, heat treatment at 150 ° C for 10 minutes to form an organic hole transport layer Then, on the PEDOT: PSS layer, the perovskite precursor solution prepared in Preparation Example 1 was spin-coated at 4000 rpm for 30 seconds to form a perovskite layer, 7 seconds after spin-coating with the perovskite precursor solution began. After that, 0.6 ml of diethyl ether is sprinkled on the perovskite film being spin coated, and when spin coating is completed, heat treatment is performed at 100 ° C for 10 minutes. On the perovskite layer, a solution in which PCBM material was dissolved in a chlorobenzene solvent at a concentration of 40 mg ml ^-1 was spin-coated at 1500 rpm for 20 seconds to form an electron transport layer. Lastly, a large area perovskite solar cell was prepared by depositing an aluminum electrode on the electron transport layer by thermal treatment under high vacuum conditions.

Example  One. P3HT / PFN / CH3NH3PbI3

The solar cell device was made of ITO / organic hole transport layer / PFN / CH3NH3PbI3 (Perovskite) / electron transport layer / aluminum structure.

After forming the organic hole transport layer by spin-coating a compound (P3HT) of [Formula 9] at 5000 rpm on an ultraviolet-ozone treated ITO substrate, and then spin-coating the compound (PFN solution) of [Formula 5] at 5000 rpm A polymer layer was formed. The perovskite precursor solution prepared in Preparation Example 1 was spin coated on the PFN layer at 4000 rpm for 30 seconds to form a perovskite layer, 0.6 ml after 7 seconds after spin coating with the perovskite precursor solution started. Sprinkle diethyl ether of on the perovskite film under spin coating, and heat-treat at 100 ° C for 10 minutes when spin coating is completed. On the perovskite layer, a solution in which PCBM material was dissolved in a chlorobenzene solvent at a concentration of 40 mg ml ^-1 was spin-coated at 1500 rpm for 20 seconds to form an electron transport layer. Lastly, a large area perovskite solar cell was prepared by depositing an aluminum electrode on the electron transport layer by thermal treatment under high vacuum conditions.

When the size of the substrate is 18.4 cm2, the perovskite film being spin-coated with 3 ml of diethyl ether 10 seconds after spin coating with a perovskite precursor solution when forming the perovskite layer Sprinkle on top.

Example  2. TT / PFN / CH3NH3PbI3

A large area perovskite solar cell was prepared in the same manner as in Example 1, using the compound (TT) of [Formula 10] instead of the compound (P3HT) of [Formula 9].

Example  3. PTB7 - Th / PFN / CH3NH3PbI3

A large area perovskite solar cell was prepared in the same manner as in Example 1, but using the compound (PTB7-Th) of [Formula 11] instead of the compound (P3HT) of [Formula 9].

Example  4. MEH -PPV / PFN / CH3NH3PbI3

A large area perovskite solar cell was prepared in the same manner as in Example 1, using the compound of [Formula 12] (MEH-PPV) instead of the compound of [Formula 9] (P3HT).

Example  5. PTPD / PFN / CH3NH3PbI3

A large area perovskite solar cell was prepared in the same manner as in Example 1, using the compound (PTPD) of [Formula 8] instead of the compound (P3HT) of [Formula 9] (FIG. 1).

Example  6. PCDTBT / PFN / CH3NH3PbI3

A large-area perovskite solar cell was prepared in the same manner as in Example 1, using the compound (PCDTBT) of [Formula 13] instead of the compound (P3HT) of [Formula 9].

Example  7. PTPD / PFN / CH3NH3PbI3 / Electron transport layer / TiOx

The solar cell device was fabricated with ITO / hole transport layer / PFN / CH3NH3PbI3 (Perovskite) / electron transport layer / TiOx / silver structure.

Performed in the same manner as in Example 5, after forming a metal oxide layer by spin-coating a TiOx solution at 5000 rpm for 20 seconds on an electron transport layer formed of a PCBM material, and finally depositing a silver electrode in a high vacuum condition by heat treatment to obtain a large area. Perovskite solar cells were prepared.

Example  8. PTPD / PEO / CH3NH3PbI3

A large area perovskite solar cell was prepared in the same manner as in Example 5, using the compound of Formula 6 (PEO solution) instead of the compound of Formula 5 (PFN solution).

