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Vol.3 , No. 1, Publication Date: Feb. 17, 2017, Page: 1-6
![](https://www.facebook.com/dialog/feed?app_id=808315475849687&link=http://www.aascit.org/journal/archive2?journalId=970%26paperId=4572&redirect_uri=http://www.aascit.org/journal/archive2?journalId=970%26paperId=4572&display=popup&name=Silicon Nanomaterial Technologies for Detections of Viruses in the Environment&description=Our aim is a searching for specific electrical responses of silicon nanomaterials under loading of NEPO viruses of plant. We used mesoporous silicon and DG MOSFET nanotransistors on the basis of silicon nanowires with the modified surface for detecting of viruses nanoparticles less than 30 nm. Electronic properties of the studied viruses have been observed and discussed. Such researches could be a key for understanding physical properties of "living" matter (virus particles). This result can be useful for creating new biosensors for other similar viruses in the environment.&picture=http://www.aascit.org/aascit/decorators/img/journal/970.jpg)
| [1] | Yuriy Vashpanov, Department of Automation of Production Processes and Robotics, Odessa National Academia of Food Technology, Odessa, Ukraine; Electrical and Computer Engineering Division of Hanyang Institute of Technology, Hanyang University, Seoul, South Korea. |
Our aim is a searching for specific electrical responses of silicon nanomaterials under loading of NEPO viruses of plant. We used mesoporous silicon and DG MOSFET nanotransistors on the basis of silicon nanowires with the modified surface for detecting of viruses nanoparticles less than 30 nm. Electronic properties of the studied viruses have been observed and discussed. Such researches could be a key for understanding physical properties of "living" matter (virus particles). This result can be useful for creating new biosensors for other similar viruses in the environment.
Keywords
Silicon, Semiconductor Nanotechnology, Biosensors, Viruses
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