From: hackbard Date: Wed, 21 Sep 2011 09:08:45 +0000 (+0200) Subject: refs added X-Git-Url: https://hackdaworld.org/gitweb/?a=commitdiff_plain;h=5d82b4e30a8ba13492dd0c38f544520952d53eaf;p=lectures%2Flatex.git refs added --- diff --git a/bibdb/bibdb.bib b/bibdb/bibdb.bib index 92eba98..6ce19ef 100644 --- a/bibdb/bibdb.bib +++ b/bibdb/bibdb.bib @@ -4675,8 +4675,8 @@ R. P. Smith and S. T. Allen and T. J. Smith and Z. Ring and J. J. Sumakeris and A. W. Saxler and J. W. Milligan", - booktitle = "Microwave Symposium Digest, 2002 IEEE MTT-S - International", + booktitle = "2002 IEEE MTT-S International Microwave Symposium + Digest", title = "Applications of Si{C} {MESFET}s and Ga{N} {HEMT}s in power amplifier design", year = "2002", @@ -4693,8 +4693,8 @@ author = "F. Temcamani and P. Pouvil and O. Noblanc and C. Brylinski and P. Bannelier and B. Darges and J. P. Prigent", - booktitle = "Microwave Symposium Digest, 2001 IEEE MTT-S - International", + booktitle = "2001 IEEE MTT-S International Microwave Symposium + Digest", title = "Silicon carbide {MESFET}s performances and application in broadcast power amplifiers", year = "2001", @@ -4723,7 +4723,7 @@ @Article{bhatnagar93, author = "M. Bhatnagar and B. J. Baliga", - journal = "Electron Devices, IEEE Transactions on", + journal = "IEEE Trans. Electron Devices", title = "Comparison of 6{H}-Si{C}, 3{C}-Si{C}, and Si for power devices", year = "1993", @@ -4744,10 +4744,84 @@ notes = "comparison 3c 6h sic and si devices", } +@Article{ryu01, + author = "Sei-Hyung Ryu and A. K. Agarwal and R. Singh and J. W. + Palmour", + journal = "IEEE Electron Device Lett.", + title = "1800 {V} {NPN} bipolar junction transistors in + 4{H}-Si{C}", + year = "2001", + month = mar, + volume = "22", + number = "3", + pages = "124--126", + keywords = "1800 V;4H-SiC high-voltage n-p-n bipolar junction + transistor;SiC;blocking voltage;current gain;deep level + acceptor;minority carrier lifetime;on-resistance;power + switching device;temperature coefficient;carrier + lifetime;deep levels;minority carriers;power bipolar + transistors;silicon compounds;wide band gap + semiconductors;", + doi = "10.1109/55.910617", + ISSN = "0741-3106", +} + +@Article{baliga96, + author = "B. J. Baliga", + journal = "IEEE Trans. Electron Devices", + title = "Trends in power semiconductor devices", + year = "1996", + month = oct, + volume = "43", + number = "10", + pages = "1717--1731", + keywords = "DMOS technology;GTO;GaAs;IGBT;MOS-gated + devices;MOS-gated thyristors;MPS rectifier;PIN + rectifier;Schottky rectifier;Si;SiC;SiC based + switches;TMBS rectifier;UMOS technology;VMOS + technology;bipolar power transistor;high voltage power + rectifiers;low voltage power rectifiers;power + MOSFET;power losses;power semiconductor devices;power + switch technology;review;semiconductor device + technology;MOS-controlled thyristors;bipolar transistor + switches;field effect transistor switches;gallium + arsenide;insulated gate bipolar transistors;p-i-n + diodes;power bipolar transistors;power field effect + transistors;power semiconductor devices;power + semiconductor diodes;power semiconductor + switches;reviews;silicon;silicon compounds;solid-state + rectifiers;thyristors;", + doi = "10.1109/16.536818", + ISSN = "0018-9383", +} + +@Article{bhatnagar92, + author = "M. Bhatnagar and P. K. McLarty and B. J. Baliga", + journal = "IEEE Electron Device Lett.", + title = "Silicon-carbide high-voltage (400 {V}) Schottky + barrier diodes", + year = "1992", + month = oct, + volume = "13", + number = "10", + pages = "501--503", + keywords = "1.1 V;25 to 200 C;400 V;6H-SiC;Pt-SiC;Schottky barrier + diodes;breakdown + voltages;characteristics;fabrication;forward I-V + characteristics;forward voltage drop;on-state current + density;rectifiers;reverse I-V characteristics;reverse + recovery characteristics;sharp breakdown;temperature + range;Schottky-barrier diodes;platinum;power + electronics;semiconductor materials;silicon + compounds;solid-state rectifiers;", + doi = "10.1109/55.192814", + ISSN = "0741-3106", +} + @Article{neudeck94, author = "P. G. Neudeck and D. J. Larkin and J. E. Starr and J. A. Powell and C. S. Salupo and L. G. Matus", - journal = "Electron Devices, IEEE Transactions on", + journal = "IEEE Trans. Electron Devices", title = "Electrical properties of epitaxial 3{C}- and 6{H}-Si{C} p-n junction diodes produced side-by-side on 6{H}-Si{C} substrates", @@ -4774,6 +4848,98 @@ substrate", } +@Article{weitzel96, + author = "C. E. Weitzel and J. W. Palmour and Jr. {Carter, C.H.