Progress Report

Defect-Mediated Polarization Switching in Ferroelectrics and Related Materials: From Mesoscopic Mechanisms to Atomistic Control

  1. Sergei V. Kalinin1,*,
  2. Brian J. Rodriguez2,*,
  3. Albina Y. Borisevich1,*,
  4. Arthur P. Baddorf1,
  5. Nina Balke1,
  6. Hye Jung Chang1,
  7. Long-Qing Chen3,
  8. Samrat Choudhury3,
  9. Stephen Jesse1,
  10. Peter Maksymovych1,
  11. Maxim P. Nikiforov1,
  12. Stephen J. Pennycook1

Article first published online: 27 JUL 2009

DOI: 10.1002/adma.200900813

Issue

Advanced Materials

Advanced Materials

Volume 22, Issue 3, pages 314–322, January 19, 2010

Additional Information

How to Cite

Kalinin, S. V., Rodriguez, B. J., Borisevich, A. Y., Baddorf, A. P., Balke, N., Chang, H. J., Chen, L.-Q., Choudhury, S., Jesse, S., Maksymovych, P., Nikiforov, M. P. and Pennycook, S. J. (2010), Defect-Mediated Polarization Switching in Ferroelectrics and Related Materials: From Mesoscopic Mechanisms to Atomistic Control. Adv. Mater., 22: 314–322. doi: 10.1002/adma.200900813

Author Information

  1. 1

    Oak Ridge National Laboratory Oak Ridge, TN 37831 (USA)

  2. 2

    Conway Institute of Biomolecular and Biomedical Research University College Dublin Belfield, Dublin 4 (Ireland)

  3. 3

    Department of Materials Science and Engineering Pennsylvania State University University Park, PA 16802 (USA)

*Oak Ridge National Laboratory Oak Ridge, TN 37831 (USA).

Publication History

  1. Issue published online: 13 JAN 2010
  2. Article first published online: 27 JUL 2009

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Keywords:

  • defects;
  • ferroelectric materials;
  • polarization switching

Abstract

The plethora of lattice and electronic behaviors in ferroelectric and multiferroic materials and heterostructures opens vistas into novel physical phenomena including magnetoelectric coupling and ferroelectric tunneling. The development of new classes of electronic, energy-storage, and information-technology devices depends critically on understanding and controlling field-induced polarization switching. Polarization reversal is controlled by defects that determine activation energy, critical switching bias, and the selection between thermodynamically equivalent polarization states in multiaxial ferroelectrics. Understanding and controlling defect functionality in ferroelectric materials is as critical to the future of oxide electronics and solid-state electrochemistry as defects in semiconductors are for semiconductor electronics. Here, recent advances in understanding the defect-mediated switching mechanisms, enabled by recent advances in electron and scanning probe microscopy, are discussed. The synergy between local probes and structural methods offers a pathway to decipher deterministic polarization switching mechanisms on the level of a single atomically defined defect.

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