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Method for measuring coverage rate of quantum dot surface ligand

A technology of surface ligand and measurement method, applied in the field of quantum dots, can solve the problems of poor uniformity of quantum dot solution, non-uniform photoelectric efficiency, non-uniform panel quality, etc., to avoid coffee ring effect, ensure solubility, and simple operation. Effect

Active Publication Date: 2019-06-25
TCL CORPORATION
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

If the surface coverage of the quantum dots is low, the solubility of the quantum dots is poor, the uniformity of the quantum dot solution is poor, and the drying rate of the quantum dot solution and the coffee ring effect affect the quality of the light-emitting layer film, which directly leads to the quality of the printed panel. Problems such as unevenness, low pixel resolution, turn-on voltage, uneven photoelectric efficiency, etc.

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0050] A method for measuring the coverage of ligands on the surface of quantum dots, comprising:

[0051] (1) Determine the average particle size d, and provide several sample particles, which include CdSe quantum dots and octylthiol ligands bound on the surface of the CdSe quantum dots. Dissolve the sample particles in n-hexane solution to prepare a 5 mg / ml solution. After the solution is completely dissolved, take a small amount of sample particle solution and drop 5 drops on the copper grid, and place the copper grid in a transmission electron microscope analyzer for testing and analysis . Set the accelerating voltage to 200kV, the emission current to 10μA, the working distance to 15 mm, and the dead time to 20%. For magnification analysis of the sample particles, first set the magnification to 70,000 times, take the area where the sample particles are concentrated and uniformly dispersed for focusing analysis, and take its TEM pictures. To analyze the TEM image, first s...

Embodiment 2

[0060] A method for measuring the ligand coverage of quantum dots, comprising:

[0061] (1) Determine the average particle size d, and provide several sample particles, which include CdSe quantum dots and octylthiol ligands bound on the surface of the CdSe quantum dots. Dissolve the sample particles in n-octane solution to prepare a 5 mg / ml solution. After the solution is completely dissolved, take a small amount of sample particle solution and drop 8 drops on the copper grid, and place the copper grid in a transmission electron microscope analyzer for testing For analysis, set the accelerating voltage to 300 kV, the emission current to 20 μA, the working distance to 20 mm, and the dead time to 30%. The sample particles are amplified and analyzed. First, the magnification is set to 100,000 times, and the area where the sample particles are concentrated and evenly dispersed is taken. Perform focus analysis and take its TEM pictures. To analyze the TEM image, first set the scal...

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PUM

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Abstract

The invention provides a method for measuring the coverage rate of a quantum dot surface ligand. The coverage rate Ki of the organic ligand containing sulfydryl on the quantum dot surface is determined by an oxidation-reduction method. The method can be used for quality evaluation of the quantum dot. If the Ki is less than 2*10<-10> mol / cm<2>, the quality of the quantum dot is poor; and solution or ink configuration can not be carried out until the Ki value is improved. With the provided method, the result is accurate; and the operation is simple. Furthermore, with the method, the high stability of the quantum dot surface ligand content is ensured; the solubility of different batches of quantum dots is guaranteed; a coffee ring effect caused by different drying rates in quantum dot solution preparation for a film is avoided; add the pixel resolution and uniformity of the brightening voltage and the photoelectric efficiency of the quantum dot display panel can be improved.

Description

technical field [0001] The invention relates to the technical field of quantum dots, in particular to a method for measuring ligand coverage on the surface of quantum dots. Background technique [0002] Quantum dots refer to semiconductor nanocrystals whose geometric size is smaller than their excitonic Bohr radius. Quantum dots have great potential applications in the fields of biomedicine, environmental energy, and lighting display due to their excellent optical properties such as absorption bandwidth, narrow fluorescence emission band, high quantum efficiency, and good photostability. The display technology based on quantum dot luminescence has been highly valued by the display industry in recent years. Compared with liquid crystal display and organic light-emitting display, quantum dot luminescence has a wider color gamut, higher color purity, simpler structure, and higher stability. It is considered It is a new generation display technology. [0003] The preparation t...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G01N21/31
CPCY02E10/549
Inventor 覃辉军叶炜浩杨一行
Owner TCL CORPORATION
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