Example  9. PTPD / PVA / CH3NH3PbI3

A large area perovskite solar cell was prepared in the same manner as in Example 5, using the compound of Formula 7 (PVA solution) instead of the compound of Formula 5 (PFN solution).

Example  10. PTAA / PFN / CH3NH3PbI3

A large-area perovskite solar cell was prepared in the same manner as in Example 1, using the compound (PTAA) of [Formula 14] instead of the compound (P3HT) of [Formula 9].

Example  11. PCBM / PFN / CH3NH3PbI3

The solar cell device was fabricated with ITO / PCBM / PFN / CH3NH3PbI3 (Perovskite) / hole transport layer / silver structure.

After forming the organic electron transport layer by spin coating the compound (PCBM) of [Formula 15] at 1200 rpm on the UV-ozone treated ITO substrate, spin-coating the compound (PFN solution) of [Formula 5] at 5000 rpm for amphiphilic properties. A polymer layer was formed. The perovskite precursor solution prepared in Preparation Example 1 was spin coated on the PFN layer at 4000 rpm for 30 seconds to form a perovskite layer, 0.6 ml after 7 seconds after spin coating with the perovskite precursor solution started. Sprinkle diethyl ether of on the perovskite film under spin coating, and heat-treat at 100 ° C for 10 minutes when spin coating is completed. On the perovskite layer, a solution in which PTAA material was dissolved in a toluene solvent at a concentration of 10 mg ml ^-1 was spin-coated at 3000 rpm for 20 seconds to form a hole transport layer. Finally, a large-area perovskite solar cell was prepared by depositing a silver electrode on the hole transport layer in a high-vacuum condition by a heat treatment method.

Example  12. PCBM / TiOx (Metal oxide) / CH3NH3PbI3

An electron transport layer formed of a PCBM material of the compound (TiOx solution, R = CH2CH2OCH3) of [Formula 16] which is a metal oxide prepared in Preparation Example 2 instead of the compound (PFN) of [Formula 5] A large area perovskite solar cell was prepared by spin coating at 5000 rpm for 20 seconds and heat treatment at 80 ° C for 10 minutes.

Example  13. PTPD / MoO3 (Metal oxide) / CH3NH3PbI3

The same procedure as in Example 5 was carried out, but instead of the compound (PFN solution) of [Formula 5], molybdenum oxide, which is a metal oxide, was deposited by heat treatment under high vacuum conditions to prepare a large area perovskite solar cell.

Comparative example  One. P3HT / CH3NH3PbI3

In the same manner as in Example 1, the process of forming the amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

Comparative example  2. TT / CH3NH3PbI3

In the same manner as in Example 2, the process of forming the amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

Comparative example  3. PTB7 - Th / CH3NH3PbI3

In the same manner as in Example 3, the process of forming the amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

Comparative example  4. MEH -PPV / CH3NH3PbI3

In the same manner as in Example 4, a process of forming an amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

Comparative example  5. PTPD / CH3NH3PbI3

In the same manner as in Example 5, the process of forming the amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

Comparative example  6. PCDTBT / CH3NH3PbI3

In the same manner as in Example 6, the process of forming the amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

Comparative example  7. PTAA / CH3NH3PbI3

In the same manner as in Example 10, a process for forming an amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

Comparative example  8. PCBM / CH3NH3PbI3

In the same manner as in Example 11, the process of forming the amphiphilic polymer layer was omitted to prepare a perovskite solar cell.

< Test example >

Test example  One. Amity Polymer layer  According to existence Perovskite layer  Shaping shape

Figure 2a is a schematic diagram showing the formation of a perovskite layer according to the presence of an amphiphilic polymer (PFN) layer between the organic charge transport layer (PTPD) and the perovskite layer, Figure 2b is an organic charge transport layer (PTPD) and perovskite It is a diagram showing the interaction of amphiphilic polymer layer (PFN) provided between the skyt layers.

2A and 2B, PTPD was used as the organic charge transport layer, and PTPD is a HOMO (highest) of 5.4 eV that matches well with the valance band level of perovskite (CH ₃ NH ₃ PbI ₃ , 5.4 eV). It has an occupied molecular orbital (OCC) level, and has a high eosmolarity of 2.4 eV (lowest unoccupied molecular orbital), which can effectively prevent holes and suppress recombination of electrons and holes.

