PROGRAM SYNTHE c revised 13jul15 molecule number increased, parameter mw=139, mw6=mw*6 c revised 11nov14 modified to agree with Fiorella Castelli's Linux version c including He I lines and reverting to her HPROF c revised 4nov14 constants given D exponents c revised 5mar02 Jo Bruls found dimensions of CONTX too small, now 26 c revised 20jul01 John Lester found dimensions of CONTX too small, now 25 c revised 14nov99 C THIS PROGRAM IS REAL*4 EXCEPT FOR WAVELENGTHS AND ENERGY LEVELS C REAL*8 INPUT ON TAPE10 IS CONVERTED TO REAL*4 C C TAPE5 INPUT C TAPE6 OUTPUT C TAPE7 temporary file for line identifications C TAPE8 file that passes the number of lines to SPECTRV C TAPE9 output opacity vectors and line data C TAPE10 input from XNFPELSYN C TAPE12 input line data needed for calculation C TAPE13 input line data, all data for each line C TAPE14 temporary file of opacity spectra C TAPE15 temporary file of opacity vectors for each line C TAPE19 input line data from RNLTE C TAPE93 parameters for this run from SYNBEG PARAMETER (kw=99,mw=139,mw6=mw*6) PARAMETER (LENREC=8000,MAXLEN=2000001,MAXPROF=10000, 1 MAXBUFF=MAXLEN+MAXPROF,MAXLIN=MAXBUFF+MAXPROF*2) C LENREC transposition is done in blocks of LENRECxkw C MAXLEN number of points in the spectrum C MAXPROF number of points in either wing of a line with a Voigt profile COMMON /BUFFER/BUFFER(MAXBUFF),PROFILE(MAXPROF) DIMENSION LINE(MAXLIN) DIMENSION TRANSP(kw,LENREC),RECORD(LENREC),INDEXR(5000) EQUIVALENCE (BUFFER(1),LINE(1),TRANSP(1)) C DIMENSION TRANSP(55000,kw) COMMON /CONTIN/CONTINUUM(MAXBUFF) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) COMMON /EXTAB/EXTAB(1001),EXTABF(1001),E1TAB(2000) COMMON /H1TAB/H0TAB(2001),H1TAB(2001),H2TAB(2001) COMMON /LINDAT/WL,E,EP,LABEL(2),LABELP(2),OTHER1(2),OTHER2(2), 1 WLVAC,CENTER,CONCEN, NELION,GAMMAR,GAMMAS,GAMMAW,REF, 2 NBLO,NBUP,ISO1,X1,ISO2,X2,GFLOG,XJ,XJP,CODE,ELO,GF,GS,GR,GW, 3 DWL,DGFLOG,DGAMMAR,DGAMMAS,DGAMMAW,EXTRA1,EXTRA2,EXTRA3 COMMON /NLINES/WLBEG,WLEND,RESOLU,RATIO,RATIOLG,WBEGIN, 1 LENGTH,MLINES,IXWLBEG COMMON /RHOX/RHOX(kw),NRHOX COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /TURBPR/VTURB(kw),PTURB(kw),TRBFDG,TRBCON,TRBPOW,TRBSND, 1 IFTURB COMMON /TXNXN/EMERGE(kw),TXNXN(kw),BSTIM(kw),XNFH2(kw) COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) common /elem/abund(99),atmass(99),elem(99) DIMENSION ABLOG(3,377),IFTP(kw),ABMIN(kw),MLINEJ(kw) DIMENSION ASYNTH(kw),ALINEC(kw),ASYNCONT(kw),ALINECONT(kw) DIMENSION DECKJ(7,kw) DIMENSION