相应的,半导体电子学(微电子学)、激光电子学和相对论电子学等现代电子学领域则发端于此。
Accordingly the modern electronics such as the semiconductor electronics (microelectronics), the laser electronics and the relativistic electronics etc began to develop.
自旋电子学在创建更高速、更节能的电路元件方面比标准半导体器件拥有更大的潜力。
Spintronics holds great promise for creating circuits that are faster and more energy efficient than standard semiconductor devices.
半导体垂直腔面发射量子阱激光器是当前光电子学领域最活跃的研究课题之一。
Currently quantum well VCSEL (Vertical Cavity Surface Emitting Laser) is one of the most active research problems in the field of optoelectronics.
而另一方面电子学则论述自由电子在电子管或半导体里流动的情况。
Electronics, on the other hand, deals with the movement of free electrons in a vacuum or in semiconductors.
但是锁相环的设计过程,涉及到信号与系统、集成电子学、版图、半导体工艺和测试等方面,难度比较大。
But PLLs design process involves much theory and application base, such as signal and system, integrated electronics, layout, semiconductor technology, measurement etc.
半导体异质外延材料和量子点材料在纳米电子学、光电子学中具有广泛的应用前景。
The materials of semiconductor hetero-epitaxy and quantum dots are widely used in the fields such as nano-electronics and optoelectronics.
稀磁半导体作为自旋电子学的重要基础,目前引起了科学界广泛的关注。
Meanwhile, as the footstone of designing spin-based devices, diluted magnetic semiconductors have now drawn dramatic attentions.
自旋电子学器件需要一个有效的自旋注入到传统的半导体中,最近人们比较感兴趣的是利用自旋相关的输运现象-自旋轨道耦合来产生自旋极化。
Of special interest is to produce an uneven spin population out of an unpolarized source by means of various spin-related transport phenomena (relativistic spin-orbit interaction).
自旋电子学的飞速发展及其在电子器件领域的实用性使得磁性半导体成为当前的研究热点。
The rapid development of spintronics and its usefulness in the field of electronic devices makes the magnetic semiconductor become a research hotspot.
自旋电子学的飞速发展及其在电子器件领域的实用性使得磁性半导体成为当前的研究热点。
The rapid development of spintronics and its usefulness in the field of electronic devices makes the magnetic semiconductor become a research hotspot.
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