Phase Transition near the Filling Factor ν = 3

IF 1.4 4区物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY

JETP Letters Pub Date : 2024-07-15 DOI:10.1134/S002136402460085X

A. V. Shchepetilnikov, G. A. Nikolaev, S. A. Andreeva, A. R. Khisameeva, Ya. V. Fedotova, A. A. Dremin, I. V. Kukushkin

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Abstract

A phase transition accompanied by the appearance of a spike in the longitudinal resistance of a two-dimensional electron system has been studied using the electron spin resonance near the filling factor ν = 3 in the ZnO/MgZnO heterojunction. This transition occurs when the tilt angle θ of the magnetic field is increased to some critical value θ_c. An analysis of the spin resonance amplitude has made it possible to demonstrate the spin nature of this phenomenon. For example, the ground state of the system on both sides of the transition has a nonzero spin polarization, which changes by several times when the phase of the system is changed. Strong spin resonance is observed both at θ < θ_c and at θ > θ_c. Surprisingly, the spin resonance at the critical angle θ_c has been detected in only one phase, which lies in the region of magnetic fields below the critical field B_c corresponding to the spike position in the longitudinal resistance. An increase in the magnetic field to this value leads to a decrease in the resonance amplitude and an increase in the resonance width. In the field region above B_c, the spin resonance disappears completely. Such behavior of the spin resonance is most likely due to the formation of domains with different spin polarizations in the electron system.

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填充因子 ν = 3 附近的相变

利用氧化锌/氧化镁异质结中填充因子ν = 3 附近的电子自旋共振，研究了伴随着二维电子系统纵向电阻尖峰出现的相变。当磁场的倾斜角θ增加到某个临界值θc时，就会发生这种转变。通过分析自旋共振幅度，可以证明这一现象的自旋性质。例如，过渡两侧的系统基态具有非零自旋极化，当系统的相位发生变化时，自旋极化会发生数倍的变化。在 θ < θc 和 θ > θc 处都能观察到强烈的自旋共振。令人惊讶的是，临界角 θc 处的自旋共振只在一个相位被检测到，该相位位于与纵向电阻中尖峰位置相对应的临界磁场 Bc 以下的磁场区域。磁场增加到这个值会导致共振幅度减小，共振宽度增加。在高于 Bc 的磁场区域，自旋共振完全消失。自旋共振的这种行为很可能是由于电子系统中形成了具有不同自旋极化的畴。

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来源期刊

JETP Letters 物理-物理：综合

CiteScore

2.40

自引率

30.80%

发文量

164

审稿时长

3-6 weeks

期刊介绍： All topics of experimental and theoretical physics including gravitation, field theory, elementary particles and nuclei, plasma, nonlinear phenomena, condensed matter, superconductivity, superfluidity, lasers, and surfaces.