VELSHIFT(kw),HFIELD(kw) DIMENSION TITLE(74),IDMOL(60),MOMASS(60) REAL*8 FRQEDG(377),WLEDGE(377),CMEDGE(377),CONFRQ(1131) REAL*8 DELEDGE(377),HALFEDGE(377) REAL KAPPA0,KAPPA,KAPCEN,KAPMIN REAL*8 QT(kw),QTKEV(kw),QTK(kw),QHKT(kw),QTLOG(kw),QHCKT(kw) REAL*8 QP(kw),QXNE(kw),QXNATOM(kw),QRHO(kw),QRHOX(kw),QVTURB(kw) REAL*8 QXNFH(kw),QXNFHE(kw,2),QXNFH2(kw),QDOPPLE(mw6),QXNFPEL(mw6) REAL*8 QABLOG(1131),QXNFDOP(mw6),QCONGF C REAL*8 ASYNTH,ALINEC,TITLE,TEFF,GLOG,IDMOL,MOMASS REAL*8 TITLE,TEFF,GLOG,IDMOL,MOMASS dimension hfactor(kw),hefactor(kw),h2factor(kw) REAL*8 CONWAV,CONCM,WAVE REAL*8 LINDAT8(14) REAL*4 LINDAT4(28) EQUIVALENCE (LINDAT8(1),WL),(LINDAT4(1),NELION) REAL*8 RESOLU,RATIO,RATIOLG,SIGMA2,WLBEG,WLEND,WBEGIN REAL*8 EMERGE REAL*8 WL,E,EP,WLVAC,CENTER,CONCEN REAL*8 LABEL,LABELP,OTHER1,OTHER2 real*8 wavel C FASTEX(X)=EXTAB(IFIX(X)+1)* 1EXTABF(IFIX((X-FLOAT(IFIX(X)))*1000.+1.5)) C READ(93)NLINES,LENGTH,IFVAC,IFNLTE,N19,TURBV,DECKJ,IFPRED, 1WLBEG,WLEND,RESOLU,RATIO,RATIOLG,CUTOFF,LINOUT IXWLBEG=DLOG(WLBEG)/RATIOLG WBEGIN=DEXP(IXWLBEG*RATIOLG) IF(WBEGIN.LT.WLBEG)THEN IXWLBEG=IXWLBEG+1 WBEGIN=DEXP(IXWLBEG*RATIOLG) ENDIF CLOSE(UNIT=93,DISP='DELETE') OPEN(UNIT=10,STATUS='OLD',FORM='UNFORMATTED',READONLY,SHARED) OPEN(UNIT=12,STATUS='OLD',FORM='UNFORMATTED',ACCESS='APPEND') OPEN(UNIT=13,STATUS='NEW',FORM='UNFORMATTED') OPEN(UNIT=14,STATUS='OLD',FORM='UNFORMATTED',ACCESS='APPEND') OPEN(UNIT=19,STATUS='OLD',FORM='UNFORMATTED',ACCESS='APPEND') OPEN(UNIT=20,STATUS='OLD',FORM='UNFORMATTED',ACCESS='APPEND') IF(LINOUT.LT.0.)GO TO 3442 IF(N19.GT.0)THEN REWIND 20 DO 3440 I=1,N19 READ(20)LINDAT8,LINDAT4 3440 WRITE(13)LINDAT8,LINDAT4 ENDIF IF(NLINES.GT.0)THEN REWIND 14 DO 3441 I=1,NLINES READ(14)LINDAT8,LINDAT4 3441 WRITE(13)LINDAT8,LINDAT4 ENDIF 3442 CLOSE(UNIT=20,DISP='DELETE') CLOSE(UNIT=14,DISP='DELETE') OPEN(UNIT=14,TYPE='NEW',FORM='UNFORMATTED',RECORDTYPE='FIXED', 1ACCESS='DIRECT',BLOCKSIZE=LENREC*4,RECORDSIZE=LENREC) C DO 3456 I=1,1001 EXTAB(I)=EXP(-FLOAT(I-1)) 3456 EXTABF(I)=EXP(-FLOAT(I-1)*.001) DO 3457 I=1,2000 3457 E1TAB(I)=EXPI(1,FLOAT(I)*.01) C PRETABULATE VOIGT FUNCTION C 200 STEPS PER DOPPLER WIDTH VSTEPS=200. CALL TABVOIGT(VSTEPS,2001) C READ(10)NRHOX,TEFF,GLOG,TITLE WRITE(6,2000)TEFF,GLOG,TITLE 2000 FORMAT(6H TEFF=,F10.1,3X,5HGRAV=,F6.3,3X,74A1) READ(10)NEDGE,(FRQEDG(IEDGE),WLEDGE(IEDGE),CMEDGE(IEDGE), 1IEDGE=1,NEDGE),IDMOL,MOMASS READ(10)NCON,(CONFRQ(NU),NU=1,NCON) WLEDGE(1)=ABS(WLEDGE(1)) DO 2001 IEDGE=2,NEDGE WLEDGE(IEDGE)=ABS(WLEDGE(IEDGE)) HALFEDGE(IEDGE-1)=(WLEDGE(IEDGE-1)+WLEDGE(IEDGE))*.5 