Self-arranging molecules could form the basis for efficient optoelectronic memory devices

Self-arranging molecules could form the basis for efficient optoelectronic memory devices
Figure 1: Scanning tunneling microscopy image (background) of the ordered array of diarylethene derivative molecules. A schematic of the molecular structure is shown in the foreground. Credit: Reproduced, with permission, from ref. 1 © 2014 Wiley

A way to use weak molecular bonding interactions to create well-ordered and stable metal–organic monolayers with optoelectronic properties has been found by researchers from the RIKEN Surface and Interface Science Laboratory. The development could form the basis for the scalable fabrication of molecular optoelectronic devices.

A variety of emerging technologies are being investigated as potential replacements or enhancements of the electrical-charge-based electronics that lie at the heart of all electronic devices. Utilizing interactions between light and charge—referred to as optoelectronics—is of particular interest to researchers and engineers. Organic molecules that change state reversibly in response to pulses of light could, for example, be used to build versatile optoelectronic memory devices with ultrahigh storage capacities.

For individual organic molecules to be used as single digital 'bits' in such devices, the molecules need to be arranged into highly ordered, single-molecule layers, bonded to a . However, as bonding to a metal surface also affects optical properties, preparing ordered arrays of organic molecules with the desired optoelectronic characteristics has proved challenging.

The RIKEN team, led by Tomoko Shimizu and Yousoo Kim, developed a scheme for laying ordered monolayers of diarylethene derivatives on a copper substrate. Diarylethenes have well-established photochromic properties, undergoing reversible color changes when irradiated with light. Crucially, the diarylethene derivative used by Shimizu and Kim's team has an electric dipole, meaning that the distribution of electric charge in the molecule causes one end to be slightly negative and the other to be slightly positive.

When the diarylethene derivatives are deposited onto a copper surface in the presence of sodium ions, the interaction between the ions and organic molecules results in self-organization of the molecules into a precisely ordered array in which the diarylethene derivative molecules are lined up in neat, tightly packed rows (Fig. 1).

Application of a chemical 'annealing' process promotes a further subtle rearrangement of each molecule into a more stable configuration on the metal surface that reinforces the conductive 'on' state. The use of a copper substrate with a particular crystal arrangement, known as Cu(111), also facilitates precise arrangement of the .

"With homogeneous and close placing of individual molecules on a solid surface, we might be able to develop a memory device with several hundred to a thousand times the density achievable using current technology," says Shimizu. "We now want to study ways to achieve on–off switching of individual molecules in the superstructure in a controlled manner."


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More information: Shimizu, T. K., Jung, J., Imada, H. & Kim, Y. "Supramolecular assembly through interactions between molecular dipoles and alkali metal ions." Angewandte Chemie International Edition 53, 13729–13733 (2014). DOI: 10.1002/anie.201407555
Provided by RIKEN
Citation: Self-arranging molecules could form the basis for efficient optoelectronic memory devices (2014, December 12) retrieved 25 May 2019 from https://phys.org/news/2014-12-self-arranging-molecules-basis-efficient-optoelectronic.html
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Dec 12, 2014
> We now want to study ways to achieve on–off switching of individual molecules in the superstructure in a controlled manner.

Until then, it's hard to get excited about this work.

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