University of Hamburg, Institute for Applied Physics, Jungiusstrasse 11a, 20355 Hamburg, Germany.
Phys Rev Lett. 2016 Feb 19;116(7):077202. doi: 10.1103/PhysRevLett.116.077202. Epub 2016 Feb 17.
Dirac strings in spin ices are lines of reversed dipoles joining two quasiparticle excitations. These excitations behave as unbound emergent monopoles if the tension of Dirac strings vanishes. In this Letter, analytical and numerical analysis are used to study the dynamics of two-dimensional dipolar spin ices, artificially created analogs of bulk spin ice, in the regime of bound monopoles. It is shown that, in this regime, strings, rather than monopoles, are effective degrees of freedom explaining the finite-width band of Pauling states. A measurable prediction of path-time dependence of endpoints of a stretched and, then, released Dirac string is made and verified via simulations. It is shown that string dynamics is defined by the characteristic tension-to-mass ratio, which is determined by the fine structure constant and lattice dependent parameter. It is proposed to use string tension to achieve spontaneous magnetic currents. A concept of an energy storing device on the basis of this principle is proposed and illustrated by an experimental demonstration. A scheme of independent measurement at the nanoscale is proposed.
狄拉克弦是连接两个准粒子激发的反磁化强度线。如果狄拉克弦的张力为零,这些激发就会表现为非束缚的单极子。在这封信中,我们使用分析和数值分析来研究二维偶极自旋冰的动力学,这是体自旋冰的人工模拟。结果表明,在这个系统中,弦而不是单极子,是解释泡林态有限带宽的有效自由度。通过模拟验证了拉伸然后释放的狄拉克弦的端点的路径时间依赖性的可测量预测。结果表明,弦动力学由特征张力与质量比定义,该比由精细结构常数和晶格相关参数决定。我们提出利用弦张力来实现自发磁流。基于这一原理,我们提出了一种储能装置的概念,并通过实验演示进行了说明。我们还提出了一种在纳米尺度上进行独立测量的方案。