Electrode and preparation method thereof, and dye-sensitized solar cell containing same

A solar cell and dye sensitization technology, which is applied in the field of dye sensitized solar cells, can solve the problems of affecting the external output power of the cell, the large number of photogenerated electrons, and the increase in the transmission path, so as to reduce the internal resistance and increase the transfer capacity , the effect of increasing the output power

Inactive Publication Date: 2011-11-16
PEKING UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, the network structure electrode formed by sintering nanoparticles also has its problems: the number of photogenerated electrons generated on the side of the nanoparticle film close to the conductive substrate is often large, while the side close to the electrolyte is difficult to reach the light, and the adsorbed dyes are often unable to be absorbed by light. excited to generate electrons
The possible reason for this degradation is that when the area of ​​the battery increases, the resistance of the conductive film of the FTO conductive glass used as the battery substrate gradually increases, and consumes most of the photogenerated current, thereby affecting the external output power of the battery; On the other hand, when the cell area increases, the transmission path of a single photogenerated electron in the transparent conductive film also increases, thereby increasing the possibility of dark current (that is, the current in which the electrons in the conductive layer react with the electrolyte) to occur.

Method used

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  • Electrode and preparation method thereof, and dye-sensitized solar cell containing same
  • Electrode and preparation method thereof, and dye-sensitized solar cell containing same
  • Electrode and preparation method thereof, and dye-sensitized solar cell containing same

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0030] The transparent conductive substrate is made of FTO (F-doped tin oxide) conductive glass from Nippon Sheet Glass Company of Japan, and the substrate is placed in an ultrasonic water bath cleaning machine for cleaning and drying for the next step of the preparation process.

[0031] On TiO using the screen-printing method 2 Before film preparation, the TiO needed for the screen printing step needs to be formulated 2 Slurry (see the preparation process figure 1 ). 5 g TiO 2 The powder (manufactured by Degussa, Germany) was mixed with 1 ml of deionized water and 1 ml of glacial acetic acid and ground in a mortar for about 10 minutes. Slowly add 80 milliliters of ethanol to the mixture, grinding the mixture continuously while adding, and then continue grinding for about 10 minutes. This mixture was transferred to a beaker and stirred with a magnetic stirrer for about 1 hour. Add 15 ml of sesame oil to the beaker, and continue stirring with a magnetic stirrer for about ...

Embodiment 2

[0037] The transparent conductive substrate is made of FTO (F-doped tin oxide) conductive glass from Nippon Sheet Glass Company of Japan, and the substrate is placed in an ultrasonic water bath cleaning machine for cleaning and drying for the next step of the preparation process.

[0038] On TiO using the screen-printing method 2 Before film preparation, the TiO needed for the screen printing step needs to be formulated 2 Slurry, the process of concrete preparation is identical with embodiment 1.

[0039] Use Solaronix T / SP slurry (Solaronix SA Co., Switzerland) and self-made slurry for double-layer TiO 2 The preparation of the thin film, and then complete the preparation of the conductive metal grid, see image 3 .

[0040] first in ( image 3 301) FTO bilayer TiO on conductive glass substrates using screen printing method 2 Film preparation. The parameters of the screen are: mesh number 350, wire diameter 34 microns, pore diameter 39 microns, and opening ratio 28%. Th...

Embodiment 3

[0044] The transparent conductive substrate is made of FTO (F-doped tin oxide) conductive glass from Nippon Sheet Glass Company of Japan, and the substrate is placed in an ultrasonic water bath cleaning machine for cleaning and drying for the next step of the preparation process.

[0045] On TiO using the screen-printing method 2 Before film preparation, the TiO needed for the screen printing step needs to be formulated 2 Slurry, concrete preparation method is identical with embodiment 1.

[0046] Use Solaronix T / SP slurry (Solaronix SA Co., Switzerland) and self-made slurry for double-layer TiO 2 The preparation of the thin film, and then complete the preparation of the conductive metal grid, see image 3 .

[0047] Firstly, double-layer TiO was prepared on the FTO conductive glass substrate using the method of screen printing 2 Film preparation. The parameters of the screen are: mesh number 350, wire diameter 34 microns, pore diameter 39 microns, and opening ratio 28%. ...

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Abstract

The invention relates to an electrode which comprises a transparent conductive substrate, double-layer TiO2 nanoparticle films and metalgrid films, wherein the double-layer TiO2 nanoparticle films are covered on the conductive substrate in a blocky array way; the metal grid films are nested in the gaps among the blocky array of the double-layer TiO2 nanoparticle films; and the double-layer TiO2 nanoparticle film consists of a first-layer TiO2 nanoparticle film and a second-layer nanoparticle TiO2 film which are sequentially covered on the substrate. The invention also relates to a preparationmethod of the electrode and a dye-sensitized solar cell containing the electrode. The electrode of the dye-sensitized solar cell is beneficial to sufficiently absorbing light rays, can reduce the generation of dark currents and the current loss caused by the internal resistance of a transparent conductive film, and is suitable for preparing large-area dye-sensitized solar cells.

Description

technical field [0001] The invention relates to an electrode of a solar cell, in particular to an electrode of a dye-sensitized solar cell, a preparation method thereof and a dye-sensitized solar cell containing the electrode. Background technique [0002] French scientist Henri Becquerel first observed the phenomenon of photoelectric conversion in 1839, but it was not until the advent of the first practical semiconductor solar cell in 1954 that the idea of ​​"converting solar energy into electrical energy" really became a reality. There are many types of solar cells. If the material used is a narrow bandgap semiconductor material with certain absorption in the visible region, this type of solar cell is also called a semiconductor solar cell. Since the ability of the wide bandgap semiconductor itself to capture sunlight is very poor, if an appropriate dye is adsorbed on the surface of the semiconductor, with the help of the strong absorption of visible light by the dye, the...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H01G9/048H01G9/042H01M14/00H01L51/44H01L51/46H01L51/48H01G9/20H01L51/42
CPCY02E10/542Y02E60/13Y02E10/549
Inventor 康晋锋印海友张天舒王旭刘力锋王漪刘晓彦韩汝琦
Owner PEKING UNIV
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