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Method for improving performance of nanofiber membrane of dye-sensitized battery by synergistic action of carbon nanotubes and titanium tetrachloride

A technology of dye-sensitized cells and nanofiber membranes, applied in circuits, photovoltaic power generation, electrical components, etc., can solve the problems of reduced electronic life and diffusion distance, increased recombination probability, and restricted battery efficiency, so as to improve photocurrent density and short-circuit current Isc, increase the intensity, and improve the effect of photoresponse

Inactive Publication Date: 2012-06-13
ZHEJIANG SCI-TECH UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

This patented technology involves adding magnetic particles (MWDCNT's), such as iron oxide or manganoferrite, into titania for better electrical performance while maintaining high transparency at different wavelength ranges from UV rays through infrared waves. These added materials can enhance the photosensitive properties of the material by increasing their ability to absorb energy during sunlight exposure without losing effectiveness over longer periods of time due to reduced degradation caused by environmental conditions like temperature changes. Additionally, they are able to scatter evenly throughout the fibers themselves making them stronger than other types of semiconductors that have been previously used with this type of composition. Overall, this new method provides improved solar cell characteristics and increased power output compared to previous methods.

Problems solved by technology

This patent describes various technical solutions related to developing novel materials called quantum dots or nanosheets, specifically those containing metal atoms like gold, silver, cobalt, rhodamene, etc., capable of generating electrical current when exposed to sunlight. These quantum dents absorb incident visible rays and convert these lights into electricity through photosynthesis reactions. Quantum dyes provide promise because their ability to generate more efficient electronic signals makes them ideal candidates for use in applications involving low costs and improved environmental sustainability. Additionally, certain types of quantum dangers exist due to issues associated with particle boundary formation during fabrication processes, making them difficult to control and enhance device efficacy.

Method used

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  • Method for improving performance of nanofiber membrane of dye-sensitized battery by synergistic action of carbon nanotubes and titanium tetrachloride
  • Method for improving performance of nanofiber membrane of dye-sensitized battery by synergistic action of carbon nanotubes and titanium tetrachloride
  • Method for improving performance of nanofiber membrane of dye-sensitized battery by synergistic action of carbon nanotubes and titanium tetrachloride

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Experimental program
Comparison scheme
Effect test

Embodiment 1

[0025] 0.68g PVAc was added to 4ml DMF organic solvent to form a solution with a mass percentage of 15wt.%, and 1ml Triton X-100, 0.5ml HAc, and 1.36g TiP were added to the solution; magnetic stirring was carried out for 8 hours to obtain clarification, Viscous TiO 2 The precursor is spin-coated liquid, and it is spin-coated on the FTO conductive glass ultrasonically cleaned with acetone and absolute ethanol using a spin-coating machine to form a spin-coating layer. The spin-coating machine speed is 2000r·min -1 , Spin coating time is 30s.

[0026] 0.52g PVAc was added to 4ml DMF to form a solution with a mass percentage of 11.5wt.%, and 0.6ml Triton X-100, 0.4ml HAc, and 1.04g TiP were added to the solution. Subsequently, MWCNTs with a molar percentage of 0.1% TiP were also added to the DMF solution. Magnetic stirring for 8h to obtain TiO 2 Precursor spinning solution 1, and ultrasonic for 2h to ensure the uniform dispersion of MWCNTs in the solution; put the precursor spinning ...

Embodiment 2

[0029] 0.68g PVAc was added to 4ml DMF organic solvent to form a solution with a mass percentage of 15wt.%, and 1ml Triton X-100, 0.5ml HAc, and 1.36g TiP were added to the solution; magnetic stirring was carried out for 8 hours to obtain clarification, Viscous TiO 2 The precursor is spin-coated liquid, and it is spin-coated on the FTO conductive glass ultrasonically cleaned with acetone and absolute ethanol using a spin-coating machine to form a spin-coating layer. The spin-coating machine speed is 2000r·min -1 , Spin coating time is 30s.

[0030] 0.52g PVAc was added to 4ml DMF to form a solution with a mass percentage of 11.5wt.%, and 0.6ml Triton X-100, 0.4ml HAc, and 1.04g TiP were added to the solution. Subsequently, MWCNTs with a molar percentage of 0.5% TiP were also added to the DMF solution. Magnetic stirring for 8h to obtain TiO 2 Precursor spinning solution 1, and ultrasonic for 2h to ensure the uniform dispersion of MWCNTs in the solution; put the precursor spinning ...

Embodiment 3

[0033] 0.68g PVAc was added to 4ml DMF organic solvent to form a solution with a mass percentage of 15wt.%, and 1ml Triton X-100, 0.5ml HAc, and 1.36g TiP were added to the solution; magnetic stirring was carried out for 8 hours to obtain clarification, Viscous TiO 2 The precursor is spin-coated liquid, and it is spin-coated on the FTO conductive glass ultrasonically cleaned with acetone and absolute ethanol using a spin-coating machine to form a spin-coating layer. The spin-coating machine speed is 2000r·min -1 , Spin coating time is 30s.

[0034] 0.52g PVAc was added to 4ml DMF to form a solution with a mass percentage of 11.5wt.%, and 0.6ml Triton X-100, 0.4ml HAc, and 1.04g TiP were added to the solution. Subsequently, MWCNTs with a molar percentage of 1% TiP were also added to the DMF solution. Magnetic stirring for 8h to obtain TiO 2 Precursor spinning solution 1, and ultrasonic for 2h to ensure the uniform dispersion of MWCNTs in the solution; put the precursor spinning so...

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Abstract

The invention discloses a method for improving the performance of a nanofiber membrane of a dye-sensitized battery by synergistic action of carbon nanotubes and titanium tetrachloride. The method comprises the following steps of: 1) doping multi-wall carbon nanotubes in TiO2 precursor spinning solution; and 2) carrying out aftertreatment on a sintered TiO2 nanofiber membrane by using titanium tetrachloride solution. Due to addition of the multi-wall carbon nanotubes, the transmission capability of photoproduction electrons and the strength of the fiber membrane are improved. Due to treatment by the titanium tetrachloride, the absorbing quantity of the membrane for sensitized dyes is increased, the combination of the photoproduction electrons, the oxidation-state dyes and electrolyte is restrained, and the density of the electrons on a TiO2 conduction band is improved. Under the synergistic action of doping of the carbon nanotubes and treatment of the titanium tetrachloride, the performance of the TiO2 nanofiber membrane prepared on the basis of an electrostatic spinning technology is improved, and the total photoelectric conversion efficiency of the dye-sensitized solar battery is improved by 15%-23%.

Description

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Claims

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Application Information

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Owner ZHEJIANG SCI-TECH UNIV
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