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Method for improving luminous thermal stability of manganese-doped perovskite quantum dots

A technology of quantum dot luminescence and thermal stability, which is applied in the direction of luminescent materials, chemical instruments and methods, electrical components, etc., to achieve the effects of inhibiting agglomeration and growth, improving the thermal stability of luminescence, and improving luminous efficiency

Inactive Publication Date: 2018-06-05
JILIN NORMAL UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

Unfortunately, there is no report on the effect of PDMS coating on the thermal stability of inorganic perovskite quantum dots.

Method used

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  • Method for improving luminous thermal stability of manganese-doped perovskite quantum dots
  • Method for improving luminous thermal stability of manganese-doped perovskite quantum dots
  • Method for improving luminous thermal stability of manganese-doped perovskite quantum dots

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0046] Example 1 Mn:CsPbCl 3 Preparation of quantum dot solution

[0047] Weigh 0.025g (2mmol) manganese chloride (MnCl 2 ), 0.054g (2mmol) lead chloride (PbCl 2 ) and 5mL octadecene (ODE) were added into a 50mL three-necked flask and mixed to obtain a mixed solution I;

[0048] Under an inert environment, add 1.5mL oleic acid (OA), 1.5mL oleylamine (OAm) and 1mL trioctylphosphine to the above mixed solution I to obtain mixed solution II;

[0049] The high-purity nitrogen atmosphere in the bottle was ensured by repeated vacuuming and nitrogen gas, and the temperature was raised from room temperature to 110°C for 30 minutes to remove the gas in the bottle, and then the temperature was raised to 190°C, and 0.3mL of cesium precursor (oleic acid cesium), keep it for 1min, cool down to room temperature quickly with an ice-water cooling bath to terminate the reaction, and finally centrifuge the reaction solution at 7000 revolutions per minute (rpm) for 5min, remove the supernatan...

Embodiment 2

[0053] Embodiment 2 PDMS injection amount is to Mn:CsPbCl 3 Effect of Quantum Dot Luminescence

[0054] Take sample B (Mn / Pb=2.5) in Example 1 and dissolve it in a cuvette containing 4mL of n-hexane to ensure that the exciton absorption of the quantum dots is about 0.05 (optical density), and put them in the quantum dot solution in turn Add 0, 40, 120, 200, 300 μL of PDMS solution (PDMS dissolved in n-hexane, 10 mg / mL) to obtain mixed solution III; respectively measure the absorption spectrum, luminescence spectrum, and exciton emission lifetime of mixed solution III at each concentration and Mn 2+ Luminous lifetime.

[0055] image 3 For the PDMS of the embodiment of the present invention 2 different amounts to Mn:CsPbCl 3 Effect of quantum dots on luminescence. Among them, Figures (a)(b)(c)(d) respectively represent injection into PDMS, Mn:CsPbCl 3 Quantum dot luminescence absorption, photoluminescence spectrum and exciton luminescence and Mn 2+ Luminous lifetime. i...

Embodiment 3

[0057] Get 0.2mL (25mg / mL) Mn in Example 1 2+ :CsPbCl 3 Quantum dot B sample was uniformly drop-coated on a silicon wafer cleaned by ultrasonic waves, and placed in a vacuum drying oven at 50°C for 30 minutes, and finally the sample was placed at room temperature to cool, and recorded as a pure quantum dot film sample ( QD).

[0058] Get 0.2mL (25mg / mL) Mn in Example 1 2+ :CsPbCl 3 Quantum dot B sample, add 0.25mL (200mg / mL) of PDMS solution, and the mixed solution is uniformly drip-coated on the silicon wafer that has been cleaned by ultrasonic waves, and placed in a vacuum drying oven at 50°C for 30min, and finally the sample is placed Cooled at room temperature, denoted as PDMS-coated Mn 2+ :CsPbCl 3 Quantum dot film samples (QD / PDMS).

[0059] The above two kinds of quantum dot films were respectively placed in Dewar flasks, evacuated for 30 minutes, and the corresponding luminescence spectra were measured at intervals of 20K in the temperature range of 293-393K (20-...

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Abstract

The invention provides a method for improving luminous thermal stability of manganese-doped perovskite quantum dots, belonging to the technical field of material preparation. The method comprises thefollowing steps: preparing a Mn:CsPbCl3 quantum dot solution; mixing the Mn:CsPbCl3 quantum dot solution and a PDMS solution to obtain a mixed solution III; dispensing the mixed solution III onto a silicon substrate to form a film, placing the film in a vacuum unit to perform continuous changed temperature heat treatment and conventional annealing heat treatment so as to obtain samples subjected to heat treatment, and performing luminous thermal stability test on the samples subjected to heat treatment; or, dispensing the obtained mixed solution III and Cu:ZnInS / ZnS quantum dots on a blue LEDchip, preparing a white LED device, drying, and performing luminous thermal stability test on the device. With the adoption of PDMS coating, luminescence quenching brought by ligand drop and size growth can be obviously reduced, and the luminous thermal stability of the quantum dots is improved.

Description

technical field [0001] The invention belongs to the technical field of material preparation, and in particular relates to a method for improving the luminous thermal stability of manganese-doped perovskite quantum dots. Background technique [0002] In the past two years, the all-inorganic CsPbX 3 (X is a halogen atom Cl, Br and I) perovskite quantum dots are rapidly gaining popularity due to their high quantum yield (>90%), narrow linewidth (15-30nm), adjustable absorption bandgap and emitted light wavelength. focus on. The potential application value in solar cells, light-emitting diodes, lasers, photodetectors, etc., makes the research of this kind of perovskite materials one of the frontiers in the international research field. [0003] Usually, in traditional II-VI and III-V semiconductor quantum dots, transition metal doping brings many novel optical, electrical, and magnetic properties. Among them, the most widely used method is to adjust the optical properties ...

Claims

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Application Information

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IPC IPC(8): C09K11/02C09K11/62C09K11/66H01L33/50
CPCC09K11/025C09K11/623C09K11/665H01L33/502
Inventor 赵家龙蔡冬袁曦李海波
Owner JILIN NORMAL UNIV
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