Ion Implantation in Semiconductors
Ion Implantation in Semiconductors

Author: Susumu Namba

Publisher: Springer Science & Business Media

Published: 2012-12-06

Total Pages: 716

ISBN-13: 1468421514

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The technique of ion implantation has become a very useful and stable technique in the field of semiconductor device fabrication. This use of ion implantation is being adopted by industry. Another important application is the fundamental study of the physical properties of materials. The First Conference on Ion Implantation in Semiconductors was held at Thousand Oaks, California in 1970. The second conference in this series was held at Garmish-Partenkirchen, Germany, in 1971. At the third conference, which convened at Yorktown Heights, New York in 1973, the emphasis was broadened to include metals and insulators as well as semiconductors. This scope of the conference was still accepted at the fourth conference which was held at Osaka, Japan, in 1974. A huge number of papers had been submitted to this conference. All papers which were presented at the Fourth International Conference on Ion Implantation in Semiconductors and Other Materials are included in this proceedings. The success of this conference was due to technical presentations and discussions of 224 participants from 14 countries as well as to financial support from many companies in Japan. On behalf of the committee, I wish to thank the authors for their excellent papers and the sponsors for their financial support. The International Committee responsible for advising this conference consisted of B.L. Crowder, J.A. Davies, G. Dearna1ey, F.H. Eisen, Ph. G1otin, T. Itoh, A.U. MacRae, J.W. Mayer, S. Namba, I. Ruge, and F.L. Vook.

Ion Implantation: Basics to Device Fabrication
Ion Implantation: Basics to Device Fabrication

Author: Emanuele Rimini

Publisher: Springer Science & Business Media

Published: 2013-11-27

Total Pages: 400

ISBN-13: 1461522595

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Ion implantation offers one of the best examples of a topic that starting from the basic research level has reached the high technology level within the framework of microelectronics. As the major or the unique procedure to selectively dope semiconductor materials for device fabrication, ion implantation takes advantage of the tremendous development of microelectronics and it evolves in a multidisciplinary frame. Physicists, chemists, materials sci entists, processing, device production, device design and ion beam engineers are all involved in this subject. The present monography deals with several aspects of ion implantation. The first chapter covers basic information on the physics of devices together with a brief description of the main trends in the field. The second chapter is devoted to ion im planters, including also high energy apparatus and a description of wafer charging and contaminants. Yield is a quite relevant is sue in the industrial surrounding and must be also discussed in the academic ambient. The slowing down of ions is treated in the third chapter both analytically and by numerical simulation meth ods. Channeling implants are described in some details in view of their relevance at the zero degree implants and of the available industrial parallel beam systems. Damage and its annealing are the key processes in ion implantation. Chapter four and five are dedicated to this extremely important subject.

Silicon Molecular Beam Epitaxy
Silicon Molecular Beam Epitaxy

Author: E. Kasper

Publisher: CRC Press

Published: 2018-05-04

Total Pages: 306

ISBN-13: 1351085077

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This subject is divided into two volumes. Volume I is on homoepitaxy with the necessary systems, techniques, and models for growth and dopant incorporation. Three chapters on homoepitaxy are followed by two chapters describing the different ways in which MBE may be applied to create insulator/Si stackings which may be used for three-dimensional circuits. The two remaining chapters in Volume I are devoted to device applications. The first three chapters of Volume II treat all aspects of heteroepitaxy with the exception of the epitaxial insulator/Si structures already treated in volume I.

Ion Implantation and Activation
Ion Implantation and Activation

Author: Kunihiro Suzuki

Publisher: Bentham Science Publishers

Published: 2013-11-05

Total Pages: 171

ISBN-13: 1608057909

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Ion Implantation and Activation presents the derivation process of related models in a comprehensive step by step manner starting from the fundamental processes and moving up into the more advanced theories. Ion implantation can be expressed theoretically as a binary collision, and, experimentally using various mathematical functions. Readers can understand how to establish an ion implantation database by combining theory and experimental data. The models described in this ebook can be directly related to practical experimental data with various approaches: physical, empirical or experimental. Readers can also understand the approximations, and assumptions to reach these models. The redistribution and activation of implanted impurities during subsequent thermal processes are also important subjects and they are described in a broad manner with the combination of theory and experiment, even though many of the models are not well established. Chapters in the book explain, in depth, various topics such as Pearson functions, LSS theory, Monte Carlo simulations, Edgeworth Polynomials and much more. This book provides advanced engineering and physics students and researchers with complete and coherent coverage of modern semiconductor process modeling. Readers can also benefit from this volume by acquiring the necessary information to improve contemporary process models by themselves.