2001 DELEDGE(IEDGE-1)=(WLEDGE(IEDGE)-WLEDGE(IEDGE-1))**2*.5 C ITEMP=1 C READ(10)T,TKEV,TK,HKT,TLOG,HCKT,P,XNE,XNATOM,RHO,RHOX,VTURB, C 1XNFH,XNFHE,XNFH2 C ON VAX VARIABLES ARE READ REAL*8 AND CONVERTED TO REAL*4 READ(10)QT,QTKEV,QTK,QHKT,QTLOG,QHCKT,QP,QXNE,QXNATOM,QRHO, 1QRHOX,QVTURB,QXNFH,QXNFHE,QXNFH2 DO 2010 J=1,NRHOX T(J)=QT(J) TKEV(J)=QTKEV(J) TK(J)=QTK(J) HKT(J)=QHKT(J) TLOG(J)=QTLOG(J) HCKT(J)=QHCKT(J) P(J)=QP(J) XNE(J)=QXNE(J) XNATOM(J)=QXNATOM(J) RHO(J)=QRHO(J) RHOX(J)=QRHOX(J) VTURB(J)=QVTURB(J) XNFH(J)=QXNFH(J) XNFHE(J,1)=QXNFHE(J,1) XNFHE(J,2)=QXNFHE(J,2) 2010 XNFH2(J)=QXNFH2(J) C DO 2011 J=1,kw VELSHIFT(J)=DECKJ(1,J) HFIELD(J)=DECKJ(2,J) 2011 CONTINUE C WRITE(9)WLBEG,RESOLU,WLEND,LENGTH,NRHOX,LINOUT,TURBV,IFVAC WRITE(9)NEDGE,(FRQEDG(IEDGE),WLEDGE(IEDGE),CMEDGE(IEDGE), 1IEDGE=1,NEDGE),IDMOL,MOMASS C ILINES=0 N12=NLINES NLINES=NLINES+N19 IREC=0 DO 500 J=1,NRHOX REWIND 12 C INITIALIZE BUFFER DO 210 NBUFF=1,LENGTH 210 BUFFER(NBUFF)=0. READ(10)QABLOG READ(10) READ(10) NU=0 DO 2002 IEDGE=1,NEDGE-1 NU=NU+1 ABLOG(1,IEDGE)=QABLOG(NU) NU=NU+1 ABLOG(2,IEDGE)=QABLOG(NU) NU=NU+1 2002 ABLOG(3,IEDGE)=QABLOG(NU) IEDGE=1 DO 2005 NBUFF=1,LENGTH WAVE=WBEGIN*RATIO**(NBUFF-1) 2003 IF(WAVE.LT.WLEDGE(IEDGE+1))GO TO 2005 IEDGE=IEDGE+1 GO TO 2003 2005 CONTINUUM(NBUFF)= 1((WAVE-HALFEDGE(IEDGE))*(WAVE-WLEDGE(IEDGE+1))*ABLOG(1,IEDGE)+ 2 (WLEDGE(IEDGE)-WAVE)*(WAVE-WLEDGE(IEDGE+1))*2.*ABLOG(2,IEDGE)+ 3 (WAVE-WLEDGE(IEDGE))*(WAVE-HALFEDGE(IEDGE))*ABLOG(3,IEDGE))/ 4 DELEDGE(IEDGE) DO 2006 NBUFF=1,LENGTH 2006 CONTINUUM(NBUFF)=10.**CONTINUUM(NBUFF) C READ(10)QXNFPEL,QDOPPLE WRITE(28,2828)J,QXNFPEL 2828 FORMAT(I5/(1P6E21.14)) C IF(IFTP(J).EQ.0)GO TO 400 XNFPH(J,1)=QXNFPEL(1) XNFPH(J,2)=QXNFPEL(2) XNFPHE(J,1)=QXNFPEL(7) XNFPHE(J,2)=QXNFPEL(8) XNFPHE(J,3)=QXNFPEL(9) DO 203 NELION=1,mw6 XNFPEL(NELION)=0. C PATCH FOR NLTE HELIUM WHERE CAN GET OVERFLOW ON VAX C NLTE HELIUM IS NOT COMPUTED BY SYNTHE IN ANY CASE IF(QXNFPEL(NELION).LT.1.D25)XNFPEL(NELION)=QXNFPEL(NELION) 203 CONTINUE DO 205 NELION=1,mw6 QDOPPLE(NELION)=SQRT(QDOPPLE(NELION)**2+(TURBV/299792.458D0)**2) DOPPLE(NELION)=QDOPPLE(NELION) C PROBLEMS WITH OVERFLOW XNFPEL(NELION)=XNFPEL(NELION)/RHO(J) QXNFDOP(NELION)=QXNFPEL(NELION)/QRHO(J)/QDOPPLE(NELION) 205 XNFDOP(NELION)=QXNFDOP(NELION) TXNXN(J)=(XNFH(J)+.42D0*XNFHE(J,1)+.85D0*XNFH2(J))* 1(T(J)/10000.D0)**.3 C C DOPPLER SHIFT IN POINT NUMBERS NVSHIFT=RESOLU*VELSHIFT(J)/299792.458D0+.5D0 WRITE(6,215)J,VELSHIFT(J),NVSHIFT 215 