However, when the amphiphilic polymer (PFN) is not used, the very different polarity of the hydrophobic PTPD layer and the ionic material-based hydrophilic perovskite layer shows a thermodynamic repulsive interaction, and eventually the perovskite precursor solution Dewetting is not evenly caused, so that the complete surface coverage of the perovskite layer is not achieved (upper photo in FIG. 2A). As a result of measuring the perovskite layer thus prepared by SEM, it was confirmed that a large number of pinholes, voids and defects were generated (upper SEM photograph of FIG. 2A).

On the other hand, when using an amphiphilic polymer (PFN) between the hydrophobic PTPD layer and the perovskite layer, as in Example 5, the hydrophobic backbone and the hydrophilic ion end group coexist with PFN. It shows excellent interfacial contact to both PTPD layers (Fig. 2b).

When a very thin PFN layer (~ 5 nm) is coated on the PTPD layer, the surface energy of the PTPD layer can be effectively controlled, thereby dramatically improving the wettability of the perovskite precursor solution on the PTPD layer to improve the perovskite precursor. The solution can be evenly coated over the entire surface.

Test example  2. Amity Polymer layer  According to existence Contact angle , Perovskite layer  Shaping shape and XRD  Measure

3A is a photograph showing the contact angle of water on the hole transport layer / PFN prepared according to Examples 1 to 6 and Comparative Examples 1 to 6, and FIG. 3B is on the hole transport layer / PFN prepared according to Examples 1 to 6 The perovskite precursor solution is a photograph showing the coated form, Figure 3c is a graph analyzing the hole transport layer / PFN / perovskite layer prepared according to Examples 1 to 6 by XRD.

3A and 3B, it was confirmed that the contact angle of the water on the hole transport layer / PFN prepared according to Examples 1 to 6 was sharply lower compared to the contact angle of the water on the hole transport layer prepared according to Comparative Examples 1 to 6 (FIG. 3A), it was confirmed that the perovskite precursor solution was uniformly coated on the entire surface of the hole transport layer / PFN prepared according to Examples 1 to 6 (FIG. 3B).

In addition, as shown in Figure 3c, Examples 1 to 6 was confirmed that a polycrystalline perovskite layer was obtained on the organic hole transport layer / PFN through XRD analysis. In the XRD spectrum, it was confirmed that the tetragonal structure of CH3NH3PbI3-based perovskite showed two peaks, 14.11 ° and 28.45 °, corresponding to the (110) and (220) planes.

The biggest feature of the present invention is that an n-type amphiphilic polymer layer was used between the organic charge transport layer and the perovskite layer. Through ultraviolet photoelectron spectroscopy (UPS) analysis, the spectral shift of the organic static transport layer / PFN was negligible. This means that the PFN layer does not affect the electronic structure of the organic charge transport layer. The reason for this result is that similar dielectric properties of the PFN and the organic charge transport layer only cause slight image charge interaction, and eventually weaken the dipole effect at the interface. In addition, strong photoluminescence quenching of the perovskite layer fabricated on the organic hole transport layer / PFN means that the photogenerated holes in the perovskite can effectively move across the PFN. Therefore, it can be seen that PFN can control the surface energy of the hole transport layer.

Test example  3. Performance measurement

Figure 4a is a graph showing the current-voltage curve of the perovskite solar cell prepared according to Examples 1 to 6, Figure 4b is a series of perovskite solar cells prepared according to Examples 1 to 6 ( Rs ) And shunt ( Rsh ).

As shown in Figure 4a, it was confirmed that the perovskite solar cells prepared according to Examples 1 to 4 and 6 showed 12.68%, 14.01%, 14.83%, 15.82%, 14.66% performance, respectively.

In particular, it was confirmed that the perovskite solar cell manufactured according to Example 5 showed the highest performance of 19.14%.

In addition, as shown in FIG. 4B, the perovskite solar cells of Examples 1 to 6 confirmed a high FF value with little difference in Series ( Rs ) and shunt ( Rsh ) resistance.

