scholarly journals Selective Doping in Silicon Carbide Power Devices

Materials ◽  
2021 ◽  
Vol 14 (14) ◽  
pp. 3923
Author(s):  
Fabrizio Roccaforte ◽  
Patrick Fiorenza ◽  
Marilena Vivona ◽  
Giuseppe Greco ◽  
Filippo Giannazzo
Keyword(s):  
Silicon Carbide ◽  
Ion Implantation ◽  
Large Scale ◽  
High Efficiency ◽  
Wide Band ◽  
Power Devices ◽  
Wide Band Gap ◽  
Selective Doping ◽  
P Type ◽  
Post Implantation

Silicon carbide (SiC) is the most mature wide band-gap semiconductor and is currently employed for the fabrication of high-efficiency power electronic devices, such as diodes and transistors. In this context, selective doping is one of the key processes needed for the fabrication of these devices. This paper concisely reviews the main selective doping techniques for SiC power devices technology. In particular, due to the low diffusivity of the main impurities in SiC, ion implantation is the method of choice to achieve selective doping of the material. Hence, most of this work is dedicated to illustrating the main features of n-type and p-type ion-implantation doping of SiC and discussing the related issues. As an example, one of the main features of implantation doping is the need for post-implantation annealing processes at high temperatures (above 1500 °C) for electrical activation, thus having a notable morphological and structural impact on the material and, hence, on some device parameters. In this respect, some specific examples elucidating the relevant implications on devices’ performances are reported in the paper. Finally, a short overview of recently developed non-conventional doping and annealing techniques is also provided, although these techniques are still far from being applied in large-scale devices’ manufacturing.

scholarly journals Ion Implantation Doping in Silicon Carbide and Gallium Nitride Electronic Devices

Micro ◽  
2022 ◽  
Vol 2 (1) ◽  
pp. 23-53
Author(s):  
Fabrizio Roccaforte ◽  
Filippo Giannazzo ◽  
Giuseppe Greco
Keyword(s):  
Silicon Carbide ◽  
Gallium Nitride ◽  
Ion Implantation ◽  
Band Gap ◽  
Electronic Devices ◽  
Wide Band ◽  
Decomposition Temperature ◽  
Wide Band Gap ◽  
Selective Doping ◽  
The Impact

Wide band gap semiconductors such as silicon carbide (SiC) and gallium nitride (GaN) are excellent materials for the next generation of high-power and high-frequency electronic devices. In fact, their wide band gap (>3 eV) and high critical electric field (>2 MV/cm) enable superior performances to be obtained with respect to the traditional silicon devices. Hence, today, a variety of diodes and transistors based on SiC and GaN are already available in the market. For the fabrication of these electronic devices, selective doping is required to create either n-type or p-type regions with different functionalities and at different doping levels (typically in the range 1016–1020 cm−3). In this context, due to the low diffusion coefficient of the typical dopant species in SiC, and to the relatively low decomposition temperature of GaN (about 900 °C), ion implantation is the only practical way to achieve selective doping in these materials. In this paper, the main issues related to ion implantation doping technology for SiC and GaN electronic devices are briefly reviewed. In particular, some specific literature case studies are illustrated to describe the impact of the ion implantation doping conditions (annealing temperature, electrical activation and doping profiles, surface morphology, creation of interface states, etc.) on the electrical parameters of power devices. Similarities and differences in the application of ion implantation doping technology in the two materials are highlighted in this paper.

Effects of Thermal Annealing Processes in Phosphorous Implanted 4H-SiC Layers

2019 ◽  
Vol 963 ◽  
pp. 407-411 ◽  
Author(s):  
Andrea Severino ◽  
Domenico Mello ◽  
Simona Boninelli ◽  
Fabrizio Roccaforte ◽  
Filippo Giannazzo ◽  
...  
Keyword(s):  
Silicon Carbide ◽  
Ion Implantation ◽  
Thermal Annealing ◽  
High Electron ◽  
Power Devices ◽  
High Quality ◽  
High Electron Mobility ◽  
Implantation Process ◽  
P Type ◽  
High Breakdown Electric Field

Silicon carbide (SiC) is an attractive material for power devices owing to the availability of high-quality epitaxial wafers and superior physical properties, such as its high breakdown electric field strength, high electron mobility, and low anisotropy. Ion implantation is a key process for both n- and p-type selective doping of SiC devices. A subsequent annealing in the temperature range of 1600- 1800°C is required to remove the damage induced by the implantation process and to electrically activate the implanted dopants. The aim of this work is the investigation of the effect of thermal annealing on the damage induced by Phosphorous ion implantation to produce n-type regions.

