The method of detection of biomolecules for the creation of sensors based on nano-structured Si.
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No. 64 (2019), Types of Forensic Examinations
No. 64 (2019)

The method of detection of biomolecules for the creation of sensors based on nano-structured Si.

Types of Forensic Examinations
https://doi.org/10.33994/kndise.2019.64.47
Published May 7, 2019
P. Teselko
Київський науково-дослідний інститут судових експертиз Міністерства юстиції України
V. Shevchenko
Київський національний університет імені Тараса Шевченка
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Keywords

photoluminescence
nanostructured porous silicon
biosensors

How to Cite

Teselko, P., & Shevchenko, V. (2019). The method of detection of biomolecules for the creation of sensors based on nano-structured Si. Criminalistics and Forensics, (64), 521 - 528. https://doi.org/10.33994/kndise.2019.64.47
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Abstract

In the work, the modification of photoluminescence spectra in the processing of porous silicon in aqueous solutions with different oxygen contents and aqueous solutions of amino acids was studied in order to further create a sensor sensitive to chemically active oxygen near the surface of porous silicon in the presence of various amino acids. he growth of the photoluminescence intensity at the processing of porous silicon in distilled water and the sensitivity of the intensity of photoluminescence to the oxygen content in water are revealed. It is proposed to use a change in the intensity of luminescence to study the properties of biomolecules, namely the determination of the amount of chemically active oxygen near the surface of porous silicon in the presence of various amino acids.

Changing the sizes of nanocrystals is the main reason for increasing the intensity of photoluminescence when processing porous silicon in aqueous solutions. After applying to the surface of samples of porous silicon aqueous solutions of glycine, alanine, phenylalanine, the intensity of photoluminescence varies for all samples. Changing the sizes of nanocrystals is the main reason for increasing the intensity of photoluminescence when processing porous silicon in aqueous solutions. After applying to the surface of samples of porous silicon aqueous solutions of glycine, alanine, phenylalanine, the intensity of photoluminescence varies for all samples.

https://doi.org/10.33994/kndise.2019.64.47
PDF (Українська)

References

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