FORMAT(I5,' VELOCITY SHIFT',F9.3,I7) C ADD LINES TO BUFFER MLINES=0 IF(N19.GT.0)CALL XLINOP(J,N19,CUTOFF,VELSHIFT(J),IFVAC,LINOUT) IF(N12.EQ.0)GO TO 400 N191=N19+1 alpha=0. DO 350 ILINE=N191,NLINES READ(12)NBUFF,CONGF,NELION,ELO,GAMRF,GAMSF,GAMWF c c include Barklem, Anstee, and O'Mara van der Waals c READ(12)NBUFF,CONGF,NELION,ELO,GAMRF,GAMSF,GAMWF,alpha c QCONGF=CONGF KAPPA0=CONGF*QXNFDOP(NELION) C KAPPA0=CONGF*XNFDOP(NELION) C PROBLEMS WITH OVERFLOW ON VAX C KAPPA0=CONGF/DOPPLE(NELION)*XNFPEL(NELION) KAPMIN=CONTINUUM(MIN(MAX(NBUFF,1),LENGTH))*CUTOFF IF(KAPPA0.LT.KAPMIN)GO TO 350 KAPPA0=KAPPA0*FASTEX(ELO*HCKT(J)) C KAPPA0=KAPPA0*EXP(-ELO*HCKT(J)) IF(KAPPA0.LT.KAPMIN)GO TO 350 C c Castelli for Barklem, Anstee, and O'mara van der Waals broadening if(alpha.ne.0.)then nelem=int(nelion/6)+1 v2=(1.-alpha)/2 wavel=wbegin*ratio**(nbuff-1) type*,wavel,nelem,alpha,v2 hfactor(j)=(t(j)/10000.)**v2 hefactor(j)=0.628*(2.0991D-4*T(j)*(1/4+1.008/atmass(nelem)))**v2 h2factor(j)=1.08*(2.0991D-4*T(j)*(1/2+1.008/atmass(nelem)))**v2 txnxn(j)=xnfh(j)*hfactor(j)+xnfhe(J,1)*hefactor(j)+xnfh2(j)*h2factor(j) endif c C VOIGT APPROXIMATION ACCURATE ONLY TO ADAMP**2 ADAMP=(GAMRF+GAMSF*XNE(J)+GAMWF*TXNXN(J))/DOPPLE(NELION) NBUFF=NBUFF+NVSHIFT IF(NBUFF.LT.1.OR.NBUFF.GT.LENGTH)GO TO 320 MLINES=MLINES+1 IF(ADAMP.LT..2)THEN KAPCEN=KAPPA0*(1.-1.128*ADAMP) ELSE KAPCEN=KAPPA0*VOIGT(0.,ADAMP) ENDIF IF(LINOUT.GE.0)WRITE(15)ILINE,KAPCEN BUFFER(NBUFF)=BUFFER(NBUFF)+KAPCEN C PROFILE INSIDE 10 DOPPLER WIDTHS 320 N10DOP=10.*(DOPPLE(NELION)*RESOLU) IF(ADAMP.LT..2)THEN TABSTEP=VSTEPS/(DOPPLE(NELION)*RESOLU) TABI=1.5 DO 321 NSTEP=1,N10DOP TABI=TABI+TABSTEP PROFILE(NSTEP)=KAPPA0*(H0TAB(IFIX(TABI))+ADAMP*H1TAB(IFIX(TABI))) IF(PROFILE(NSTEP).LT.KAPMIN)GO TO 323 321 CONTINUE ELSE DVOIGT=1./DOPPLE(NELION)/RESOLU DO 1321 NSTEP=1,N10DOP PROFILE(NSTEP)=KAPPA0*VOIGT(FLOAT(NSTEP)*DVOIGT,ADAMP) IF(PROFILE(NSTEP).LT.KAPMIN)GO TO 323 1321 CONTINUE ENDIF C FAR WINGS X=PROFILE(N10DOP)*FLOAT(N10DOP)**2 MAXSTEP=SQRT(X/KAPMIN)+1. MAXSTEP=MIN(MAXSTEP,MAXPROF) N1=N10DOP+1 DO 322 NSTEP=N1,MAXSTEP 322 PROFILE(NSTEP)=X/FLOAT(NSTEP)**2 NSTEP=MAXSTEP 323 IF(NBUFF+NSTEP.LT.1.OR.NBUFF-NSTEP.GT.LENGTH)GO TO 350 IF(NBUFF.GE.LENGTH)GO TO 325 C RED WING MAXRED=MIN0(LENGTH-NBUFF,NSTEP) MINRED=MAX0(1,1-NBUFF) DO 324 ISTEP=MINRED,MAXRED 324 BUFFER(NBUFF+ISTEP)=BUFFER(NBUFF+ISTEP)+PROFILE(ISTEP) IF(NBUFF.LE.1)GO TO 350 C BLUE WING 325 MAXBLUE=MIN0(NBUFF-1,NSTEP) MINBLUE=MAX0(1,NBUFF-LENGTH) DO 326 ISTEP=MINBLUE,MAXBLUE 326 