Modeling field structures for biosensor with systems of quantum dots

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Published: Nov 16, 2016
DOI: https://doi.org/10.20535/2312-1807.2016.21.2.69835
Keywords:
biomolecular compounds, biosensor, quantum dots, field structure, mobility, sensitivity

Main Article Content

Oksana Kutova
Oleksii Shuliak
Volodymyr Ivanovych Tymofeev
National technical university of Ukraine "Igor Sikorsky Kyiv polytechnic institute"
https://orcid.org/0000-0003-0515-1580

Abstract

This article has shown the features of biosensors modelling and field structure analysis results for a biosensor with embedded quantum dots creation. The estimation regarding sensitivity increasing of the biosensor by using the surface layer system with quantum dots was done.
Also, this paper has described the possibilities of using such biosensors for biomolecular compounds detecting (proteins, DNA) on the sensitive surface of the transistor in the area between drain and source.

Bibl. 15, Fig. 5.

Article Details

How to Cite
Kutova, O., Shuliak, O., & Tymofeev, V. I. (2016). Modeling field structures for biosensor with systems of quantum dots. Electronics and Communications, 21(2), 18–24. https://doi.org/10.20535/2312-1807.2016.21.2.69835
Issue
Vol. 21 No. 2 (2016)
Section
Vacuum, plasma and quantum electronics
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References

Gouvea, C. (2011). Biosensors for health, environment and biosecurity, P. 540.

Zhang, Q., Majumdar, H.S., Kaisti, M., Prabhu, A., Ivask, A., Österbacka, R., Rahman, A., Levon. K. (2015). Surface functionalization of ion-sensitive floating-gate field-effect transistors with organic elec-tronics. Vol. 62. No 4. Pp. 1291-1298.

Kaisti, M., Zhang, Q., Lehmusvuori, F., Rahman, A., Levon, K. (2015). An Ion-Sensitive Floating Gate FET Model: Operating Principles and Electrofluidic Gating. Vol. 62. No 8. Pp. 2628-2635.

Ajay, Narang R., Saxena, M., Gupta, M. (2015). Drain current model of a four-gate dielectric modulat-ed MOSFET for application as a biosensor Transactions On Electron Devices. Vol. 62. No 8. Pp. 2636-2644.

Popescu, D., Brändlein, M., Melzer K., Lugli, P. (2015). Modeling of electrolyte-gated organic thin-film transistors for sensing applications.Vol. 62. No 12. Pp. 4206-4212.

Kim, J-Y., Ahn, J-H., Choi, S-J., Im, M., Kim, S., Duart, J.P., Kim, C-H., Park, T.J., Lee, S.Y., Choi, Y-K. (2012). An underlap channel-embedded field-effect transistor for biosensor application in watery and dry environment. Vol. 11. No 2. Pp. 390-394.

Timofeyev, V. I., Faleeva, E. M. (2010). Model of heterotransistor with quantum dots. Vol. 13. No 2. Рp.186-188.

Timofeyev, V., Faleeva E. (2014). Relaxation processes analysis in heterotransistors with systems of quantum wells and quantum dots. Electronics and Nanotechnology: 34th International Scientific Con-ference (ELNANO). Pp. 115-118.

Timofeyev, V. I., Faleeva, E. M. (2014). Analysis of relaxation processes of momentum and energy in heterotransistors with systems of quantum dots. Electronics and Communications. No 6. Pp. 54-56. (Rus)

Dvurechensky, A. V., Yakimov, A. I. (2001). Heterostructures Ge/Si with quantum dots. Vol. 171. No 12. Pp. 1371–1373. DOI: http://dx.doi.org/10.3367/UFNr.0171.200112h.1371. (Rus)

Yakimov, A. I., Dvurechensky, A. V., Bloshkin, A. A., Nenashev, A. V. (2006). Binding of electron states in Ge/Si multilayer strained heterostructures with quantum dots type 2 Vol. 83. No 4. Pp. 189-194. (Rus)

Ryndin, Е. А., Konoplev, B. G. (2001). Submicron integrated circuits: an elementary framework and design. P. 147. (Rus)

Nelaev, V. V., Stempitsky, V. R. (2008). CAD basics in microelectronics. P. 221. (Rus)

Shmyryeva, A. N., Borisov, A. V., Maksimchuk, N. V. (2010). Electronic Sensors Built on Nanostruc-tured Cerium Oxide Films. Nanotechnologies in Russia. Vol. 5, No 5-6. Рp. 383-390.

Maksimchuk, N. V., Shmyryeva, A. N., Borisov, A. V. (2010). Properties and applications of nano-crystalline films of cerium oxide. No 5-6, Pp. 54-59. (Rus)