1、REGIONThe REGION statement defines the location of materials in a rectangular mesh.REGION NAME Materials LocationNAME=Semiconductor MaterialsSILICON 硅硅GAAS 砷化镓砷化镓POLYSILI 多晶硅多晶硅GERMANIU 锗锗SIC 碳化硅碳化硅SEMICOND 半导体半导体SIGE 锗硅锗硅ALGAAS 铝镓砷铝镓砷A-SILICO 多晶硅多晶硅DIAMOND 金刚石金刚石HGCDTE INAS INGAASINP S.OXIDE ZNSE Z
2、NTE ALINAS GAASP INGAP INASPInsulator MaterialsOXIDE NITRIDE SAPPHIRE OXYNITRI INSULATOLocation Case1:X.MIN=X.MAX=Y.MIN=Y.MAX=IX.MIN=IX.MAX=IY.MIN=IY.MAX=Case 2:ROTATE R.INNER=R.OUTER=X.CENTER=Y.CENTER=Case 3:POLYGON X.POLY=Y.POLY=The following REGION statements may be used to define the material re
3、gions for a MOSFET that has an interface between oxide and silicon at y=0.In this example,the silicon region was named“Body”and the oxide region was named“SiO2”:REGION NAME=Body SILICONREGION NAME=Si02 OXIDE Y.MAX=0SiSiO2Polygon region A polygon can be specified which defines boundaries of a region.
4、The following statement could be used to specify a triangular polysilicon region:REGION NAME=STRANGE POLYGON POLY+X.POLY=(1,2,3)+Y.POLY=(1,2,1)Circular regionA circular region can be defined by specifying a 0 parameter.The following statement could be used to specify a donut-shaped nitride region wi
5、th a center at x=0 and y=0,internal radius of 0.5 micron and external radius of 1 micron:A zero internal radius would convert a donut-shaped region into a circular one.REGION NAME=RING ROTATE NITRIDE+X.CENTER=0 Y.CENTER=0+R.INNER=0.5 R.OUTER=1ELECTRODEThe ELECTRODE statement specifies the placement
6、of electrodes in a devicestructure.ELECTRODE NAME=LOCALELECTRODENAME=VOID TOP|BOTTOM|LEFT|RIGHT|INTERFAC|PERIMETE X.MIN=|IX.MIN=X.MAX=|IX.MAX=Y.MIN=|IY.MIN=Y.MAX=|IY.MAX=(ROTATE X.CENTER=Y.CENTER=R.INNER=R.OUTER=)|(POLYGON X.POLY=Y.POLY=)|REGION=ELECTROD NAME=Drain INTERFAC X.MIN=2.5ELECTROD NAME=Ga
7、te TOP X.MIN=1.0 X.MAX=2.0ELECTROD NAME=Source INTERFAC X.MAX=0.5ELECTROD NAME=Substrate BOTTOMELECTROD NAME=RING ROTATE+X.CENTER=0 Y.CENTER=0+R.INNER=0.5 R.OUTER=1A region name may be specified that is converted to an electrode.In this case,every node in the specified region becomes part of the ele
8、ctrode.As an example,the following statement converts region named Top_part into an electrode.The electrode name in this example is arbitrarily chosen to be Anode.ELECTROD NAME=Anode REGION=Top_partPROFILEThe PROFILE statement defines impurity profiles to be used in the device structure.Statement fo
9、rmatPROFILE type local Profiles Outputtype N-TYPE P-TYPE regionREGION=localX.MIN=WIDTH=|X.MAX=Y.MIN=DEPTH=|Y.MAX=Output Doping FileOUT.FILE=Uniform Profile Analytic or One-Dimensional Profiles from Data Files Two-Dimensional Profiles from Data Files Polygonal Profiles Rotated ProfileUniform ProfileU
