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A CNTFET-Based Nanowired Induction Two-Way Transducers

By Rostyslav Sklyar

Independent researcher

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Abstract

A complex of the induction magnetic field two-way nanotransducers of the different physical values for both the external and implantable interfaces in a wide range of arrays are summarized. Implementation of the nanowires allows reliable transducing of the biosignals' partials and bringing of carbon nanotubes into circuits leading to examination of the superconducting transition.

Novel sensors are based on the induction magnetic field principle, which causes their interaction with an ambient EM field. Mathematical description of both the signal and mediums defines space embracing of the relevant interfacing devices. As a result, a wide range of the nano-bio-transducers allow both delivering the variety of ionized biosignals and interface the bioEM signals with further stages of electronic systems. The space coverage and transducing values properties of the state-of-the-art magnetic interfaces are summarized, and directions for their future development are deduced.

Bio

was born October 1, 1964 in Kyiv, Ukraine. Married Nadiya, son Andrew is also married. education 1986- graduated Radiotechnic department of Lviv TU and was qualified as engineer-designertechnologist of radioapparatus; 1993- completed post-graduate study in the speciality "Information-Measuring Systems" from the Ukrainian NAS; work experience 1986-1995, 2003-2005- engineer, researcher at the Ukrainian NAS; R&D of the highly sensitive magnetic field sensors for outer-space application. since 1996- independent research scientist. The current research interests cover SuFET incorporation into highly sensitive sensors of electric current and nanoelectronics in the biosignals transduction area.

