Individual Variability and Average Reliability in Parallel Networks of Heterogeneous Biological and Artificial Nanostructures

We simulate the collective electrical response of heterogeneous ensembles of biological and artificial nanostructures whose individual threshold potentials show a significant variability. This problem is of current interest because nanotechnology is bound to produce nanostructures with a significant...

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Bibliographic Details
Published in:IEEE transactions on nanotechnology 2013-11, Vol.12 (6), p.1198-1205
Main Authors: Cervera, Javier, Claver, Jose M., Mafe, Salvador
Format: Article
Language:English
Subjects:
Applied sciences
Biologically inspired networks and diversity
Condensed matter: structure, mechanical and thermal properties
Cross-disciplinary physics: materials science
rheology
Electric potential
Electronics
Exact sciences and technology
information processing
ion channel
Logic gates
Low-dimensional structures (superlattices, quantum well structures, multilayers): structure, and nonelectronic properties
Materials science
Molecular electronics, nanoelectronics
Nanobioscience
Nanoparticles
Nanoscale materials and structures: fabrication and characterization
nanostructure variability
nanowire field-effect transistor (FET)
Noise
Other topics in nanoscale materials and structures
Physics
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
single electron transistor
Surfaces and interfaces
thin films and whiskers (structure and nonelectronic properties)
Transistors
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Summary:We simulate the collective electrical response of heterogeneous ensembles of biological and artificial nanostructures whose individual threshold potentials show a significant variability. This problem is of current interest because nanotechnology is bound to produce nanostructures with a significant experimental variability in their individual physical properties. This diversity is also present in biological systems that are however able to process information efficiently. The nanostructures considered are the ion channels of biological membranes, nanowire field-effect transistors, and metallic nanoparticle-based single electron transistors. These systems are simulated with canonical models that incorporate the basic threshold characteristics observed in the respective experimental current-voltage curves. In each case, the different shape, size, and charge distributions of the nanostructures result in statistical distributions for the individual threshold potentials, characterized by experimental average and width distribution values, rather than in identical replicates of the same unit. Despite the significant variability, the simulations suggest that useful average responses can still be achieved with summing networks of heterogeneous nanostructures because the collective behavior may compensate for individual failures and variability. Since threshold potential systems are commonplace in biology, the results obtained are also significant for understanding the role of diversity in biologically inspired networks.
ISSN:1536-125X
1941-0085
DOI:10.1109/TNANO.2013.2283871