} + and K. Moore and K. K. Nordquist and S. Allen and C. + Thero and M. Bhatnagar", + journal = "IEEE Trans. Electron Devices", + title = "Silicon carbide high-power devices", + year = "1996", + month = oct, + volume = "43", + number = "10", + pages = "1732--1741", + keywords = "1200 V;1400 V;4H-SiC;500 MHz to 32 GHz;57 W;Schottky + barrier diodes;SiC;SiC devices;UMOSFET;current + density;high electric breakdown field;high saturated + electron drift velocity;high thermal + conductivity;high-power devices;packaged SIT;submicron + gate length MESFET;Schottky diodes;current + density;electric breakdown;power MESFET;power + MOSFET;power semiconductor devices;power semiconductor + diodes;reviews;silicon compounds;static induction + transistors;wide band gap semiconductors;", + doi = "10.1109/16.536819", + ISSN = "0018-9383", + notes = "high power devices", +} + +@Article{zhu08, + author = "Lin Zhu and T. P. Chow", + journal = "IEEE Trans. Electron Devices", + title = "Advanced High-Voltage 4{H}-Si{C} Schottky Rectifiers", + year = "2008", + month = aug, + volume = "55", + number = "8", + pages = "1871--1874", + keywords = "H-SiC;OFF-state characteristics;ON-state + characteristics;blocking capability;high-voltage + Schottky rectifier;junction barrier Schottky + rectifier;lateral channel JBS rectifier;leakage + current;pinlike reverse characteristics;Schottky + barriers;Schottky diodes;leakage currents;rectifying + circuits;", + doi = "10.1109/TED.2008.926642", + ISSN = "0018-9383", +} + +@Article{brown93, + author = "D. M. Brown and E. T. Downey and M. Ghezzo and J. W. + Kretchmer and R. J. Saia and Y. S. Liu and J. A. Edmond + and G. Gati and J. M. Pimbley and W. E. Schneider", + journal = "IEEE Trans. Electron Devices", + title = "Silicon carbide {UV} photodiodes", + year = "1993", + month = feb, + volume = "40", + number = "2", + pages = "325--333", + keywords = "200 to 400 nm;6H epitaxial layers;SiC photodiodes;UV + responsivity characteristics;low dark current;low light + level UV detection;quantum + efficiency;reproducibility;reverse current + leakage;short circuit output current;leakage + currents;photodiodes;semiconductor + materials;short-circuit currents;silicon + compounds;ultraviolet detectors;", + doi = "10.1109/16.182509", + ISSN = "0018-9383", + notes = "sic photo diodes, uv detector", +} + +@Article{yan04, + author = "Feng Yan and Xiaobin Xin and S. Aslam and Yuegang Zhao + and D. Franz and J. H. Zhao and M. Weiner", + journal = "IEEE J. Quantum Electron.", + title = "4{H}-Si{C} {UV} photo detectors with large area and + very high specific detectivity", + year = "2004", + month = sep, + volume = "40", + number = "9", + pages = "1315--1320", + keywords = "-1 V; 1.2E-14 A; 210 to 350 nm; 4H-SiC UV + photodetectors; 5 mm; Pt/4H-SiC Schottky photodiodes; + SiC-Pt; leakage current; photoresponse spectra; quantum + efficiency; specific detectivity; Schottky diodes; + photodetectors; platinum; silicon compounds; wide band + gap semiconductors;", + doi = "10.1109/JQE.2004.833196", + ISSN = "0018-9197", + notes = "uv detector", +} + @Article{schulze98, author = "N. Schulze and D. L. Barrett and G. Pensl", collaboration = "", diff --git a/posic/thesis/sic.tex b/posic/thesis/sic.tex index b2b71b1..55d04fc 100644 --- a/posic/thesis/sic.tex +++ b/posic/thesis/sic.tex @@ -81,8 +81,8 @@ However, even for GaN based diodes SiC turns out to be of great importance since As such, SiC will continue to play a major role in the production of future super-bright visible emitters. Especially substrates of the 3C polytype promise good quality, single crystalline GaN films~\cite{takeuchi91,yamamoto04,ito04,haeberlen10}. -The focus of SiC based applications, however, is in the area of solid state electronics experiencing revolutionary performance improvements enabled by its capabilities~\cite{wesch96,morkoc94,casady96,capano97,pensl93,park98,edgar92,sarro00}. -These devices include ultraviolet (UV) detectors, high power radio frequency (RF) amplifiers, rectifiers and switching transistors as well as microelectromechanical system (MEMS) applications. +The focus of SiC based applications, however, is in the area of solid state electronics experiencing revolutionary performance improvements enabled by its capabilities~\cite{wesch96,morkoc94,casady96,capano97,pensl93,park98,edgar92}. +These devices include ultraviolet (UV) detectors~\cite{brown93,yan04}, high power radio frequency (RF) amplifiers, rectifiers and switching transistors~\cite{pribble02,baliga96,weitzel96,zhu08,bhatnagar92,bhatnagar93,ryu01} as well as microelectromechanical system (MEMS) applications~\cite{sarro00}. For UV detectors the wide band gap is useful for realizing low photodiode dark currents as well as sensors that are blind to undesired near-infrared wavelengths produced by heat and solar radiation. These photodiodes serve as excellent sensors applicable in the monitoring and control of turbine engine combustion. The low dark currents enable the use in X-ray, heavy ion and neutron detection in nuclear reactor monitoring and enhanced scientific studies of high-energy particle collisions as well as cosmic radiation.