In addition, the optical parameters of the perovskite solar cells of Examples 1 to 6 are shown in Table 1 below.

division J _sc (mAcm ^-2 ) V _oc (V) FF PCE (%) Control
(PEDOT: PSS) 16.60 0.84 0.76 10.60 Example 1
(P3HT / PFN) 18.31 0.87 0.79 12.68 Example 2
(TT / PFN) 18.64 0.93 0.80 14.01 Example 3
(PTB7-Th / PFN) 18.85 1.00 0.79 14.83 Example 4
(MEH-PPV / PFN) 19.16 1.05 0.79 15.82 Example 5
(PTPD / PFN) 21.23 1.11 0.81 19.14 Example 6
(PCDTBT / PFN) 18.23 1.03 0.78 14.66

As shown in Table 1 above, the perovskite solar cells prepared according to Examples 1 to 6 have a higher short-circuit current density (J _sc ), an open circuit voltage (V _oc ), a charge rate (FF), and power compared to a control group. It was confirmed that the conversion efficiency (PCE) was shown.

In particular, it was confirmed that the solar cell of Example 5 showed better short circuit current density (J _sc ), open circuit voltage (V _oc ), charging rate (FF), and power conversion efficiency (PCE) than the other groups.

These results show three conclusions. (i) The introduction of the amphiphilic polymer layer enables excellent surface coverage of the perovskite layer regardless of the type of organic charge transport layer. (ii) The amphiphilic polymer layer of the ultra-thin film does not interfere with the movement of holes. (iii) Due to the thin thickness (~ 10 nm), a hole transport layer having a low mobility that is not doped enables hole movement without loss.

Test example  4. Amity Polymer layer  Experiment by area of missing solar cell and solar cell

Figure 5a is a graph showing the current-voltage curve according to the area size of the perovskite solar cell prepared according to Comparative Example 5, Figure 5b is an area size of the perovskite solar cell prepared according to Example 5 It is a graph showing the current-voltage curve, Figure 5c is a graph showing the efficiency according to the area size of the perovskite solar cell prepared according to Example 5 and Comparative Example 5, Figure 5d is Example 5 and Comparative Example 5 is a photograph showing the formation of the perovskite layer according to the area size of the perovskite solar cell manufactured according to 5 (the region of the brown system corresponds to the PCBM layer deposited on the perovskite layer), and FIG. 4.6X4 cm2) is a photograph of the perovskite solar cell produced, and FIG. 5F is a graph showing the current-voltage curve of the perovskite solar cell manufactured in FIG. 5E.

In increasing the size of the perovskite solar cell, the amphiphilic polymer layer is an important means to allow the perovskite precursor solution to be uniformly and largely applied. Size of perovskite solar cell with PFN (Example 5) and perovskite solar cell without PFN (Comparative Example 5) in order to confirm excellence in terms of scalability and reproducibility of the perovskite solar cell. The data was measured by increasing.

As the perovskite solar cell, the solar cell of Example 5 showing the best performance was used, and the solar cell of Comparative Example 5 was used for comparison.

As shown in Figures 5a to 5f, the perovskite solar cell of Comparative Example 5 without a PFN layer was confirmed that the current-voltage is lowered as the device area is increased and the efficiency is reduced as well as the reproducibility is low. (Figures 5a and 5c). This tendency is due to insufficient surface coverage of the perovskite layer (upper line photo in FIG. 5D).

On the other hand, it was confirmed that the perovskite solar cell of Example 5 to which the PFN layer was applied exhibits an efficiency of 16% or more in an area of 1 cm ² (FIG. 5C). It was confirmed that even if the area of the solar cell increased, problems such as deterioration in performance did not occur and showed high reproducibility. In particular, even if the area was increased from 4 mm ² to 100 mm ² , almost 90% of the area device performance was preserved (FIGS. 5B and 5C). These results are evidence of the formation of a uniform perovskite layer, which means that the scalability and reproducibility of the perovskite solar cell can be improved (bottom photo in FIG. 5D).

In addition, the perovskite solar cell of Example 5 to which the PFN layer was applied obtained a uniform perovskite layer on a substrate having an area of 18.4 cm ² , based on which a total active area of 6 cm ² (1 cm ² x 6 pieces) Unit cell) to obtain a solar cell (FIG. 5E). All of the unit cells showed high performance without significant difference, and among them, the highest performance achieved 17%. This high efficiency is the highest in the field of printed large area perovskite solar cells manufactured without metal oxides requiring high-temperature heat treatment (FIG. 5F).

