RU2793724C1 - Method for protecting perovskite-like materials from photodegradation - Google Patents

Abstract

FIELD: manufacturing.

SUBSTANCE: invention relates to methods for manufacturing devices on a solid body using organic materials as an active part, designed to perceive light radiation, and to methods for manufacturing photovoltaic devices with a light-absorbing layer based on perovskite-like materials. A method is proposed for protecting perovskite-like materials from photodegradation in a photovoltaic device with a light-absorbing layer based on them by thermal deposition in vacuum of a protective optical filter in the form of a layer of organic dye capable of sublimation and having intense absorption in the blue-green region of the visible range, by thermal deposition in vacuum on the side of the photovoltaic device that will face the light during operation.

EFFECT: increasing the retention period of the initial values of the main photoconversion parameters during continuous operation of photovoltaic devices with a light-absorbing layer based on perovskite-like materials with a minimum decrease in efficiency.

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Description

The invention relates to methods for manufacturing devices on a solid state using organic materials as an active part, designed to perceive light radiation, in particular to methods for manufacturing photovoltaic devices with a light-absorbing layer based on perovskite-like materials.

Photovoltaic devices with a light-absorbing layer based on perovskite-like materials have a high efficiency of 10-23% (see, for example, Jung J.W. High-performance semitransparent perovskite solar cells with 10% power conversion efficiency and 25% average visible transmittance based on transparent CuSCN as the hole -transporting material / J. W. Jung, C. C. Chueh, A. K.-Y. Jen // Advanced Energy Materials 2015. V. 5, 1500486. DOI: https://doi.org/10.1002/aenm.201500486; Jeong J. Pseudo- halide anion engineering for a-FAPbI3 perovskite solar cells / J. Jeong, M. Kim, J. Seo et al., Nature 2021 V 592 pp 381-385 https://doi.org/10.1038/ s41586-021-03406-5). In addition, the cost of components of perovskite-like materials (eg, methylammonium iodide, lead iodide) is significantly lower than the cost of components of photovoltaic devices with silicon-based light-absorbing layer. At the same time, perovskite-like materials are destroyed under the influence of air and moisture; therefore, photovoltaic devices based on them require mandatory encapsulation. However, perovskite-like materials also gradually decompose when irradiated with white light. It is known that photodegradation of perovskite-like materials results from the absorption of radiation at wavelengths from 500 to 540 nm (the blue-green component of the visible range of solar radiation). The retention period of the initial values of the main photoconversion parameters during continuous operation of photovoltaic devices with a light-absorbing layer based on perovskite-like materials without the use of protection against photodegradation is no more than 20 hours (see, for example, Travkin V. Multi-Analytical Study of Degradation Processesin Perovskite Films for Optoelectronic Applications / V. Travkin, G. Pakhomov, P. Yuninand M. Drozdov // Acta Physica Polonica. Ser. A. 2019. V. 135, No. 5. P. 1039-1041).

There is a known method of protecting solar cells by applying to the side of these photovoltaic devices oriented to the light source an array of plasmonic cruciform nanoantennas, which acts as an optical filter and, depending on the size and shape of the antennas, cuts off the radiation of a specific wavelength range (see Khoshdel V. UV and IR cut -off filters based on plasmonic crossed-shaped nano-antennas for solar cell applications / V. Khoshdel, M. Joodaki, M. Shokooh-Saremi // Opt. Commun. 2018. V. 433. P. 275-282). However, the use of such protection requires high-precision lithography technology with a resolution of less than 20 nm.

Also known is the method chosen as a prototype for protecting perovskite-like materials from radiation at wavelengths from 500 to 540 nm by applying an optical filter made of colored glass. So, for example, the use of a light filter PS11 (see GOST 9411-91) leads to complete protection of the perovskite layer from destruction under the action of sunlight. However, the excessive width of the absorption band of the radiation spectrum (160 nm, wavelength range from 500 to 660 nm) leads to significant losses in the efficiency of converting sunlight into electrical energy (by 1.8 times).

The task to be solved by the present invention is to create a technologically simple method of protection against photodegradation of perovskite-like materials used in photovoltaic devices as a light-absorbing layer, which makes it possible to increase the retention period of the initial values of the main parameters of photoconversion during continuous operation of photovoltaic devices with a light-absorbing layer based on perovskite-like materials at minimum reduction in efficiency.

A positive effect is achieved by the fact that immediately before the stage of encapsulation of the photovoltaic device with a light-absorbing layer based on perovskite-like materials, a protective optical filter is applied to the side of the photovoltaic device that will be facing the light during operation.

What is new is that a layer of an organic dye capable of sublimation and having intense absorption in the blue-green region of the visible range, applied by thermal deposition in vacuum, is used as a protective optical filter.

The method is illustrated in Fig. 1, which compares the spectra of PSI filters measured on the Genesis 50 Thermo Scientific instrument (dotted line) and a filter from a subporphyrazine dye of the phthalocyanine series C ₁₂ N ₁₂ S ₃ BCl (solid line).

In FIG. Table 2 shows the evolution under the influence of light of the main parameters of the photoelectric conversion of a photovoltaic device over time (top table) and a comparison of the main parameters of photovoltaic devices with a light-absorbing layer based on perovskite-like materials without a protective optical filter and with a filter used in the proposed method and in the prototype (bottom table). The data are given for a protective optical filter, which is a layer of subporphyrazine dye of the phthalocyanine series C ₁₂ N ₁₂ S ₃ BCl.

A possible embodiment of the method can be described using the example of a photovoltaic device with a light-absorbing layer based on perovskite-like materials. Such a device is usually a multilayer thin-film structure on a transparent substrate, and the structure consists of two electrodes, charge-transport layers and a light-absorbing layer, in which the radiation of the visible range of the solar spectrum is absorbed and the energy of such radiation is converted into electrical energy.

