Systematic Low-Energy Effective Field Theory for Electron-Doped Antiferromagnets
arXiv:cond-mat/0612363 · doi:10.1103/PhysRevB.75.214405
Abstract
In contrast to hole-doped systems which have hole pockets centered at $(\pm \fracÏ{2a},\pm \fracÏ{2a})$, in lightly electron-doped antiferromagnets the charged quasiparticles reside in momentum space pockets centered at $(\fracÏ{a},0)$ or $(0,\fracÏ{a})$. This has important consequences for the corresponding low-energy effective field theory of magnons and electrons which is constructed in this paper. In particular, in contrast to the hole-doped case, the magnon-mediated forces between two electrons depend on the total momentum $\vec P$ of the pair. For $\vec P = 0$ the one-magnon exchange potential between two electrons at distance $r$ is proportional to $1/r^4$, while in the hole case it has a $1/r^2$ dependence. The effective theory predicts that spiral phases are absent in electron-doped antiferromagnets.
25 pages, 7 figures