In addition, a perovskite solar cell having an area of 1 cm ² was fabricated by grafting the technology of the present invention using a poly-triarylamine (PTAA) material recently reported by a researcher Huang as an organic hole transport layer. Similar to the PTPD / PFN case, it was confirmed that the performance and reproducibility of the device were significantly improved in the case of PTAA / PFN compared to the simple PTAA.

The anti-solvent drop method used in forming the perovskite layer in the present invention is a method in which defects may occur in a radial gradient direction. Therefore, combining the technique of the present invention with a method of coating a new perovskite precursor solution may lead to better device expandability and reproducibility.

Test example  5. Stability test

Figure 6a is a graph measuring the power conversion efficiency (PCE) of the perovskite solar cell prepared according to the control group, Example 5 and Example 7, Figure 6b is a perovskite solar cell prepared according to the control group A graph showing the current-voltage curve, and FIG. 6C is a graph showing the current-voltage curve of the perovskite solar cell manufactured according to Example 5, and FIG. 6D is a perovskite solar manufactured according to Example 7 It is a graph showing the current-voltage curve of the battery.

In addition to the high efficiency, scalability and reproducibility in the present invention, another advantage is increased device life. In order to confirm this, the stability test was performed while the perovskite solar cells of the control group, Example 5 and Example 7 were stored in the air without external sealing.

As shown in Figures 6a to 6d, the control of the perovskite solar cells of the efficiency is rapidly reduced to deteriorate to 25% of the initial efficiency in one day. On the other hand, it was confirmed that the perovskite solar cells of Examples 5 and 7 showed more stable device driving and maintained more than half the initial performance even after 16 days of storage in the air (FIG. 6A).

In addition, the perovskite solar cells of the control group show a rapid decrease in the photocurrent as the exposure time in the atmosphere increases, which is predicted because the characteristics of the acidic and hygroscopic properties of PEDOT: PSS accelerate deterioration of the perovskite layer. . On the other hand, the perovskite solar cells of Examples 5 and 7 do not adversely affect the device life even if the exposure time passes in the air because of the very thin thickness, neutrality, and low hygroscopicity of PFN.

In particular, the perovskite solar cell of Example 7, in which a TiOx layer was introduced between the electron transport layer and the upper electrode, suppressed corrosion of the upper electrode by halogen ions movable from the perovskite layer, thereby allowing the perovskite of Example 5 It shows that the device life is extended longer than that of the sky solar cell and 80% of the initial device performance is maintained even after the life test (FIGS. 5A and 5D).

Test example  6. Example  8's and 9's Contact angle , Current-voltage curves and performance measurements

Figure 7a is a photo showing the contact angle of water on the hole transport layer / amphiphilic polymer prepared according to Examples 8 and 9, Figure 7b is a current-voltage curve of the perovskite solar cell prepared according to Examples 8 and 9 It is a graph showing.

As shown in FIG. 7A, the contact angle of water on the hole transport layer / PFN prepared according to Example 8 was confirmed to be similar to those of Examples 1 to 7, but the water on the hole transport layer / PFN prepared according to Example 9 It was confirmed that the contact angle was significantly lower than in Examples 1 to 7.

In addition, as shown in Figure 7b, it was confirmed that the perovskite solar cells prepared according to Examples 8 and 9 exhibit excellent current-voltage curves.

In addition, the optical parameters of the perovskite solar cells of Examples 8 to 9 are shown in Table 2 below.

division J _sc (mAcm ^-2 ) V _oc (V) FF PCE (%) Control
(PEDOT: PSS) 16.60 0.84 0.76 10.60 Example 8
(PTPD / PEO) 20.05 1.09 0.78 17.21 Example 9
(PTPD / PVA) 20.31 1.10 0.79 17.75

As shown in Table 2 above, the perovskite solar cells prepared according to Examples 8 and 9 have higher short-circuit current density (J _sc ), open circuit voltage (V _oc ), charge rate (FF), and power compared to the control group. It was confirmed that the conversion efficiency (PCE) was shown.

