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Origin of the dielectric dead layer in nanoscale capacitors

Nature volume 443, pages 679682 (12 October 2006) | Download Citation

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Abstract

Capacitors are a mainstay of electronic integrated circuits and devices, where they perform essential functions such as storing electrical charge, and blocking direct current while allowing alternating currents to propagate. Because they are often the largest components in circuits, extensive efforts are directed at reducing their size through the use of high-permittivity insulators such as perovskite-structure SrTiO3 (refs 1, 2), which should provide more capacitance per unit area of device. Unfortunately, most experiments on thin-film SrTiO3 capacitors have yielded capacitance values that are orders of magnitude smaller than expected3. The microscopic origin of this reduced capacitance, which is often discussed in terms of a low-permittivity interfacial ‘dead layer’4, is not well understood. Whether such a dead layer exists at all, and if so, whether it is an intrinsic property of an ideal metal–insulator interface or a result of processing issues such as defects and strains, are controversial questions. Here we present fully ab initio calculations of the dielectric properties of realistic SrRuO3/SrTiO3/SrRuO3 nanocapacitors, and show that the observed dramatic capacitance reduction is indeed an intrinsic effect. We demonstrate the existence of a dielectric dead layer by calculating the dielectric profile across the interface and analyse its origin by extracting the ionic and electronic contributions to the electrostatic screening. We establish a correspondence between the dead layer and the hardening of the collective SrTiO3 zone-centre polar modes, and determine the influence of the electrode by repeating our calculations for Pt/SrTiO3/Pt capacitors. Our results provide practical guidelines for minimizing the deleterious effects of the dielectric dead layer in nanoscale devices.

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Acknowledgements

We thank A. De Vita, Ph. Ghosez, J. Junquera, R. Ramesh, R. Seshadri, J. F. Scott and S. Stemmer for discussions. This work was supported by the National Science Foundation's Division of Materials Research, through the Condensed Matter and Materials Theory Program; computations were performed on the DataStar machine at the San Diego Supercomputer Center.

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  1. Materials Department, University of California, Santa Barbara, California 93106-5050, USA

    • Massimiliano Stengel
    •  & Nicola A. Spaldin

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Reprints and permissions information is available at www.nature.com/reprints. The authors declare no competing financial interests.

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Correspondence to Massimiliano Stengel.

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https://doi.org/10.1038/nature05148

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