BUFFER(NBUFF-ISTEP)=BUFFER(NBUFF-ISTEP)+PROFILE(ISTEP) 350 CONTINUE C 400 CONTINUE C MEMORY TRANSPOSITION C DO 26 I=1,LENGTH C 26 TRANSP(I,J)=BUFFER(I) C DIRECT IO TRANSPOSITION NUMREC=(LENGTH+LENREC-1)/LENREC DO 26 NBEG=1,LENGTH,LENREC IREC=IREC+1 NEND=NBEG+LENREC-1 WRITE(14,REC=IREC)(BUFFER(I),I=NBEG,NEND) 26 CONTINUE WRITE(6,499)J,MLINES 499 FORMAT(30X,2I10,' LINES USED') MLINEJ(J)=MLINES ILINES=ILINES+MLINES 500 CONTINUE WRITE(6,106)ILINES 106 FORMAT(I10) C C DIRECT IO TRANSPOSITION N9=0 DO 99 N=1,NUMREC WRITE(6,106)N DO 93 J=1,NRHOX IREC=J*NUMREC-NUMREC+N READ(14,REC=IREC)(TRANSP(J,I),I=1,LENREC) 93 CONTINUE NOUT=LENREC LASTREC=LENGTH-NUMREC*LENREC+LENREC IF(N.EQ.NUMREC)NOUT=LASTREC DO 95 I=1,NOUT N9=N9+1 WAVE=WBEGIN*RATIO**(N9-1) FREQ=2.99792458D17/WAVE DO 94 J=1,NRHOX 94 ASYNTH(J)=TRANSP(J,I)*(1.-EXP(-FREQ*HKT(J))) WRITE(29,2929)WAVE,(ASYNTH(J),J=1,NRHOX) 2929 FORMAT(F15.8/(1P8E15.7)) 95 WRITE(9)ASYNTH 99 CONTINUE C N9=LENGTH IS A CHECK THAT THE TRANSPOSITION WORKED PROPERLY WRITE(6,96)N9 96 FORMAT(I10,27H OPACITY VECTORS ON TAPE 9 ) C C SAVE ALL LINES USED N9=0 IF(NLINES.EQ.0)GO TO 810 IF(LINOUT.LT.0)GO TO 810 DO 800 I=1,NLINES 800 LINE(I)=0 IF(ILINES.EQ.0)GO TO 810 REWIND 15 I=0 803 I=I+1 READ(15)ILINE LINE(ILINE)=1 IF(I.LT.ILINES)GO TO 803 REWIND 13 REWIND 7 DO 809 I=1,NLINES READ(13)LINDAT8,LINDAT4 IF(LINE(I).EQ.0)GO TO 809 LINE(I)=0 WRITE(7)LINDAT8,LINDAT4 N9=N9+1 LINE(I)=N9 809 CONTINUE 810 WRITE(6,106)N9 WRITE(8)N9 WRITE(9)N9 CLOSE(UNIT=12,DISP='DELETE') CLOSE(UNIT=13,DISP='DELETE') C C SET UP LINE CENTER OPACITY FOR EACH LINE IF(ILINES.EQ.0)CALL EXIT IF(LINOUT.LT.0)CALL EXIT REWIND 15 IREC=0 DO 830 J=1,NRHOX MAXLINE=MLINEJ(J) C WRITE(6,817)J,MAXLINE 817 FORMAT(3I10) K=0 JOUT=0 IF(MAXLINE.EQ.0)GO TO 820 I9LAST=0 DO 815 L=1,MAXLINE READ(15)ILINE,KAPCEN I9=LINE(ILINE) IF(I9.EQ.0)GO TO 815 NSKIP=I9-I9LAST-1 IF(NSKIP.EQ.0)GO TO 811 DO 812 ISKIP=1,NSKIP K=K+1 RECORD(K)=0. JOUT=JOUT+1 IF(K.LT.LENREC)GO TO 812 IREC=IREC+1 WRITE(14,REC=IREC)RECORD K=0 812 CONTINUE 811 I9LAST=I9 K=K+1 JOUT=JOUT+1 RECORD(K)=KAPCEN IF(K.LT.LENREC)GO TO 815 IREC=IREC+1 WRITE(14,REC=IREC)RECORD K=0 815 CONTINUE NSKIP=N9-I9LAST IF(NSKIP.EQ.0)GO TO 825 GO TO 821 820 NSKIP=N9 821 DO 822 ISKIP=1,NSKIP K=K+1 JOUT=JOUT+1 RECORD(K)=0. IF(K.LT.LENREC)GO TO 822 IREC=IREC+1 WRITE(14,REC=IREC)RECORD K=0 822 CONTINUE 825 IF(K.EQ.0)GO TO 830 IREC=IREC+1 WRITE(14,REC=IREC)RECORD K=0 830 WRITE(6,817)J,MAXLINE,JOUT C C TRANSPOSE IF(N9.LE.MAXLIN)GO TO 808 WRITE(6,877) 877 FORMAT(28H TOO MANY LINES