In the process of creating a device, both surfaces of the transparent substrate are first prepared. The cleaning protocol minimally includes mechanical cleaning, sonication in the presence of three organic solvents: heavy (DFMA), medium (acetone), light (isopropyl alcohol); then treatment with deionized water and drying in a stream of high purity argon. After that, a layered structure is deposited on a transparent substrate and, if necessary, its thermal annealing.

A method for protecting perovskite-like materials from photodegradation consists in the fact that before the encapsulation stage (that is, sealing and placing the photovoltaic device in a protective housing), first, by thermal deposition in a vacuum, an organic dye layer is applied, which has intense absorption in the blue-green region of the visible range, on the side of the photovoltaic device that will face the light during operation. As an organic dye with intense absorption in the blue-green region of the visible range, there can be, for example, a dye of the xanthene group Pyronin Y (absorbs in the wavelength range of 465-575 nm), a representative of fluorone dyes Rhodamine 6G (absorbs in the wavelength range of 465 -554 nm), subporphyrazine dye of the phthalocyanine series C ₁₂ N ₁₂ S ₃ BCl (absorbs in the wavelength range of 500-560 nm). All these organic dyes are sublimable, that is, suitable for deposition by thermal deposition in a vacuum, and, compared with the protective filter in the prototype, they have a much narrower absorption band in the visible region, which makes it possible to reduce the initial decrease in efficiency due to the use of a protective optical filter. .

To explain the proposed invention and compare the characteristics, a subporphyrazine dye of the phthalocyanine series C ₁₂ N ₁₂ S ₃ BCl, which has the narrowest absorption band, was used.

When applying a layer of C ₁₂ N ₁₂ S ₃ BCl on a photovoltaic device, the temperature of the crucible was 190°C, the distance to the surface to be coated was 15 cm, and the pressure was maintained at 8×10 ^-7 Torr.

In the case of a photovoltaic device, a layer of organic dye is applied either to a transparent substrate or to an upper transparent electrode.

The method of thermal deposition in vacuum is technologically simple, allows you to apply a layer of organic dye uniformly and evenly and at the same time control the layer thickness and prevent a layer thickness difference over the entire deposition area of more than 6 nm; for organic dye C ₁₂ N ₁₂ S ₃ BCl, the minimum layer thickness sufficient to completely protect the layer of perovskite-like material from photodegradation is 60 nm (These values were obtained at illumination of 120,000 lux, ZolixX150A sunlight simulator with an AM 1.5G filter). The minimum thickness of the applied layer, sufficient for complete protection against photodegradation of the perovskite-like material layer, for other organic dyes depends on their absorption (extinction) coefficient, but in any case is not more than 200 nm, which is much less than the thickness of the colored glass 2-5 mm used in the prototype. This makes it possible to reduce the overall weight of the produced photovoltaic device.

In FIG. Figure 1 compares the spectra of the PS11 filters and the C ₁₂ N ₁₂ S ₃ BCl filter measured on the Genesis 50 Thermo Scientific instrument, and also indicates the range of solar radiation wavelengths leading to the destruction of perovskite-like materials. It is obvious that, in comparison with the PSI filter, C ₁₂ N ₁₂ S ₃ BCl has a much narrower absorption spectrum. Moreover, it absorbs only wavelengths in the range of 500-560 nm, effectively cutting off radiation leading to photodestruction at a wavelength of 500-540 nm, while all other photons can reach the perovskite-like material layer, including photons in the blue and near ultraviolet range, which are in prototype method are absorbed.

In FIG. 2 in the upper table shows the evolution under the influence of light of the main photoconversion parameters of a photovoltaic device over time. The device was illuminated from the side of the substrate. It can be seen that the short-circuit current density of a photovoltaic device with a protective optical filter increases more slowly, but does not decrease, while without the use of a filter, it begins to decrease already by the sixth hour of use, which is an indicator of the destruction of the light-absorbing layer based on perovskite-like materials. In addition, at the initial moment of time, the efficiency increases both with and without a filter, because the light-absorbing layer based on perovskite-like materials undergoes morphological changes under the influence of radiation heating, but later in the device without a filter, the efficiency decreases due to photodestruction of the light-absorbing layer. Although the efficiency of a photovoltaic device with a protective optical filter is lower during the first five hours, it is higher at longer exposure times, and optical filtering becomes an operational advantage.

In FIG. 2 in the lower table compares the main parameters of photovoltaic devices with a light-absorbing layer based on perovskite-like materials without a protective optical filter and filters used in the proposed method and in the prototype.

Obviously, both in the proposed invention and in the prototype, it is possible to increase the retention period of the initial values of the main photoconversion parameters during continuous operation of photovoltaic devices with a light-absorbing layer based on perovskite-like materials by at least an order of magnitude, but due to the use of an organic dye layer as a protective optical filter with a narrower absorption spectrum than in colored glass, it becomes possible to reduce the initial decrease in efficiency due to the use of a protective optical filter by several times. At the same time, the method of applying an organic dye is technologically simple and can be easily integrated into the process of manufacturing photovoltaic devices.

Claims (1)

A method for protecting perovskite-like materials from photodegradation, in which immediately before the stage of encapsulation of a photovoltaic device with a light-absorbing layer based on perovskite-like materials, a protective optical filter is applied to the side of the photovoltaic device that will be facing the light during operation, characterized in that as a protective optical The filter uses a layer of organic dye capable of sublimation and having intense absorption in the blue-green region of the visible range, applied by thermal deposition in a vacuum.

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