Process for producing low-toxicity fluorescent carbon point

A technology of fluorescent carbon dots and low toxicity, applied in the fields of chemistry and material science, can solve the problems of wide half-peak width of fluorescence spectrum, low fluorescence quantum yield, difficult separation of carbon dots, etc., and achieves low preparation cost, simple instrument and raw materials. Inexpensive effects from a wide range of sources

Inactive Publication Date: 2009-04-08
WUHAN UNIV
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  • Summary
  • Abstract
  • Description
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  • Application Information

AI Technical Summary

Problems solved by technology

The nitric acid oxidation method is time-consuming and the prepared carbon dots are not easy to separate, the fluorescence quantum yield is very low, and the half-peak width of the fluorescence spectrum is wide
The only

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0015] (1) Cut multiple strands of carbon fiber into 4-5cm length, fix one end on the spectral pure graphite electrode with sealing glue, and rinse with ultrapure water.

[0016] (2) Put the cleaned carbon fiber electrode into a platinum beaker containing about 1 mol of sodium dihydrogen phosphate solution with a pH of 4.5, using the platinum beaker electrode as the auxiliary electrode, and the saturated calomel electrode (SCE) as the reference The electrode was electrolytically oxidized at a constant potential of 2V relative to the saturated calomel electrode for 120 minutes.

[0017] (3) Rinse the oxidized carbon fiber electrode with ultrapure water, usually until the rinsed aqueous solution is colorless, and collect the rinsed aqueous solution.

[0018] (4) Combine the sodium dihydrogen phosphate solution in (2) and the aqueous solution in (3), and centrifuge at RCF 28000g for 0.5-1 hour. Collect the supernatant and remove the precipitate.

[0019] (5) Ultrafiltration of the co...

Embodiment 2

[0021] (1) The spectral pure graphite electrode is ultrasonically cleaned in absolute ethanol and ultrapure water in sequence, and dried by nitrogen;

[0022] (2) Put the cleaned spectral pure graphite electrode into a platinum beaker containing a 0.1mol / L disodium hydrogen phosphate solution with a pH of 10.2, using the platinum beaker electrode as the auxiliary electrode, and the saturated calomel electrode (SCE ) Is the reference electrode, electrolytic oxidation is constant potential at a positive 9V potential relative to the saturated calomel electrode for 60 minutes.

[0023] (3) Rinse the oxidized spectral pure graphite electrode with ultrapure water, usually until the aqueous solution after the rinsing is colorless, and collect the aqueous solution after the rinsing.

[0024] (4) Combine the disodium hydrogen phosphate solution in (2) and the aqueous solution in (3), and centrifuge at RCF 28000g for 0.5-1 hour. Collect the supernatant and remove the precipitate.

[0025] (...

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PUM

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Abstract

The invention provides a preparation method for a low-toxic fluorescence carbon point. The method comprises the steps as follows: a washed carbon electrode is added into an electrolyte liquid and oxidation is carried out on the carbon electrode by a constant potential electrolytic oxidation method at a more positive potential position; then the carbon electrode after being oxidized is washed by ultra-pure water; the water liquid after washing is collected; the electrolyte liquid and the water liquid after washing are combined and centrifugated for collecting supernatant and removing the deposits; finally the collected supernatant is filtered in sequence by ultrafilter pipes the retained molecular weights of which are respectively 30, 10 and 5kDa; the components with the retained molecular weights of 5-10kDa and less than 5kDa are collected, wherein, the component of the retained molecular weight of 5-10kDa is the carbon point which gives out yellow fluorescence; and the component less than 5kDa is the carbon point which gives out blue fluorescence. The method is simple and easy to carry; the material resources are broad and cheap; and the obtained carbon points do not have cytotoxicity and resist light bleaching.

Description

Technical field [0001] The invention relates to a method for preparing low-toxic fluorescent carbon dots, and belongs to the field of chemistry and material science. Background technique [0002] In recent years, fluorescent semiconductor quantum dots, due to their unique fluorescent properties (such as strong fluorescence intensity and wide excitation wavelength range, can achieve single-element excitation and multiple emission, the emission peak half-width is very narrow (about 20nm), emission wavelength is controllable, and light drift resistance Etc.) and has attracted much attention, and has been widely used in cell imaging, biological labeling, nucleic acid analysis and detection, protein analysis and detection, ion probes, etc. However, the fluorescent semiconductor quantum dots currently used are mainly composed of II B and VI A elements such as: CdSe@ZnS, CdTe, etc., Cd 2+ The existence of posed a potential threat to the environment. Although the quantum dots are not tox...

Claims

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Application Information

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IPC IPC(8): C09K11/65C25B1/00
Inventor 庞代文赵巧玲张志凌
Owner WUHAN UNIV
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