1) spin-polarized pendulum
自旋极化扭秤
1.
Survey of spin-mass interaction by spin-polarized pendulum;
用自旋极化扭秤探测自旋与质量相互作用
2) spin polarization
自旋极化
1.
Effect of spin polarization on electron recombination dynamics in bulk intrinsic GaAs;
本征GaAs中电子自旋极化对电子复合动力学的影响研究
2.
Current-induced spin polarization in spin-orbit coupling systems
自旋轨道耦合系统中的电流导致的自旋极化
3.
Relation between charge shot noise and spin polarization governed by Rashba spin orbit interaction
Rashba自旋轨道耦合作用下电荷流散粒噪声与自旋极化的关系研究
3) spin-polarization
自旋极化
1.
The results show that:(i) the spin-polarization of electron can not be produced in the anti-parallel magnetic barriers structure at zero bias voltage;(ii) the energy threshold of electronic transmission are increase with the increases of magnetic field or bias voltage;(iii) the comparison of the electron spin polarization degree is made between.
研究了双磁垒量子结构中,磁场强度和偏压大小对电子自旋极化输运的影响。
2.
By using scattering matrix method,the quantized conductance,spin-polarization,and magnetoresistance in multi-channel ferromagnetic nanowire are calculated.
利用散射矩阵理论,研究了多通道纳米线结构中的量子化电导、自旋极化和弹道磁电阻。
4) spin polarization
自旋极化率
1.
The main feature of half_metallic materials is its high spin polarization up to 100%.
半金属材料的一个重要特征为具有高达100%的传导电子自旋极化率。
2.
By using the coherent quantum transport theory and transfer matrix method,the transmission coefficient and spin polarization for polarized electrons with different spin orientations through ferromagnetic/semiconductor/ferromagnetic heterostructures have been investigated.
采用相干量子输运理论和传递矩阵方法,研究了具有不同自旋指向的极化电子渡越铁磁/半导体/铁磁异质结构的隧穿几率和自旋极化率。
5) Non-spin-polarized
非自旋极化
6) nuclear spin polarization
核自旋极化
1.
The technologies of nuclear spin polarization involve broad areas of atomic, molecular and optical physics.
核自旋极化的惰性气体原子在诸如核物理、材料科学和磁共振成像等许多领域中都有着广泛的应用,核自旋极化技术涉及领域很广,包括原子、分子和光学物理等等。
补充资料:自旋-自旋弛豫
自旋-自旋弛豫
磁共振成像术语。又称T2弛豫或横向弛豫(transverse relaxation),指垂直于外磁场B0方向的磁化矢量的指数性衰减过程。磁共振成像时,对置于外磁场B0中的自旋系统施加90°射频脉冲,则自旋系统被激励,其净磁化矢量指向与外磁场B0垂直;射频脉冲终止后,被激励的质子与邻近的原子核之间发生相互作用,逐渐失去相位,净磁化矢量指向恢复与外磁场平行,该过程称自旋-自旋弛豫。自旋-自旋弛豫过程无能量交换。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条