We study the characteristics of the precessional switching induced by voltage control of magnetic anisotropy (VCMA) in back-end-of-line (BEOL)-compatible perpendicular magnetic tunnel junction devices. Using micromagnetic simulation, we find three operation regimes differentiated by zero excess energy, lower boundary, zero energy barrier, and upper boundary. Experimentally, the switching speed ( f s ) is characterized by two phases: non-precession and acceleration. Non-precession is a thermal mediated phase, where f s cannot be deduced, while in acceleration, both the higher electric field ( EF ) and in-plane field ( B x ) increase f s progressively. We find that the intrinsic thresholds can be retrieved by linear extrapolation of f s as a function of EF . Those thresholds and experimental results are in good agreement with the simulation. In addition, we numerically calculate the characteristic switching speed of 2γ * m z * B x and verify it experimentally. This work provides insights into the VCMA-induced precessional switching, including detailed understandings of the switching mechanism and modeling of switching speed for reliable write duration control for practical applications.
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机译:我们研究了磁各向异性(VCMA)的电压控制诱导的电压控制诱导的电压 - 封端(BEOL)呈现垂直磁隧道结装置。使用微磁模拟,我们发现三个操作制度以零超出能量,下边界,零能量屏障和上边界分化。实验地,开关速度(F S)的特征在于两个阶段:非进样和加速度。非动力是热介导的阶段,其中不能推导出F S,而在加速度中,较高的电场(EF)和面内场(B X)逐渐增加。我们发现可以通过F s的线性外推检索固有阈值作为EF的功能。这些阈值和实验结果与模拟吻合良好。此外,我们在数值上计算了2γ* M Z * B X的特征切换速度,并通过实验验证。这项工作提供了进入VCMA诱导的模型交换的见解,包括对切换机制的详细了解,用于对实际应用的可靠写入持续时间控制的开关机构和建模。
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