Detail publikačního výsledku

Graphene field-effect transistor sensor for detection of urea in water: Experimental study and DFT analysis

ŠPAČEK, O.; SUPALOVÁ, L.; MACH, J.; NEZVAL, D.; ŠIKOLA, T.; BARTOŠÍK, M.

Originální název

Graphene field-effect transistor sensor for detection of urea in water: Experimental study and DFT analysis

Anglický název

Graphene field-effect transistor sensor for detection of urea in water: Experimental study and DFT analysis

Druh

Článek WoS

Originální abstrakt

Urea sensors are used in medicine for disease monitoring, the automotive industry for emission control, agriculture and food safety for fertilizer and residue analysis, environmental monitoring for water pollution detection, and in industrial processes for production control. This article presents a pioneering experimental study of non-selective urea detection in aqueous solution using graphene doping in a field-effect transistor (FET) configuration. It is demonstrated that water itself p-dopes graphene, while the addition of urea weakens this effect (resulting in reduced p-doping). The response is explained by original density functional theory (DFT) calculations considering the common influence of water and urea. Analyses of charge redistributions and band structures indicate the formation of non-doping urea-water complexes responsible for the observed results. Moreover, the calculations provide deeper insight into the complex urea-water-graphene interactions, which may be utilized in other applications.

Anglický abstrakt

Urea sensors are used in medicine for disease monitoring, the automotive industry for emission control, agriculture and food safety for fertilizer and residue analysis, environmental monitoring for water pollution detection, and in industrial processes for production control. This article presents a pioneering experimental study of non-selective urea detection in aqueous solution using graphene doping in a field-effect transistor (FET) configuration. It is demonstrated that water itself p-dopes graphene, while the addition of urea weakens this effect (resulting in reduced p-doping). The response is explained by original density functional theory (DFT) calculations considering the common influence of water and urea. Analyses of charge redistributions and band structures indicate the formation of non-doping urea-water complexes responsible for the observed results. Moreover, the calculations provide deeper insight into the complex urea-water-graphene interactions, which may be utilized in other applications.

Klíčová slova

DFT, Graphene, Water, Urea, Sensor, FET, Charge transfer

Klíčová slova v angličtině

DFT, Graphene, Water, Urea, Sensor, FET, Charge transfer

Autoři

ŠPAČEK, O.; SUPALOVÁ, L.; MACH, J.; NEZVAL, D.; ŠIKOLA, T.; BARTOŠÍK, M.

Vydáno

01.04.2026

Nakladatel

Elsevier

Periodikum

Applied Surface Science Advances

Svazek

33

Číslo

April

Stát

Nizozemsko

Strany počet

8

URL

https://www.sciencedirect.com/science/article/pii/S2666523926000498?pes=vor&utm_source=clarivate&getft_integrator=clarivate

BibTex

@article{BUT201997,
  author="Ondřej {Špaček} and Linda {Supalová} and Jindřich {Mach} and David {Nezval} and Tomáš {Šikola} and Miroslav {Bartošík}",
  title="Graphene field-effect transistor sensor for detection of urea in water: Experimental study and DFT analysis",
  journal="Applied Surface Science Advances",
  year="2026",
  volume="33",
  number="April",
  pages="8",
  doi="10.1016/j.apsadv.2026.100978",
  issn="2666-5239",
  url="https://www.sciencedirect.com/science/article/pii/S2666523926000498?pes=vor&utm_source=clarivate&getft_integrator=clarivate"
}