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.
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.
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ISRN Nanotechnology, 2012, Article ID 102783, doi: 10.5402/2012/102783
- carbon nanotubes
- ionic transport
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- magnetic field
- Nerve Impulse propagation