TO TRANSPOSE) CALL EXIT 808 CONTINUE REWIND 7 NUMREC=(N9+LENREC-1)/LENREC NLAST=N9-NUMREC*LENREC+LENREC NCEN=0 DO 899 N=1,NUMREC WRITE(6,106)N DO 893 J=1,NRHOX IREC=J*NUMREC-NUMREC+N READ(14,REC=IREC)(TRANSP(J,I),I=1,LENREC) 893 CONTINUE NOUT=LENREC IF(N.EQ.NUMREC)NOUT=NLAST DO 895 I=1,NOUT NCEN=NCEN+1 READ(7)LINDAT8,LINDAT4 FREQ=2.99792458D17/WLVAC DO 897 J=1,NRHOX 897 ALINEC(J)=TRANSP(J,I)*(1.-EXP(-FREQ*HKT(J))) 895 WRITE(9)LINDAT8,LINDAT4,ALINEC 899 CONTINUE CLOSE(UNIT=7,DISP='DELETE') CLOSE(UNIT=15,DISP='DELETE') CLOSE(UNIT=14,DISPOSE='DELETE') WRITE(6,96)NCEN CALL EXIT END SUBROUTINE XLINOP(J,N19,CUTOFF,VELSHIFT,IFVAC,LINOUT) PARAMETER (kw=99,mw=139,mw6=mw*6) PARAMETER (LENREC=8000,MAXLEN=2000001,MAXPROF=10000, 1 MAXBUFF=MAXLEN+MAXPROF,MAXLIN=MAXBUFF+MAXPROF*2) COMMON /BUFFER/BUFFER(MAXBUFF),PROFILE(MAXPROF) COMMON /CONTIN/CONTINUUM(MAXBUFF) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) COMMON /EXTAB/EXTAB(1001),EXTABF(1001),E1TAB(2000) COMMON /NLINES/WLBEG,WLEND,RESOLU,RATIO,RATIOLG,WBEGIN, 1 LENGTH,MLINES,IXWLBEG COMMON /RHOX/RHOX(kw),NRHOX COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /TURBPR/VTURB(kw),PTURB(kw),TRBFDG,TRBCON,TRBPOW,TRBSND, 1 IFTURB COMMON /TXNXN/EMERGE(kw),TXNXN(kw),BSTIM(kw),XNFH2(kw) COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) common /elem/abund(99),atmass(99),elem(99) dimension hfactor(kw),hefactor(kw),h2factor(kw) REAL NSTARK,NDOPP,NMERGE,INGLIS EQUIVALENCE (GAMMAS,ASHORE),(GAMMAW,BSHORE) EQUIVALENCE (GF,G,CGF),(TYPE,NLAST),(GAMMAR,XSECT,GAUNT) INTEGER TYPE REAL KAPPA,KAPMIN,KAPPA0,KAPCEN REAL KAPPA0RED,KAPPARED,KAPPA0BLUE,KAPPABLUE REAL*8 WAVE,WCON,EMERGE,WMERGE,WSHIFT,CONTX(26,17),WTAIL REAL*8 RESOLU,RATIO,RATIOLG,SIGMA2,WLBEG,WLEND c error 7jun2012 velshift is real*4 C REAL*8 WL,DOPRATIO,VELSHIFT,WBEGIN,EMERGEH(kw) REAL*8 WL,DOPRATIO,WBEGIN,EMERGEH(kw) REAL*8 BLUECUT,WLPLUS1,WLPLUS2,REDCUT,WLMINUS1,WLMINUS2,VACAIR REAL*8 EHYD(100),CONTH(15) ,ALPHAHYD(99) DIMENSION DOPPH(kw) DATA CONTH/ 1 109678.764D0,27419.659D0,12186.462D0,6854.871,4387.113D0, 1.00 2 3046.604D0,2238.320D0,1713.711D0,1354.044D0,1096.776D0, 3 906.426D0,761.650D0,648.980D0,559.579D0,487.456D0/ DATA CONTX/ 1 109678.764D0,27419.659D0,12186.462D0,6854.871D0,4387.113D0, 1.00 2 3046.604D0,2238.320D0,1713.711D0,1354.044D0,1096.776D0,16*0., 3 198310.760D0,38454.691D0,32033.214D0,29223.753D0,27175.760D0, 2.00 4 15073.868D0,0.,0.,0.,0.,16*0., 5 438908.850D0,109726.529D0,48766.491D0,27430.925D0,17555.715D0, 2.01 6 12191.437D0,0.,0.,0.,0.,16*0., 