Test example  7. Example  Lesson 10 Comparative example  7, Example  Lesson 11 Comparative example  8's Contact angle , Current-voltage curves and performance measurements

8A is a photograph showing the contact angle of water on the hole transport layer / affinity polymer prepared according to Example 10 and the contact angle of water on the hole transport layer prepared according to Comparative Example 7, FIG. It is a graph showing the current-voltage curve of a lobsky solar cell.

8A, it was confirmed that the contact angle of water on the hole transport layer / PFN prepared according to Example 10 was sharply lower than that of water on the hole transport layer prepared according to Comparative Example 7.

In addition, as shown in Figure 8b, it was confirmed that the perovskite solar cell prepared according to Example 10 exhibits an excellent current-voltage curve.

9A is a photograph showing the contact angle of water on the electron transport layer / affinity polymer prepared according to Example 11 and the contact angle of water on the electron transport layer prepared according to Comparative Example 8, and FIG. It is a graph showing the current-voltage curve of a lobsky solar cell.

As shown in Figure 9a, it was confirmed that the contact angle of water on the electron transport layer / PFN prepared according to Example 11 was sharply lower than that of water on the electron transport layer prepared according to Comparative Example 8.

In addition, as shown in Figure 9b, it was confirmed that the perovskite solar cell prepared according to Example 11 exhibits an excellent current-voltage curve.

In addition, the optical parameters of the perovskite solar cells of Examples 10 and 11 are shown in Table 3 below.

division J _sc (mAcm ^-2 ) V _oc (V) FF PCE (%) Control
(PEDOT: PSS) 16.60 0.84 0.76 10.60 Example 10
(PTAA / PFN) 21.37 1.09 0.80 18.36 Example 11
(PCBM / PFN) 20.40 1.10 0.78 17.72

As shown in Table 3 above, the perovskite solar cells prepared according to Examples 10 and 11 have a higher short-circuit current density (J _sc ), an open circuit voltage (V _oc ), a charge rate (FF), and power compared to a control group. It was confirmed that the conversion efficiency (PCE) was shown.

Test example  8. Example  12 and Example  13's Contact angle , Current-voltage curves and performance measurements

10A is a photograph showing a contact angle of water on an electron transport layer / metal oxide prepared according to Example 12, and FIG. 10B is a graph showing a current-voltage curve of a perovskite solar cell prepared according to Example 12.

10A, it was confirmed that the contact angle of water on the electron transport layer / TiOx prepared according to Example 12 was lower than that of Examples 1 to 6 using the amphiphilic polymer.

In addition, as shown in Figure 10b, it was confirmed that the perovskite solar cell prepared according to Example 12 exhibits an excellent current-voltage curve.

FIG. 11A is a photograph showing the contact angle of water on the electrotransport layer / metal oxide prepared according to Example 13, and FIG. 11B is a graph showing the current-voltage curve of the perovskite solar cell prepared according to Example 13.

11A, it was confirmed that the contact angle of water on the electrotransport layer / MoO 3 prepared according to Example 13 was lower than that of Examples 1 to 6 using the amphiphilic polymer.

In addition, as shown in Figure 11b, it was confirmed that the perovskite solar cell prepared according to Example 13 exhibits an excellent current-voltage curve.

In addition, the optical parameters of the perovskite solar cells of Examples 12 and 13 are shown in Table 4 below.

division J _sc (mAcm ^-2 ) V _oc (V) FF PCE (%) Control
(PEDOT: PSS) 16.60 0.84 0.76 10.60 Example 12
(PCBM / TiOx) 20.35 1.07 0.79 17.25 Example 13
(PTPD / MoO3) 21.72 1.07 0.78 18.11

As shown in Table 4 above, the perovskite solar cells prepared according to Examples 12 and 13 have a higher short-circuit current density (J _sc ), an open circuit voltage (V _oc ), a charge rate (FF), and power compared to a control group. It was confirmed that the conversion efficiency (PCE) was shown.