Packaging Trends and Challenges for Power Devices

2019 ◽  
Vol 2019 (DPC) ◽  
pp. 000706-000728
Author(s):  
E. Jan Vardaman
Keyword(s):  
Silicon Carbide ◽  
Band Gap ◽  
Smart Cities ◽  
Wide Band ◽  
Hybrid Vehicles ◽  
System Efficiency ◽  
Power Devices ◽  
Wide Band Gap ◽  
Electric Vehicle Charging ◽  
Silicon Based

Power devices are experiencing strong growth driven by demand in a variety of areas. Applications including energy generation and infrastructure, electric and hybrid vehicles, electric vehicle charging, datacenters, industrial automation, smart cities and buildings, home appliances, and transportation are driving demand for power devices. While many companies continue to expand production of silicon-based power devices, there is also demand for devices based on new wide band gap (WBG) materials such as silicon carbide (SiC) and gallium nitride (GaN). Driven by the need for increased power density and system efficiency, these WBG materials are being adopted in many applications and may require new packages, materials, and assembly methods. This presentation describes package trends and discusses some of the challenges faced.

High-Efficiency Lead-Free Wide Band Gap Perovskite Solar Cells via Guanidinium Bromide Incorporation

2021 ◽  
Author(s):  
Mengmeng Chen ◽  
Muhammad Akmal Kamarudin ◽  
Ajay K. Baranwal ◽  
Gaurav Kapil ◽  
Teresa S. Ripolles ◽  
...  
Keyword(s):  
Solar Cells ◽  
Band Gap ◽  
High Efficiency ◽  
Perovskite Solar Cells ◽  
Wide Band ◽  
Lead Free ◽  
Wide Band Gap

Wide band gap and p-type conductive Cu-Nb-O films

2011 ◽  
Vol 5 (4) ◽  
pp. 153-155 ◽  
Author(s):  
Seiji Yamazoe ◽  
Shunsuke Yanagimoto ◽  
Takahiro Wada
Keyword(s):  
Band Gap ◽  
Wide Band ◽  
Wide Band Gap ◽  
P Type

Improvement in Wide-Gap A-SI:H For High-Efficiency Solar Cells

1992 ◽  
Vol 258 ◽  
Author(s):  
Sadaji Tsuge ◽  
Yoshihiro Hishikawa ◽  
Shingo Okamoto ◽  
Manabu Sasaki ◽  
Shinya Tsuda ◽  
...  
Keyword(s):  
Solar Cells ◽  
Plasma Treatment ◽  
High Efficiency ◽  
Defect Density ◽  
Hydrogen Plasma ◽  
Wide Band ◽  
Open Circuit ◽  
Wide Band Gap ◽  
High Efficiency Solar Cells ◽  
Wide Gap

ABSTRACTA hydrogen-plasma treatment has been used for the first time to fabricate wide-gap, high-quality a-Si:H films. The hydrogen content (CH) of a-Si:H films substantially increases by the hydrogen-plasma treatment after deposition, without deteriorating the opto-electric properties of the films. The photoconductivity (σph) of ≥ 10-5 ο-1 cm-1, photosensitivity ( σ ph/σ d) of > 106 and SiH2/SiH of <0.2 are achieved for a film with CH of ∼25 atomic >%. The optical gap of the film is > 1.70 eV by the (α h ν )1/3 plot, and is >2 eV by the Tauc's plot. The open circuit voltage of a-Si solar cells exceeds 1 V conserving the fill factor of > 0.7 when the wide-gap a∼Si:H films are used as the i-layer, which proves the wide band gap and low defect density.

A pathway to p-type wide-band-gap semiconductors

2009 ◽  
Vol 95 (17) ◽  
pp. 172109 ◽  
Author(s):  
Anderson Janotti ◽  
Eric Snow ◽  
Chris G. Van de Walle
Keyword(s):  
Band Gap ◽  
Wide Band ◽  
Wide Band Gap ◽  
Wide Band Gap Semiconductors ◽  
P Type

High Temperature Silicon Carbide CMOS Integrated Circuits

2011 ◽  
Vol 679-680 ◽  
pp. 726-729 ◽  
Author(s):  
David T. Clark ◽  
Ewan P. Ramsay ◽  
A.E. Murphy ◽  
Dave A. Smith ◽  
Robin. F. Thompson ◽  
...  
Keyword(s):  
Silicon Carbide ◽  
High Temperature ◽  
Integrated Circuits ◽  
Band Gap ◽  
High Temperatures ◽  
Wide Band ◽  
Cmos Technology ◽  
Cmos Integrated Circuits ◽  
Wide Band Gap ◽  
Circuit Performance

The wide band-gap of Silicon Carbide (SiC) makes it a material suitable for high temperature integrated circuits [1], potentially operating up to and beyond 450°C. This paper describes the development of a 15V SiC CMOS technology developed to operate at high temperatures, n and p-channel transistor and preliminary circuit performance over temperature achieved in this technology.

scholarly journals A wide-band-gap p-type thermoelectric material based on quaternary chalcogenides of Cu2ZnSnQ4 (Q=S,Se)

2009 ◽  
Vol 94 (20) ◽  
pp. 202103 ◽  
Author(s):  
Min-Ling Liu ◽  
Fu-Qiang Huang ◽  
Li-Dong Chen ◽  
I-Wei Chen
Keyword(s):  
Band Gap ◽  
Thermoelectric Material ◽  
Wide Band ◽  
Wide Band Gap ◽  
P Type
Sign in / Sign up

Export Citation Format

Share Document