7 90883.840D0,90867.420D0,90840.420D0,90820.420D0,90804.000D0, 6.00 8 90777.000D0,80691.180D0,80627.760D0,69235.820D0,69172.400D0, 9 16*0., 26*0., 6.01 A 61671.020D0,39820.615D0,39800.556D0,39759.842D0,22*0., 12.00 1 26*0., 12.01 2 48278.370D0,48166.309D0,0.,0.,0.,0.,0.,0.,0.,0.,16*0., 13.00 3 0.,0.,0.,0.,0.,0.,0.,0.,0.,0.,16*0., 13.01 4 66035.000D0,65957.885D0,65811.843D0,65747.550D0,65670.435D0, 14.00 5 65524.393D0,59736.150D0,59448.700D0,50640.630D0,50553.180D0, 6 16*0., 26*0., 14.01 7 26*0.,26*0., 20.00,01 8 26*0.,26*0., 8.,11. 9 26*0.,26*0./ 5.,19. DATA ITEMP1/0/ C FASTEX(X)=EXTAB(IFIX(X)+1)* 1EXTABF(IFIX((X-FLOAT(IFIX(X)))*1000.+1.5)) C IF(ITEMP.EQ.ITEMP1)GO TO 95 EHYD(1)=0.D0 EHYD(2)=82259.105D0 EHYD(3)=97492.302D0 EHYD(4)=102823.893D0 EHYD(5)=105291.651D0 EHYD(6)=106632.160D0 EHYD(7)=107440.444D0 EHYD(8)=107965.051D0 DO 1 N=9,100 1 EHYD(N)=109678.764D0-109677.576D0/N**2 DO 2 N=1,99 2 ALPHAHYD(N)=1.D7/(EHYD(N+1)-EHYD(N)) WRITE(6,90) 90 FORMAT(' NMERGE EMERGE EMERGEH') DO 91 K=1,NRHOX C FOR NEUTRALS FOR IONS NSTARK=NSTARK*Z**.25 NDOPP=NDOPP*Z**(2./3.) C EMERGE=EMERGE*Z**2 C INGLIS=1194./XNE(K)**.125 C EMPIRICAL INGLIS=1600./XNE(K)**(2./15.) C NMERGE=INGLIS+.5 NMERGE=INGLIS-1.5 EMERGE(K)=109737.312D0/NMERGE**2 EMERGEH(K)=109677.576D0/NMERGE**2 91 WRITE(6,92)K,NMERGE,EMERGE(K),EMERGEH(K) 92 FORMAT(I3,4F10.3) ITEMP1=ITEMP C 95 BOLT=1. BOLTH=1. OLDELO=1.E30*FLOAT(J*ITEMP) OLDELOH=1.E30*FLOAT(J*ITEMP) DOPRATIO=1.D0+VELSHIFT/299792.458D0 alpha=0 REWIND 19 DO 900 ILINE=1,N19 READ(19)WL,ELO,GF,NBLO,NBUP,NELION,TYPE,NCON,NELIONX, 1GAMMAR,GAMMAS,GAMMAW,NBUFF c c include Barklem, Anstee, and O'Mara van der Waals c READ(19)WL,ELO,GF,NBLO,NBUP,NELION,TYPE,NCON,NELIONX, c 1GAMMAR,GAMMAS,GAMMAW,alpha,NBUFF c WL=WL*DOPRATIO 97 IF(TYPE.EQ.2)GO TO 500 IF(TYPE.EQ.0)GO TO 200 IF(TYPE.EQ.-1)GO TO 600 IF(TYPE.EQ.-2)GO TO 600 IF(TYPE.EQ.1)GO TO 700 IF(TYPE.EQ.3)GO TO 300 C HE LINES DO NOT WORK YET IF(TYPE.LT.-2)GO TO 200 C C MERGED CONTINUUM C EDGE WAVELENGTHS ARE IN VACUUM WSHIFT=1.D7/(1.D7/WL-109737.312D0/NLAST**2) WMERGE=1.D7/(1.D7/WL-EMERGE(J)) IF(NELION.EQ.1)THEN WSHIFT=1.D7/(1.D7/WL-109677.576D0/NLAST**2) WMERGE=1.D7/(1.D7/WL-EMERGEH(J)) ENDIF IF(WMERGE.LT.0.)WMERGE=WSHIFT+WSHIFT WMERGE=MAX(WMERGE,WSHIFT) WMERGE=MIN(WSHIFT+WSHIFT,WMERGE) WTAIL=1.D7/(1.D7/WMERGE-500.) IF(WTAIL.LT.0.)WTAIL=WMERGE+WMERGE WTAIL=MIN(WMERGE+WMERGE,WTAIL) IF(IFVAC.EQ.0)THEN WMERGE=VACAIR(WMERGE)*DOPRATIO WTAIL=VACAIR(WTAIL)*DOPRATIO ENDIF IXWL= LOG(WL)/RATIOLG