Selective Area P-type Doping in Gallium Nitride Using Ion Implantation for High Power Applications
Selective Area P-type Doping in Gallium Nitride Using Ion Implantation for High Power Applications

Author: Yekan Wang

Publisher:

Published: 2022

Total Pages: 104

ISBN-13:

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Magnesium ion implantation and subsequent activation annealing shows promise as an effective p-type doping method in Gallium Nitride (GaN). This dissertation relates implant-induced defects and the electrical performance. The implantation process introduces an elastic strain purely orthogonal to the (0001). Complete strain recovery is achieved by annealing at 1300 °C for 10 min (one GPa N2 overpressure) for dose level up to 1 1015 cm-2. However, extended defects such as stacking faults, dislocation loops, and inversion domains form during the anneal. Critical extended defects in the form of inversion domains were found to contain electrically inactive Mg after annealing at temperatures of 1300 °C (one GPa N2 overpressure), which results in a low dopant activation efficiency. A key finding of this work was to demonstrate that annealing at temperatures above 1300 °C eliminates the presence of the Mg-rich inversion domains. While other residual defects, such as dislocation loops, still exist after annealing at and above 1400 °C, chemical analysis shows no sign of Mg segregation at dislocation loops or other defects. Meanwhile, an overall decreasing trend in the dislocation loop size and density is observed after annealing at the higher temperatures and longer times. Electrical measurements show that annealing at 1400 °C leads to a dopant activation efficiency that is an order of magnitude higher than that observed at 1300 °C, which points to the benefits, in terms of defect density and p-type dopant activation, of using higher temperatures (e"1400 °C) annealing cycles to activate Mg acceptors. Novel characterization methods combining high resolution x-ray scattering and transmission electron microscopy were developed to understand the implant-induced strain recovery process and the evolution of extended defect structures after the dopant activation anneal. It was found that homoepitaxial GaN on high quality native substrates is necessary for clearly assessing the implant-induced defects by separating them from the pre-existing intrinsic defects. Results from this work are expected to bring the understanding of the key processing steps to achieve high activation efficiency selective area p-type doping for vertical GaN device structures in a scalable framework

High-Energy Ion Implantation for Multigigabit-Rate GaAs Integrated Circuit
High-Energy Ion Implantation for Multigigabit-Rate GaAs Integrated Circuit

Author: S. G. Liu

Publisher:

Published: 1979

Total Pages: 79

ISBN-13:

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The objectives of this program are: (1) study of high-energy ion implantation of donors into GaAs for multigigabit-rate GaAs integrated-circuit development; and (2) annealing of implanted GaAs using high-power lasers to remove lattice damage and activate implanted donors. We have: (1) investigated implantation of Si(28+) into semi-insulating GaAs with implant energies ranging from 40 keV to 1.2 MeV; (2) developed a capless thermal annealing process under arsenic overpressure which results in high activation efficiency with excellent surface morphology; (3) investigated laser-annealing of Si-implanted GaAs using a high-power Nd:Glass laser and a ruby laser. Electrical activation of high-dose, low-energy (

Ion Implantation in Semiconductors 1976
Ion Implantation in Semiconductors 1976

Author: Fred Chernow

Publisher: Springer Science & Business Media

Published: 2012-12-06

Total Pages: 733

ISBN-13: 1461341965

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The Fifth International Conference on Ion Implantation took place in Boulder, Colorado between the 9th and 13th of August 1976. Papers were delivered by scientists and engineers from 15 countries, and the attendees represented 19 countries. As has become the custom at these conferences, the sessions were intense with the coffee breaks and evenings given to informal meetings among the participants. It was a time to renew old friendships, begin new ones, exchange ideas, personally question authors of papers that appeared in the literature since the last conference and find out what was generally happening in Ion Implantation. In recent years it has beome more difficult to get funding to travel to such meetings. To assist the participating authors financial aid was solicited from industry and the Office of Naval Research. We are most grateful for their positive response to our requests. The success of the conference was in part due to their generous contributions. The Program Committee had the unhappy task of the reviewing of more than 170 abstracts. The result of their labors was well worth their effort. Much thanks goes to them for molding the conference into an accurate representation of activities in the field. Behind the scenes in Boulder, local arrangements were handled ably by Graeme Eldridge. The difficulty of this task cannot be overemphasized. Our thanks to him for a job well done.