Rewritable Wires Could Mean No More Obsolete Circuitry

An electric field switches the conductivity on and off in atomic-scale channels, which could allow for upgrades at will.

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Rewritable Wires Could Mean No More Obsolete Circuitry

Working towards rewritable nanoscale wires, researchers controlled electrical conductivity in 2-D ferroelectric domain walls by applying a voltage (V). The domain walls behaved like an electric switch. The charges responsible for this behavior were localized to within a few atom widths (a nanometer) of the domain walls, the barriers between regions with different electronic properties, in erbium manganite. In the atomic-resolution electron microscopy image, the positive (red) and negative (blue) polarizations come together in the white region. This polarity mismatch forms a positively charged (head-to-head) domain wall. Applying a voltage added more charge carriers to the domain wall, switching the conductivity of the channel.

The Science

Updating, rather than replacing, outdated circuits in tiny sensors would reduce cost and waste. The unusual electronic properties of ferroelectric domain walls could be the answer. A domain wall is the interface between different types of electrical ordering. Applying a voltage to the domain wall can change the preferred electrical ordering, making the domain walls move. These walls can be made, moved, and erased on demand, making them promising for next-generation circuit elements. Advanced electron microscopy allowed scientists to see that electrons move to the wall to create one-nanometer channels. Applying a voltage reversibly switches the channel from insulating to conducting, which could be used as the 0’s and 1’s for binary switches in a computer.

The Impact

Rewriteable domain walls are a promising avenue for extremely small circuitry. Reversibly switching conductivity on and off with an electric field is a critical step towards using these walls in digital devices. These devices include switches, diodes, or field-effect transistors. 


Ferroelectric materials have spontaneous electrical ordering that can be changed by applying an electric field. Where two domains of different polarizations meet, it is called a ferroelectric domain wall. These domain walls are promising for next-generation circuit elements due to their unusual electronic properties and because they can be formed, moved, and erased on demand. At “charged” domain walls, the mismatch in polarization between the two domains forces a build-up of charge at the wall.

Scientists envision a transistor where the gate is a domain wall itself—and whether you can pass current through the domain wall is controlled by the charges in the domain wall. Now, scientists have found that they can reversibly switch domain walls between being resistive or conductive depending on the electric field they apply. Using atomic-resolution electron microscopy and spectroscopy, they found that the electrons that move to the wall were confined to just one to two repeating crystalline unit cells in erbium manganite (ErMnO3). When the polarizations of the two ferroelectric domains point at each other (head-to-head), there is nominally a buildup of positive charge at the domain wall. This positive charge was compensated by extra electrons that accumulated on the atoms within the domain wall. These electrons were stuck, shielding the local charges, and did not conduct. By applying an electric field, extra electrons flowed into the channel at the domain wall. When all the local charges were sufficiently shielded, the electrons in the channel were free to move within the domain wall, forming a 2-D conductive sheet. This conductive sheet could be used as a switch or transistor. The switch is “off” when current does not flow. Applying an electric field allows current to pass, turning the switch “on.” This paves the way towards developing all-domain-wall electrical devices.


David A. Muller
Cornell University


Electron microscopy and physical samples were supported by the U.S. Department of Energy (DOE), Office of Science, Office of Basic Energy Sciences. Synchrotron studies and theory were supported by ETH Zürich, the Swiss National Science Foundation, the Alexander von Humboldt Foundation, the European Research Council Advanced Grant program, and Helmholtz-Zentrum Berlin. This work made use of the electron microscopy facility of the Cornell Center for Materials Research supported by the National Science Foundation and the LeRoy Eyring Center for Solid State Science at Arizona State. Support for graduate and postdoctoral fellowships came from the Army Research Office and National Science Foundation. Density functional theory calculations were supported by Ministry of Economy and Competitiveness-Spain and Generalitat de Catalunya. X-ray photoemission electron microscopy studies were supported in part by DOE. M. Fiebig also provided direct financial support.


J.A. Mundy, J. Schaab, Y. Kumagai, A. Cano, M. Stengel, I.P. Krug, D.M. Gottlob, H. Doğanay, M.E. Holtz, R. Held, Z. Yan, E. Bourret, C.M. Schneider, D.G. Schlom, D.A. Muller, R. Ramesh, N.A. Spaldin, and D. Meier, “Functional electronic inversion layers at ferroelectric domain walls.External linkNature Materials 16, 622 (2017). [DOI: 10.1038/NMAT4878]

Related Links

Nanotechweb.org technology update: Switching domain-wall output in semiconducting ferroelectricsExternal link

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Last modified: 1/9/2018 3:50:21 PM