Download Free Silicon On Insulator Technology And Devices X Book in PDF and EPUB Free Download. You can read online Silicon On Insulator Technology And Devices X and write the review.

This issue of ESC Transactions covers recent significant advances in SOI technologies. It will be of interest to materials and device scientists, as well as to process and applications oriented engineers. Several keynote papers introduce and review the main topics. This is followed by contributed papers covering the latest research and implementation results.
Silicon-on-Insulator Technology: Materials to VLSI, Third Edition, retraces the evolution of SOI materials, devices and circuits over a period of roughly twenty years. Twenty years of progress, research and development during which SOI material fabrication techniques have been born and abandoned, devices have been invented and forgotten, but, most importantly, twenty years during which SOI Technology has little by little proven it could outperform bulk silicon in every possible way. The turn of the century turned out to be a milestone for the semiconductor industry, as high-quality SOI wafers suddenly became available in large quantities. From then on, it took only a few years to witness the use of SOI technology in a wealth of applications ranging from audio amplifiers and wristwatches to 64-bit microprocessors. This book presents a complete and state-of-the-art review of SOI materials, devices and circuits. SOI fabrication and characterization techniques, SOI CMOS processing, and the physics of the SOI MOSFET receive an in-depth analysis.
This issue of ECS Transactions contains papers on silicon-on-insulator subjects including devices, device physics, modelling, simulations, microelectronics, photonics, nano-technology, integrated circuits, radiation hardness, material characterization, reliability, and sensors
Silicon-on-Insulator Technology: Materials to VLSI, 2nd Edition describes the different facets of SOI technology. SOI chips are now commercially available and SOI wafer manufacturers have gone public. SOI has finally made it out of the academic world and is now a big concern for every major semiconductor company. SOI technology has indeed deserved serious recognition: high-temperature (400°C), extremely rad-hard (500 Mrad(Si)), high-density (16 Mb, 0.9-volt DRAM), high-speed (several GHz) and low-voltage (0.5 V) SOI circuits have been demonstrated. Strategic choices in favor of the use of SOI for low-voltage, low-power portable systems have been made by several major semiconductor manufacturers. Silicon-on-Insulator Technology: Materials to VLSI, 2nd Edition presents a complete and state-of-the-art review of SOI materials, devices and circuits. SOI fabrication and characterization techniques, SOI device processing, the physics of the SOI MOSFET as well as that of SOI other devices, and the performances of SOI circuits are discussed in detail. The SOI specialist will find this book invaluable as a source of compiled references covering the different aspects of SOI technology. For the non-specialist, the book serves as an excellent introduction to the topic with detailed, yet simple and clear explanations. Silicon-on-Insulator Technology: Materials to VLSI, 2nd Edition is recommended for use as a textbook for classes on semiconductor device processing and physics. The level of the book is appropriate for teaching at both the undergraduate and graduate levels. Silicon-on-Insulator Technology: Materials to VLSI, 2nd Edition includes the new materials, devices, and circuit concepts which have been devised since the publication of the first edition. The circuit sections, in particular, have been updated to present the performances of SOI devices for low-voltage, low-power applications, as well as for high-temperature, smart-power, and DRAM applications. The other sections, such as those describing SOI materials, the physics of the SOI MOSFET and other devices have been updated to present the state of the art in SOI technology.
Memory devices based on floating-body effects (FBE) in Silicon-on-Insulator (SOI) technology are among the most promising candidates for sub-100nm and low power Dynamic Random Access Memory (DRAM). This new type of DRAMs, called Zero-Capacitor RAM (Z-RAM), uses only one transistor in partially-depleted (PD) SOI technology and takes advantage of FBE which have been considered as parasitic phenomena until now. The Z-RAM programming principles are based on the threshold voltage VTH variations induced by the excess or lack of majority carriers in the floating body. In this dissertation, a new floating-body effect, the Transient Floating Body Potential Effect (TFBPE), based on the body majority carriers non-equilibrium and on the dual dynamic gate coupling in standard fully-depleted (FD) SOI MOSFETs is presented for the first time. The TFBPE occurs in a specific gate bias range and can induce strong hysteresis of the gate and drain current characteristics although the FD SOI transistors are usually known to be immune against the FBE and their aftermaths. Adapted from the same physics principles as in the drain current hysteresis, that we called the Meta-Stable Dip (MSD) effect, a new concept of one-transistor capacitor-less memory was also proposed, the Meta-Stable DRAM (MSDRAM) which is dedicated for double-gate operations. All the experimental results and physics interpretations were supported by 2D numerical simulations. A 1D semi-analytical model of the body potential for non-equilibrium states was also proposed. For the first time, this original body-potential model takes into account the majority carriers density variations, i.e., the quasi-Fermi level non-equilibrium versus a transient gate voltage scan in a FD MOS device.
This proceedings volume archives the contributions of the speakers who attended the NATO Advanced Research Workshop on “Science and Technology of Semiconductor-On-Insulator Structures and Devices Operating in a Harsh Environment” held at the Sanatorium Puscha Ozerna, th th Kyiv, Ukraine, from 25 to 29 April 2004. The semiconductor industry has maintained a very rapid growth during the last three decades through impressive technological achievements which have resulted in products with higher performance and lower cost per function. After many years of development semiconductor-on-insulator materials have entered volume production and will increasingly be used by the manufacturing industry. The wider use of semiconductor (especially silicon) on insulator materials will not only enable the benefits of these materials to be further demonstrated but, also, will drive down the cost of substrates which, in turn, will stimulate the development of other novel devices and applications. In itself this trend will encourage the promotion of the skills and ideas generated by researchers in the Former Soviet Union and Eastern Europe and their incorporation in future collaborations.