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Molecular electronics

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Title: Molecular electronics  
Author: World Heritage Encyclopedia
Language: English
Subject: Mark Ratner, Supramolecular electronics, Abraham Nitzan, Nanoelectronics, Conductive polymer
Collection: Conductive Polymers, Molecular Electronics, Nanoelectronics, Organic Polymers, Organic Semiconductors
Publisher: World Heritage Encyclopedia

Molecular electronics

Molecular electronics is the study and application of molecular building blocks for the fabrication of electronic components. It is an interdisciplinary area that spans physics, chemistry, and materials science. The unifying feature is the use of molecular building blocks for the fabrication of electronic components. Due to the prospect of size reduction in electronics offered by molecular-level control of properties, molecular electronics has generated much excitement . Molecular electronics provides a potential means to extend Moore's Law beyond the foreseen limits of small-scale conventional silicon integrated circuits.[1]


  • Molecular scale electronics 1
  • Molecular materials for electronics 2
  • See also 3
  • References 4
  • Further reading 5
  • External links 6

Molecular scale electronics

Molecular scale electronics, also called single molecule electronics, is a branch of nanotechnology that uses single molecules, or nanoscale collections of single molecules, as electronic components. Because single molecules constitute the smallest stable structures possible, this miniaturization is the ultimate goal for shrinking electrical circuits.

Conventional electronic devices are traditionally made from bulk materials. The bulk approach has inherent limitations in addition to becoming increasingly demanding and expensive. Thus, the idea was born that the components could instead be built up atom for atom in a chemistry lab (bottom up) as opposed to carving them out of bulk material (top down). In single molecule electronics, the bulk material is replaced by single molecules. That is, instead of creating structures by removing or applying material after a pattern scaffold, the atoms are put together in a chemistry lab. The molecules utilized have properties that resemble traditional electronic components such as a wire, transistor or rectifier.

Single molecule electronics is an emerging field, and entire electronic circuits consisting exclusively of molecular sized compounds are still very far from being realized. However, the continuous demand for more computing power together with the inherent limitations of the present day lithographic methods make the transition seem unavoidable. Currently, the focus is on discovering molecules with interesting properties and on finding ways to obtaining reliable and reproducible contacts between the molecular components and the bulk material of the electrodes.

Molecular electronics operates in the quantum realm of distances less than 100 nanometers. Miniaturization down to single molecules brings the scale down to a regime where quantum effects are important. As opposed to the case in conventional electronic components, where electrons can be filled in or drawn out more or less like a continuous flow of charge, the transfer of a single electron alters the system significantly. The significant amount of energy due to charging has to be taken into account when making calculations about the electronic properties of the setup and is highly sensitive to distances to conducting surfaces nearby.

Graphical representation of a rotaxane, useful as a molecular switch.

One of the biggest problems with measuring on single molecules is to establish reproducible electrical contact with only one molecule and doing so without shortcutting the electrodes. Because the current indium arsenide nanowires with an embedded segment of the wider bandgap material indium phosphide used as an electronic barrier to be bridged by molecules.[4]

One of the biggest hindrances for single molecule electronics to be commercially exploited is the lack of techniques to connect a molecular sized circuit to bulk electrodes in a way that gives reproducible results. Also problematic is the fact that some measurements on single molecules are carried out in cryogenic temperatures (close to absolute zero) which is very energy consuming.

Molecular materials for electronics

Chemical structures of some conductive polymers. From top left clockwise: polyacetylene; polyphenylene vinylene; polypyrrole (X = NH) and polythiophene (X = S); and polyaniline (X = NH/N) and polyphenylene sulfide (X = S).

The biggest advantage of conductive polymers is their processability, mainly by

  • Online lecture on Molecular Electronics and the Bottom-up View of Electronic Conduction by S. Datta
  • Online lecture on Molecular Electronics Pathway for Molecular Memory Devices by Ranganathan Shashidhar

External links

  • Heath, J. R. (2009). "Molecular Electronics". Annual Review of Materials Research 39: 1–0.  

Further reading

  1. ^ Petty, M.C.; Bryce, M.R. & Bloor, D. (1995). Introduction to Molecular Electronics. New York: Oxford University Press. pp. 1–25.  
  2. ^ Gimzewski, J.K.; Joachim, C. (1999). "Nanoscale science of single molecules using local probes". Science 283 (5408): 1683–1688.  
  3. ^ Sørensen, J.K.. (2006). “Synthesis of new components, functionalized with (60)fullerene, for molecular electronics”. 4th Annual meeting - CONT 2006, University of Copenhagen.
  4. ^ Schukfeh, Muhammed Ihab; Storm, Kristian; Mahmoud, Ahmad; Søndergaard, Roar R.; Szwajca, Anna; Hansen, Allan; Hinze, Peter; Weimann, Thomas; Fahlvik Svensson, Sofia; Bora, Achyut; Dick, Kimberly A.; Thelander, Claes; Krebs, Frederik C.; Lugli, Paolo; Samuelson, Lars; Tornow, Marc (2013). "Conductance Enhancement of InAs/InP Heterostructure Nanowires by Surface Functionalization with Oligo(phenylene vinylene)s". ACS Nano 7 (5): 4111–4118.  
  5. ^ a b c Herbert Naarmann “Polymers, Electrically Conducting” in Ullmann's Encyclopedia of Industrial Chemistry 2002 Wiley-VCH, Weinheim. doi:10.1002/14356007.a21_429
  6. ^ a b Handbook of Nanostructured Materials and Nanotechnology; Nalwa, H.S., Ed.; Academic Press: New York, NY, USA, 2000; Volume 5, pp. 501–575.
  7. ^ Skotheim, T., Elsenbaumer, R., Reynolds, J., Eds.; Handbook of Conducting Polymers, 2nd ed.; Marcel Dekker, Inc.: New York, NY, USA, 1998


See also

Due to their poor processability, conductive polymers enjoy few large-scale applications . They have some promise in antistatic materials[5] and they have been incorporated into commercial displays and batteries, but there have had limitations due to the manufacturing costs, material inconsistencies, toxicity, poor solubility in solvents, and inability to directly melt process. Nevertheless, conducting polymers are rapidly gaining attraction in new applications with increasingly processable materials with better electrical and physical properties and lower costs. With the availability of stable and reproducible dispersions, PEDOT and polyaniline have gained some large scale applications. While PEDOT (poly(3,4-ethylenedioxythiophene)) is mainly used in antistatic applications and as a transparent conductive layer in form of PEDOT:PSS dispersions (PSS=polystyrene sulfonic acid), polyaniline is widely used for printed circuit board manufacturing – in the final finish, for protecting copper from corrosion and preventing its solderability.[6] The new nanostructured forms of conducting polymers particularly, provide fresh air to this field with their higher surface area and better dispersability.

Conducting polymers have backbones of contiguous sp2 hybridized carbon centers. One valence electron on each center resides in a pz orbital, which is orthogonal to the other three sigma-bonds. The electrons in these delocalized orbitals have high mobility when the material is "doped" by oxidation, which removes some of these delocalized electrons. Thus the conjugated p-orbitals form a one-dimensional electronic band, and the electrons within this band become mobile when it is partially emptied. Despite intensive research, the relationship between morphology, chain structure and conductivity is poorly understood yet.[7]

The linear-backbone polymers such as solar cells and transistors.[5]

[6] and by advanced dispersion techniques.[5]

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