T. S. Kondratenko scite author profile

The mechanism features of colloidal quantum dots (QDs) passivation with thioglycolic acid molecules (TGA) for cases of different luminescent properties is considered using FTIR. This problem is considered based on FTIR spectra analysis for various ionic forms of TGA. Experimental TGA molecules FTIR spectra is interpreted, basing on the data on modeling of TGA vibrational modes, realized in the framework of density functional method (DFT /B3LYP/6-31+G(d)) taking into account the vibrations anharmonicity of every functional group. This approach provides a significant improvement in the agreement between the experimental and calculated data. FTIR spectra of Ag 2 S/TGA QDs with exciton and recombination luminescence are differ from each other and B “freeB” TGA molecules. The ν ( S − H ) TGA peak (2559 cm − 1 ) disappears in FTIR spectra of Ag 2 S/TGA QD samples. This fact indicates the interactions between TGA thiol group and dangling bonds of Ag 2 S nanocrystals. Ag 2 S QDs passivation with TGA molecules leads to emergence ν a s (COO − ) (1584 cm − 1 ) and ν s (COO − ) (1387 cm − 1 ) peaks. It indicates TGA adsorption in ionic form. For Ag 2 S/TGA QDs with exciton luminescence we observed (a) significant low-frequency shift of ν s (COO − ) peak from 1388 cm − 1 to 1359 cm − 1 and high-frequency shift of ν a s (COO − ) peak from 1567 cm − 1 to 1581 cm − 1 ; (b) change in the ratio of intensities of ν a s (COO − ) and ν s (COO − ) vibrations. This feature is caused by the change in the symmetry of TGA molecules due to passivation of Ag 2 S quantum dots.For Ag 2 S/TGA QDs with recombination luminescence, the insignificant high-frequency shift of 7–10 cm − 1 for ν a s (COO − ) at 1567 cm − 1 and low-frequency shift of 3–5 cm − 1 for ν s (COO − ) at 1388 cm − 1 , probably caused by the interaction of thiol with Ag 2 S surface is observed. Using FTIR spectra, it was found that IR luminescence photodegradation is also accompanied by changes in the thioglycolic acid molecules, which capped Ag 2 S QDs. In the case of Ag 2 S QDs with exciton luminescence, the degradation process is non-reversible. It is accompanied by TGA photodegradation with the formation of α -thiol-substituted acyl radical (S-CH 2 -CO • ) TGA.

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Effect of thioglycolic acid molecules on luminescence properties of $$\hbox {Ag}_2$$S quantum dots

Ovchinnikov

Grevtseva

Kondratenko

et al. 2020

Opt Quant Electron

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Reverse photodegradation of infrared luminescence of colloidal Ag2S quantum dots

Ovchinnikov

Grevtseva

Kondratenko

2019

Journal of Luminescence

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Structural and optical properties of Ag2S/SiO2 core/shell quantum dots

Perepelitsa

Ovchinnikov

Kondratenko

et al. 2021

Journal of Luminescence

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Sensitization of photoprocesses in colloidal Ag 2 S quantum dots by dye molecules

et al. 2016

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Luminescence and nonlinear optical properties of colloidal Ag2S quantum dots

Kondratenko

Zvyagin

Grevtseva

et al. 2019

Journal of Luminescence

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Colloidal Ag₂S/SiO₂ core/shell quantum dots with IR luminescence

Ovchinnikov¹,

Aslanov²,

Perepelitsa³

et al. 2020

Opt. Mater. Express

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This paper presents the results of studies of the luminescent properties for colloidal Ag2S quantum dots, coated with SiO2 shell, carried out by techniques of transmission electron microscopy, optical absorption and luminescence spectroscopy time correlated single photon counting, quantum yield of luminescence. Various approaches to the formation of SiO2 shell is analyzed. It is concluded that an increase in the quantum yield of Ag2S QDs luminescence in the condition of the formation of a SiO2 shell on the interfaces provides the passivation of dangling bonds and localization of charge carriers in the nucleus. It is shown that, under the considered conditions for the synthesis of Ag2S/SiO2 core/shell structures in ethylene glycol, the use of TEOS as a precursor for SiO2 shell provides the formation of a less defective shell, leading to an increase in the quantum yield of luminescence from 1.6% to 8%. On the contrary, the use of sodium metasilicate and high concentrations of MPTMS does not ensure the formation of a dense SiO2 shell of several monolayers thickness on Ag2S interfaces, coated with 2-mercaptopropionic acid.

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T. S. Kondratenko

Manifestation of intermolecular interactions in FTIR spectra of methylene blue molecules

Thioglycolic Acid FTIR Spectra on Ag2S Quantum Dots Interfaces

Effect of thioglycolic acid molecules on luminescence properties of $$\hbox {Ag}_2$$S quantum dots

Reverse photodegradation of infrared luminescence of colloidal Ag2S quantum dots

Structural and optical properties of Ag2S/SiO2 core/shell quantum dots

Sensitization of photoprocesses in colloidal Ag 2 S quantum dots by dye molecules

Luminescence and nonlinear optical properties of colloidal Ag2S quantum dots

Colloidal Ag₂S/SiO₂ core/shell quantum dots with IR luminescence

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T. S. Kondratenko

Manifestation of intermolecular interactions in FTIR spectra of methylene blue molecules

Thioglycolic Acid FTIR Spectra on Ag2S Quantum Dots Interfaces

Effect of thioglycolic acid molecules on luminescence properties of $$\hbox {Ag}_2$$S quantum dots

Reverse photodegradation of infrared luminescence of colloidal Ag2S quantum dots

Structural and optical properties of Ag2S/SiO2 core/shell quantum dots

Sensitization of photoprocesses in colloidal Ag 2 S quantum dots by dye molecules

Luminescence and nonlinear optical properties of colloidal Ag2S quantum dots

Colloidal Ag2S/SiO2 core/shell quantum dots with IR luminescence

Contact Info

Product

Resources

About

Colloidal Ag₂S/SiO₂ core/shell quantum dots with IR luminescence