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Mechanics of Individual, Isolated Vortices in a Cuprate Superconductor (0809.2817v1)

Published 16 Sep 2008 in cond-mat.supr-con and cond-mat.soft

Abstract: Superconductors often contain quantized microscopic whirlpools of electrons, called vortices, that can be modeled as one-dimensional elastic objects. Vortices are a diverse playground for condensed matter because of the interplay between thermal fluctuations, vortex-vortex interactions, and the interaction of the vortex core with the three-dimensional disorder landscape. While vortex matter has been studied extensively, the static and dynamic properties of an individual vortex have not. Here we employ magnetic force microscopy (MFM) to image and manipulate individual vortices in detwinned, single crystal YBa2Cu3O6.991 (YBCO), directly measuring the interaction of a moving vortex with the local disorder potential. We find an unexpected and dramatic enhancement of the response of a vortex to pulling when we wiggle it transversely. In addition, we find enhanced vortex pinning anisotropy that suggests clustering of oxygen vacancies in our sample and demonstrates the power of MFM to probe vortex structure and microscopic defects that cause pinning.

Citations (178)

Summary

Mechanics of Individual, Isolated Vortices in a Cuprate Superconductor

The paper investigates the static and dynamic properties of individual vortices in high-temperature superconductors, particularly focusing on the YBCO cuprate superconductor. Utilizing magnetic force microscopy (MFM), the paper offers considerable control over the imaging and manipulation of isolated vortices, distinguishing itself from prior research that tended to focus on vortex lattices. This technique provides new insights into vortex behavior, revealing surprising phenomena such as vortex wiggling and enhanced pinning anisotropy linked to oxygen vacancy clusters.

Through detailed analysis, the authors identified an unexpected enhancement in vortex response when a transverse alternation was introduced, facilitating greater displacement and an insightful observation of anisotropic pinning. The methodology proved invaluable for probing pinning defects spread throughout the bulk of the crystal, surpassing the limitations of other local-probe techniques that only assess surface-level interactions.

Key findings include:

  1. Vortex Wiggling: The application of a transverse force led to increased mobility of vortex segments, contrasting traditional pinned vortex behavior. This wiggling effect could have implications for applications in quantum computation and manipulation of vortex entanglement.
  2. Anisotropic Pinning: The paper observed a dependency on crystal orientation, noting more freedom along the b-axis than the a-axis. The anisotropic behavior suggests underlying clustering of oxygen vacancies in the sample, a detail that could be pivotal for understanding pinning landscapes in superconductors.
  3. Weak Collective Pinning (WCP) Model: The authors constructed a theoretical model based on WCP that accurately described quasistatic aspects of individual vortex motion. It accounted for the combined effects of elasticity and weak pinning sites distributed randomly, lending credence to the notion that vortices can be treated as elastic strings.

The paper also highlights the stochastic nature of vortex dynamics and raises questions about how these dynamics might alter the landscape of pinning forces. The potential applications of these findings extend into understanding vortex entanglement phenomena, which could be significant for advancements in superconducting technologies.

The implications of this research are manifold. Practically, the enhanced understanding of vortex dynamics at the single-vortex level provides a framework for developing refined manipulation techniques that transcend surface-level interrogation. Theoretically, the insights gained present opportunities for revising models of vortex behavior, particularly to incorporate anisotropic effects and dynamic interactions. As computational models evolve alongside experimental capabilities, future studies may build upon these discoveries to explore vortex behavior in various superconducting materials, ultimately contributing to the development of more efficient quantum systems and superconducting applications.