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Quantum Waveguide in Microcircuits / Jian-Bai Xia, Duan-Yang Liu, Wei-Dong Sheng.

By: Xia, Jian Bai [author.].
Contributor(s): Liu, Duan Yang [author.] | Sheng, Wei Dong [author.].
Material type: materialTypeLabelBookPublisher: Singapore : Pan Stanford Publishing, 2018Edition: First edition.Description: 1 online resource.ISBN: 9781315364773; 9781315322148.Subject(s): Semiconductors | OptoelectronicsAdditional physical formats: Print version: : No titleDDC classification: 621.38152 Online resources: Click here to view.
Contents:
part Part I. Non-classical, Non-linear Transport -- chapter 1 Properties Of Quantum Transport -- chapter 2 Non-equilibrium Transport -- chapter 3 Resonant Tunneling -- chapter 4 Longitudinal Transport Of Superlattices -- chapter 5 Mesoscopic Transport -- chapter 6 Transport In Quantum Dots -- chapter 7 Silicon Single-electron Transistor -- chapter 8 Silicon Single-electron Memory -- part Part II. Quantum Waveguide Theory In Mesoscopic Systems -- chapter 9 Properties Of Quantum Transport -- chapter 10 One-Dimensional QuantumWaveguide Theory -- chapter 11 Two-Dimensional QuantumWaveguide Theory -- chapter 12 One-Dimensional QuantumWaveguide Theory of a Rashba Electron -- chapter 13 1D QuantumWaveguide Theory of Rashba Electrons in Curved Circuits -- chapter 14 Spin Polarization Of A Rashba Electron With A Mixed State -- chapter 15 Two-Dimensional QuantumWaveguide Theory of Rashba Electrons.
Summary: "Moore's Law predicts that the degree of microprocessor integration of circuits would double every 18 months in DRAM. Although the scaling of microelectronic circuit elements still follows Moore's Law, the unit density of power consumption becomes unacceptable. Therefore, on one hand, people develop continuously the microelectronic technology. On the other, people consider the developing road after Moore's rule is broken. This book introduces theories and experiments of quantum transport and intends to provide foundations of semiconductor micro- and nano electronics for after the Moore age."--Provided by publisher.
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part Part I. Non-classical, Non-linear Transport -- chapter 1 Properties Of Quantum Transport -- chapter 2 Non-equilibrium Transport -- chapter 3 Resonant Tunneling -- chapter 4 Longitudinal Transport Of Superlattices -- chapter 5 Mesoscopic Transport -- chapter 6 Transport In Quantum Dots -- chapter 7 Silicon Single-electron Transistor -- chapter 8 Silicon Single-electron Memory -- part Part II. Quantum Waveguide Theory In Mesoscopic Systems -- chapter 9 Properties Of Quantum Transport -- chapter 10 One-Dimensional QuantumWaveguide Theory -- chapter 11 Two-Dimensional QuantumWaveguide Theory -- chapter 12 One-Dimensional QuantumWaveguide Theory of a Rashba Electron -- chapter 13 1D QuantumWaveguide Theory of Rashba Electrons in Curved Circuits -- chapter 14 Spin Polarization Of A Rashba Electron With A Mixed State -- chapter 15 Two-Dimensional QuantumWaveguide Theory of Rashba Electrons.

"Moore's Law predicts that the degree of microprocessor integration of circuits would double every 18 months in DRAM. Although the scaling of microelectronic circuit elements still follows Moore's Law, the unit density of power consumption becomes unacceptable. Therefore, on one hand, people develop continuously the microelectronic technology. On the other, people consider the developing road after Moore's rule is broken. This book introduces theories and experiments of quantum transport and intends to provide foundations of semiconductor micro- and nano electronics for after the Moore age."--Provided by publisher.

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