Hui-Ke Jin, Wilhelm Kadow, Michael Knap, Johannes Knolle
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引用次数: 0
Abstract
We study the effect of hole doping on the Kitaev spin liquid (KSL) and find that for ferromagnetic (FM) Kitaev exchange K the system is very susceptible to the formation of a FM spin polarization. Through density matrix renormalization group simulations on finite systems, we uncover that the introduction of a single hole, corresponding to ≈1% hole doping for the system size we consider, with a hopping strength of just t ~ 0.28K is enough to disrupt fractionalization and polarize the spins in the [001] direction due to an order-by-disorder mechanism. Taking into account a material relevant FM anisotropic exchange Γ drives the polarization towards the [111] direction via a transition into a topological FM state with chiral magnon excitations. We develop a parton mean-field theory incorporating fermionic holons and bosonic magnons, which accounts for the doping induced FM phases and topological magnon excitations. We discuss experimental implications for Kitaev candidate materials.
我们研究了空穴掺杂对基塔耶夫自旋液体(KSL)的影响,发现对于铁磁性(FM)基塔耶夫交换 K,该系统非常容易形成 FM 自旋极化。通过对有限系统进行密度矩阵重正化群模拟,我们发现,在我们所考虑的系统尺寸中,引入单个空穴(对应于≈1%的空穴掺杂),其跳跃强度仅为 t ~ 0.28K,就足以破坏分化,并由于逐阶失序机制而使自旋在 [001] 方向极化。考虑到与材料相关的调频各向异性交换Γ,通过过渡到具有手性磁子激发的拓扑调频态,将极化推向[111]方向。我们发展了一种包含费米子全子和玻色子磁子的粒子均场理论,它解释了掺杂诱导的调频态和拓扑磁子激发。我们讨论了基塔耶夫候选材料的实验意义。
期刊介绍:
npj Quantum Materials is an open access journal that publishes works that significantly advance the understanding of quantum materials, including their fundamental properties, fabrication and applications.
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