10、NIFORM N.PEAK=Analytic or One-Dimensional Profiles from Data Files|(X.CHAR=|XY.RATIO=X.ERFC(N.PEAK=|DOSE=Y.CHAR=|Y.JUNCTI=)Two-Dimensional Profiles from Data Files|(2D.PROC|SUPRA|TSUPREM4|(2D.ASCII X.COLUMN=Y.COLUMN=N.COLUMN=P.COLUMN=)IN.FILE=N.OFFSET=X.OFFSET=Y.OFFSET=X.CHAR=X.ERFC Y.CHAR=Y.ERFC)Ch
11、oosing Impurity Profiles to InputThe choice of which impurity profiles to input from the file is made by specifying either,both,or none of the parameters N-TYPE and P-TYPE.If neither parameter is specified,then both the donor and acceptor impurity profiles are read from the data file.If the impurity
12、 profiles are taken from a formatted file,the parameters N.COLUMN and P.COLUMN are used to identify columns of data containing net donor and/or net acceptor impurity concentration.As an example,the following PROFILE statements read in impurity profiles generated by TMA SUPREM-3 in order to specify t
13、he doping for an N-channelMOSFET:PROFILE P-TYPE 1D.PROC IN.FILE=CHANNELPROFILE N-TYPE 1D.PROC IN.FILE=SRCDRN X.MIN=0 WIDTH=1+XY.RATIO=.8PROFILE N-TYPE 1D.PROC IN.FILE=SRCDRN X.MIN=3 WIDTH=1+XY.RATIO=.8Two-Dimensional Profiles From Data FilesThe entire two-dimensional impurity profile may be input fr
14、om a data file by specifying the IN.FILE parameter and one parameter from the set 2D.PROC,SUPRA,TSUPREM4,and 2D.ASCII.By default the origin for the impurity profile is aligned with the origin in Medici.The X.OFFSET and Y.OFFSET parameters may be used to shift the two-dimensional impurity profile rel
15、ative to Medici structure.Polygonal Profiles(N.PEAK=POLYGON X.POLY=Y.POLY=N.CHAR=N.ERFC)Rotated Profile(N.PEAK=ROTATE X.CENTER=Y.CENTER=R.INNER=R.OUTER=R.CHAR=R.ERFC)COMMENT Specify impurity profiles and fixed chargePROFILE P-TYPE N.PEAK=3E15 UNIFORM OUT.FILE=MDEX1DSPROFILE P-TYPE N.PEAK=2E16 Y.CHAR
16、=.25PROFILE N-TYPE N.PEAK=2E20 Y.JUNC=.34 X.MIN=0.0 WIDTH=.5+XY.RAT=.75PROFILE N-TYPE N.PEAK=2E20 Y.JUNC=.34 X.MIN=2.5 WIDTH=.5+XY.RAT=.75REGRIDThe REGRID statement allows refinement of a coarse mesh.REGRID Regrid-Criteria Regrid-Controls Local OutputLocalX.MIN=X.MAX=Y.MIN=Y.MAX=REGION=IGNORE=COS.AN
17、GL=Output OUT.FILE=NO.TTINF ASCII Regrid Criteria POTENTIA|(E.FIELD X.COMPON|Y.COMPON )|QFN|QFP|DOPING|ELECTRON|HOLES|NET.CHAR|NET.CARR|(MIN.CARR LOCALDOP)|II.GENER|BB.GENER|PHOTOGEN|ELE.TEMP|HOL.TEMP|TRUNC|ARRAY1|ARRAY2|ARRAY3Regrid Controls(RATIO=|FACTOR=)IN.FILE=CHANGE ABSOLUTE LOGARITH MAX.LEVE=SMOOTH.K=REGRID DOPING LOG IGNORE=OXIDE RATIO=2 SMOOTH=1+IN.FILE=MDEX1DSREGRID POTEN IGNORE=OXIDE RATIO=.2 MAX=1 SMOOTH=1+IN.FILE=MDEX1DS