References

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Publications

[27] Sklyar R., "A CNTFET-Based Nanowired Induction Two-Way Transducers, ISRN Nanotechnology, 2012, Article ID 102783, doi: 10.5402/2012/102783; [25] Sklyar R., "Machine Perception Through Natural Intelligence ", Positioning, vol. 2, 2011, pp. 65-77, doi: 10.4236/pos.2011.22007; [24] Sklyar R., "The Method of Instant Amplification of the MCG&MEG Signals", in: Nanotech 2010 Vol. 3, Nanotechnology 2010: Bio Sensors, Instruments, Medical, Environment and Energy, Chapter 7: Nano Medical Sciences, CRC Press, ISBN: 978-1-4398-3415-2, pp. 467-470, www.nsti.org/procs/Nanotech2010v3/7/T40.615; [23] Sklyar R., "Reliable Living Being-Machine Double Interface for Smart Sensing": in "Smart System Integration and Reliability", B. Michel, K.-D. Lang (Eds.), ISBN 978-3-932434-77-8, Goldenbogenverlag, Dresden 2010, pp. 782 – 788; [22] Sklyar R., "Employing the Superconducting Properties of the Molecular Chain and OFET for the Precise Currents Transducing", The Plastic Electronics Conference & Exhibition 2010, Dresden, Germany, P-6-03#16; [21] Sklyar R., "The Transforming EM Head Coils: From Microscopy to Amplification", Proceedings of International Symposium on Flexible Electronics 2010 (ISFE'10), April 11-14, 2010, Palma de Mallorca, Spain (Poster Number 3); [20] Sklyar R., "Application of the Flexible Pickup Coils in Connection With OFETs for Distribution e-Textile Sensors in an Array", Proceedings of the Large-area, Organic & Printed Electronics Convention 2010 (LOPE-C 2010), ISBN 978-3-00-029955-1, pp. 227-232; [19] Sklyar R., "A Complex of the Electromagnetic Biosensors with a Nanowired Pickup", J. of Sensors, vol. 2009, Article ID 516850, 20 pages, 2009, www.hindawi.com/journals/js/2009/516850.html ; [18] Sklyar R., "Induction magnetic field biosensors: from the macro to nano dimensions", 1st Bio-Sensing Technology Conference, 10-12 Nov. 2009– Bristol, UK, Paper P2.3.13 (2 pages); [17] Sklyar R., "Direct Bio (Living Being) Sensors-to-Processing Unit Interface", in: Elsner, Peter (Ed.); Fraunhofer Alliance for Defense and Security Research VVS: Future security: 4th Security Research Conference Karlsruhe; September 2009: Congress Center Karlsruhe, Germany. Stuttgart: Fraunhofer IRB Verl., 2009, pp. 290-309; [16] Sklyar R., "Analytical Treatment of the Signal Propagation in an EM Transistor/ Memristor (EMTM)", Proceedings of the Second International Workshop on Nonlinear Dynamics and Synchronization (INDS'09), July 20–21, 2009, Klagenfurt, Austria, pp. 116-120; [15] Sklyar R., "An EM Transistor/Memristor (EMTM) Based Brain-Processor Interface, Frontiers Neuroscience Conference Abstract: Neuroinformatics 2009- Pilsen, Czech Republic, 6-8 Sep, 2009, doi: 10.3389/conf.neuro.11.2009.08.052; [14] Sklyar R., "Pierced Sensor for Nano-Microscope (NMSC)", in: Nanotech 2009 vol. 1, Nanotechnology 2009: Fabrication, Particles, Characterization, MEMS, Electronics and Photonics, chapt. 7: Sensors and Systems, May 3-7, 2009, in Houston, Texas, U.S.A., pp. 546 -549, www.nsti.org/procs/Nanotech2009v1/7/T81.301 ; [13] Sklyar R., "An EM Transistor Based Brain-Processor Interface", in: Nanotech 2009 vol. 2, Nanotechnology 2009: Life Sciences, Medicine, Diagnostics, Bio Materials and Composites, chapt. 3: Nano Medicine, May 3-7, 2009, in Houston, Texas, U.S.A., pp. 131 -134, www.nsti.org/procs/Nanotech2009v2/3/T82.602 ; [12] Sklyar R., "Direct Processing of the MCG and MEG Signals" , An abstract book of 6th International Conference on Biomedical Applications of Nanotechnology, March 4-6, 2009— Charite, Berlin, Germany, p. 137; [11] Sklyar R., "CNT and Organic FETs Based Two-Way Transducing of the Neurosignals", in: Nanotech 2008 vol. 2, Nanotechnology 2008: Life Sciences, Medicine, and Bio Materials, Nano Science & Technology Institute, Cambridge, MA, USA, CRC Press, vol. 2, chapt. 6: Nano Medicine & Neurology, pp. 475-478, www.nsti.org/procs/Nanotech2008v2/6/M81.404 ; [10] Sklyar R., "Two-way Interface for Directing the Biological Signals", European Cells and Materials, vol. 14, suppl. 3, 2007, page 37, www.ecmjournal.org/journal/supplements/vol014supp03/pdf/v014supp03a037.pdf ; [9] Sklyar R., "A SuFET Based Sensor for Nano-Microscope", Journal of Automation, Mobile Robotics and Intelligent Systems (JAMRIS), 2007, vol. 1, no. 3, pp. 3-20, http://www.jamris.org/03_2007/03.jpg; [8] Sklyar R., "The Microfluidic Sensors of Liquids, Gases,and Tissues", Journal of Automation, Mobile Robotics and Intelligent Systems (JAMRIS), 2007, vol. 1, no. 2, pp. 20-34, http://www.jamris.org/02_2007/20.jpg ; [7] Sklyar R., "From Nanosensors to the Artificial Nerves and Neurons // Role of the nanosensors in interaction between the health and environment", EuroNanoForum 2007: Nanotechnology in Industrial Applications, June 19-21, 2007, CCD Düsseldorf, Germany, pp. 166-168/302-303; [6] Sklyar R., "Sensors with a Bioelectronic Connection", IEEE Sensors Journal (Special Issue), vol. 7, iss. 5, 2007, pp. 835-841; [5] Sklyar R., "Superconducting Induction Magnetometer", IEEE Sensors Journal, vol. 6, iss. 2, 2006, pp. 357- 364; [4] Sklyar R., "Suppression of Low-Frequency Interferences in the Induction Sensor of Magnetic Field", Measurement, vol.39, 2006, pp. 634-642; [26] Sklyar R., "Non-Contact Passive Flowmeters of Liquids and Gaseous or Friable Substances" (paper&poster), Flomeko 2005: 13th International Flow Measurement Conference, pp. 1-8; [3] Sklyar R., "Induction Magnetic Field Transducers Stability Limits", IEEE Sensors Journal, vol. 5, iss. 5, 2005, pages: 924- 928; [2] Sklyar R., "Superconducting Organic and CNT FETs as a Biochemical Transducer", ISMCR 2004: 14th International Symposium on Measurement and Control in Robotics, 16-18 September 2004 – NASA Johnson Space Center, Houston, Texas, IEEE (ISMCR), section 24 (II), (13 pages); [1] Sklyar R., "A SuFET Based Either Implantable or Non-Invasive (Bio)Transducer of Nerve Impulses", Measurement and Control in Robotics, M. A. Armada, P. Gonzales de Santos, and S. Tachi (Eds.), Producción Gráfica Multimedia, PGM, Madrid, Spain, 2003, ISBN: 84-607-9693-0, pp. 121-126.

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Researchers should cite this work as follows:

  • ISRN Nanotechnology, 2012, Article ID 102783, doi: 10.5402/2012/102783

  • Rostyslav Sklyar (2012), "A CNTFET-Based Nanowired Induction Two-Way Transducers," http://nanohub.org/resources/15135.

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