Claims (13)

A large area perovskite solar cell comprising first and second organic charge transport layers and a perovskite layer,
The first organic charge transport layer, an interlayer material layer including an amphiphilic polymer, a perovskite layer, and a second organic charge transport layer are formed in this order, and the first organic charge transport layer is the second organic charge by the interlayer material layer. It has higher surface energy than the transport layer,
The amphiphilic polymer is a hydrophobic skeleton and a hydrophilic functional group is combined, a large area perovskite solar cell characterized in that it is one member selected from the group consisting of compounds of [Formula 1] to [Formula 4];
[Formula 1]

[Formula 2]

[Formula 3]

[Formula 4]

In Formulas 1 to 4, R ₁ and R ₂ are hydrogen, a substituted or unsubstituted alkyl group having 1 to 10 carbon atoms, a substituted or unsubstituted allyl group having 1 to 60 carbon atoms,

Is selected from the group consisting of the same or independently of each other; * Indicates a binding site; R ₃ and R ₄ are selected from the group consisting of OH, SH, NH2 and COOH; A ₁ to A ₃ is N ^+, F ^- is selected from the group consisting of ^-, O; n is an integer from 1 to 100.
The compounds of Formulas 1 and 2, wherein A ₁ to A ₃ are ions, are present in the form of salts. delete delete delete According to claim 1, wherein the amphiphilic polymer is a large area perovskite solar cell, characterized in that one member selected from the group consisting of compounds of the following [Formula 5] to [Formula 7];
[Formula 5]

[Formula 6]

[Formula 7]

In formulas 5 to 7, n is an integer from 1 to 100. A large area perovskite solar cell comprising first and second organic charge transport layers and a perovskite layer,
The first organic charge transport layer, an interlayer material layer including a first metal oxide, a perovskite layer, and a second organic charge transport layer are formed in this order, and the first organic charge transport layer is the second organic layer by the interlayer material layer. Compared to the charge transport layer, it has a higher surface energy,
The first metal oxide is a titanium oxide (TiOx), molybdenum oxide (MoO3), zinc oxide (ZnO), vanadium oxide (VOx) and tungsten oxide (WO3) at least one member selected from the group consisting of Robe Skye Solar Cell. The large area perovskite solar cell according to claim 1 or 6, wherein the first organic charge transport layer and the second organic charge transport layer are organic electron transport layers or organic hole transport layers. The method of claim 1 or 6, wherein the first organic charge transport layer in contact with the interlayer material layer is poly (N, N-bis (4-butylphenyl) -N, N-bis (phenyl) benzidine [poly (N, N-bis (4-butylphenyl) -N, N-bis (phenyl) benzidine); PTPD], polythiophene derivative; P3HT, diketopyrrolopyrrole derivative; TT, poly (thieno [3,4-b] thiophene-alt-benzodithiophene derivative [poly (thieno [3,4-b] thiophene-alt-benzodithiophene) derivative; PTB7-Th], poly (phenylene vinylene) derivative [ poly (phenylene vinylene) derivative; MEH-PPV], polycarbazole derivative; PCDTBT, poly [bis (4-phenyl) (2,4,6-trimethylphenyl) amine [poly [bis (4-phenyl) ) (2,4,6-trimethylphenyl) amine; PTAA] and large area perovskite, characterized by at least one member selected from the group consisting of phenyl-C61-butyric acid methyl ester (PCBM) Skyt Solar Cell. According to claim 1, wherein the large area perovskite solar cell comprises a first electrode comprising a conductive transparent substrate;
A first organic charge transport layer formed on the first electrode;
An interlayer material layer formed on the first organic charge transport layer and including the amphiphilic polymer;
A perovskite layer formed on the interlayer material layer;
A second organic charge transport layer formed on the perovskite layer; And
A large area perovskite solar cell comprising a; second electrode formed on the second organic charge transport layer. The large area perovskite solar cell according to claim 9, wherein a second metal oxide layer is added between the second organic charge transport layer and the second electrode. The method of claim 10, wherein the second metal oxide layer is titanium oxide (TiOx), characterized in that it comprises at least one second metal oxide selected from the group consisting of molybdenum oxide (MoO3) and zinc oxide (ZnO). Area perovskite solar cells. The method of claim 6, wherein the large area perovskite solar cell comprises a first electrode comprising a conductive transparent substrate;
A first organic charge transport layer formed on the first electrode;
An interlayer material layer formed on the first organic charge transport layer and including the first metal oxide;
A perovskite layer formed on the interlayer material layer;
A second organic charge transport layer formed on the perovskite layer; And
A large area perovskite solar cell comprising a; second electrode formed on the second organic charge transport layer. The large area perovskite solar cell according to claim 12, wherein a second metal oxide layer is added between the second organic charge transport layer and the second electrode.

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