Advanced Silicon & Semiconducting Silicon-Alloy Based Materials & Devices
Advanced Silicon & Semiconducting Silicon-Alloy Based Materials & Devices

Author: Jo Nijs

Publisher: CRC Press

Published: 2021-05-30

Total Pages: 488

ISBN-13: 1000445062

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One of the first books to cover advanced silicon-based technologies, Advanced Silicon and Semiconducting Silicon Alloy-Based Materials and Devices presents important directions for research into silicon, its alloy-based semiconducting devices, and its development in commercial applications. The first section deals with single/mono crystalline silicon, focusing on the effects of heavy doping; the structure and electronic properties of defects and their impact on devices; the MBE of silicon, silicon alloys, and metals; CVD techniques for silicon and silicon germanium; the material properties of silicon germanium strained layers; silicon germanium heterojunction bipolar applications; FETs, IR detectors, and resonant tunneling devices in silicon, silicon germanium, and d-doped silicon; and the fascinating properties of crystalline silicon carbide and its applications. The second section explores polycrystalline silicon. It examines large grain polysilicon substrates for solar cells; the properties, analysis, and modeling of polysilicon TFTs; the technology of polysilicon TFTs in LCD displays; and the use of polycrystalline silicon and its alloys in VLSI applications. With contributors from leading academic and industrial research centers, this book provides wide coverage of fabrication techniques, material properties, and device applications.

Nanotechnology and Nanoelectronics
Nanotechnology and Nanoelectronics

Author: Wolfgang Fahrner

Publisher: Springer Science & Business Media

Published: 2005-12-05

Total Pages: 277

ISBN-13: 3540266216

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Split a human hair thirty thousand times, and you have the equivalent of a nanometer. The aim of this work is to provide an introduction into nanotechnology for the s- entifically interested. However, such an enterprise requires a balance between comprehensibility and scientific accuracy. In case of doubt, preference is given to the latter. Much more than in microtechnology – whose fundamentals we assume to be known – a certain range of engineering and natural sciences are interwoven in nanotechnology. For instance, newly developed tools from mechanical engine- ing are essential in the production of nanoelectronic structures. Vice versa, - chanical shifts in the nanometer range demand piezoelectric-operated actuators. Therefore, special attention is given to a comprehensive presentation of the matter. In our time, it is no longer sufficient to simply explain how an electronic device operates; the materials and procedures used for its production and the measuring instruments used for its characterization are equally important. The main chapters as well as several important sections in this book end in an evaluation of future prospects. Unfortunately, this way of separating coherent - scription from reflection and speculation could not be strictly maintained. So- times, the complete description of a device calls for discussion of its inherent - tential; the hasty reader in search of the general perspective is therefore advised to study this work’s technical chapters as well.

Reactive Ion Etching of Indium Phosphide-based Heterostructures and Field-effect Transistors Using Hydrogen Bromide Plasma
Reactive Ion Etching of Indium Phosphide-based Heterostructures and Field-effect Transistors Using Hydrogen Bromide Plasma

Author: Sambhulal Agarwala

Publisher:

Published: 1994

Total Pages:

ISBN-13:

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A new highly selective reactive ion etching process based on HBr plasma for the removal of InGaAs over InAlAs has been developed and the results are presented. The etch selectivity at a self-bias voltage of $-$100 V is over 160, which is the highest that has been reported for this material system so far. High etch selectivity is maintained over a wide range of chamber pressure and plasma self-bias voltages. The mechanism of this etch selectivity is determined to be due to the formation of involatile Al$sb2$O$sb3$. Selective HBr etching has been applied as the gate-recess process in the fabrication of InAlAs/InGaAs heterostructure FETs. Since less RIE-induced damage was observed in delta-doped structures, delta-doping was employed in all InP-based HFETs. The dc and rf device parameters of a typical 0.75-$mu$m gate-length transistor compare favorably with those of a corresponding device gate-recessed with a selective wet-etching technique. An extrinsic current-gain cutoff frequency of 150 GHz is obtained for a typical 0.2 $mu$m gate-length HFET device that was fabricated using selective HBr gate recess process. RIE-induced damage is characterized extensively using a variety of techniques such as AES, XPS, and SIMS analyses, Raman scattering, Hall measurements and Schottky characteristics. No significant degradation in surface properties is observed. The lattice damage in layer structures with 2DEG depth of greater than 20 nm was minimal. It is also observed that with increasing self-bias voltage the rate of removal of InGaAs increases faster than the rate of introduction of damage. An exponential distribution of damage with 1/e penetration depth of about 7.8 nm has been obtained. The exponential distribution of defects suggests that either ion channeling or diffusion is the possible mechanism of defect production in regions deeper than the projected range.