EDGEBLUE=EXP(IXWL*RATIOLG) IF(EDGEBLUE.GT.WL)IXWL=IXWL-1 NBUFF1=IXWL+1-IXWLBEG+1 IXWL= LOG(WMERGE)/RATIOLG+.5 NBUFF2=IXWL-IXWLBEG+1 IXWL= LOG(WTAIL)/RATIOLG+.5 NBUFF3=IXWL-IXWLBEG+1 IF(NBUFF1.GT.LENGTH)GO TO 900 IF(NBUFF3.LT.1)GO TO 900 DNBUFF=NBUFF3-NBUFF2 NBUFF1=MAX0(NBUFF1,1) XSECTG=GF C KAPPA=XSECTG*XNFPEL(NELION)*EXP(-ELO*HCKT(J)) IF(NELION.GT.1)KAPPA=XSECTG*XNFPEL(NELION)*FASTEX(ELO*HCKT(J)) IF(NELION.EQ.1)KAPPA=XSECTG*XNFPEL(NELION)* 1FASTEX(ELO*HCKT(J)) TAIL=1. DO 190 IBUFF=NBUFF1,MIN0(NBUFF3,LENGTH) IF(IBUFF.GT.NBUFF2)TAIL=(NBUFF3-IBUFF)/DNBUFF 190 BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA*TAIL C C added 28 Mar 2015 to save the continuum edges IF(LINOUT.GE.0)WRITE(15)ILINE,KAPPA C added 7 Apr 2015 MLINES=MLINES+1 C GO TO 900 C C NORMAL LINE C 200 KAPPA0=CGF*XNFPEL(NELION)/DOPPLE(NELION) 200 KAPPA0=CGF*XNFDOP(NELION) KAPMIN=CONTINUUM(MIN(MAX(NBUFF,1),LENGTH))*CUTOFF IF(KAPPA0.LT.KAPMIN)GO TO 900 IF(ELO.EQ.OLDELO)GO TO 210 C BOLT=EXP(-ELO*HCKT(J)) BOLT=FASTEX(ELO*HCKT(J)) OLDELO=ELO 210 KAPPA0=KAPPA0*BOLT IF(KAPPA0.LT.KAPMIN)GO TO 900 MLINES=MLINES+1 WCON=0. WTAIL=0. IF(NCON.GT.0)THEN WCON=1.E7/(CONTX(NCON,NELIONX)-EMERGE(J))*DOPRATIO WTAIL=1.E7/(CONTX(NCON,NELIONX)-EMERGE(J)-500.)*DOPRATIO ENDIF c c Castelli for Barklem, Anstee, and O'Mara van der Waals broadenint if(alpha.ne.0.)then nelem=int(nelion/6)+1 v2=(1.-alpha)/2 hfactor(j)=(t(j)/10000.)**v2 hefactor(j)=0.628*(2.0991D-4*T(j)*(1/4+1.008/atmass(nelem)))**v2 h2factor(j)=1.08*(2.0991D-4*T(j)*(1/2+1.008/atmass(nelem)))**v2 txnxn(j)=xnfh(j)*hfactor(j)+xnfhe(J,1)*hefactor(j)+xnfh2(j)* 1h2factor(j) endif c ADAMP=(GAMMAR+GAMMAS*XNE(J)+GAMMAW*TXNXN(J))/DOPPLE(NELION) KAPCEN=KAPPA0*VOIGT(0.,ADAMP) IF(LINOUT.GE.0)WRITE(15)ILINE,KAPCEN DOPWL=DOPPLE(NELION)*WL IF(WL.GT.WLEND)GO TO 213 C RED WING MINRED=MAX0(1,NBUFF) WAVE=WBEGIN*RATIO**(MINRED-1) DO 211 IBUFF=MINRED,LENGTH IF(WAVE.LT.WCON)GO TO 211 VVOIGT=ABS(WAVE-WL)/DOPWL KAPPA=KAPPA0*VOIGT(VVOIGT,ADAMP) IF(WAVE.LT.WTAIL)KAPPA=KAPPA*(WAVE-WCON)/(WTAIL-WCON) C bug from john lester 23Jun03 C BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA C IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 212 IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 212 BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA 211 WAVE=WAVE*RATIO 212 IF(MINRED.EQ.1)GO TO 900 IF(WL.LT.WBEGIN)GO TO 900 C BLUE WING 213 IBUFF=MIN0(LENGTH+1,NBUFF) MAXBLUE=IBUFF-1 WAVE=WBEGIN*RATIO**(IBUFF-1) DO 214 I=1,MAXBLUE IBUFF=IBUFF-1 WAVE=WAVE/RATIO IF(WAVE.LT.WCON)GO TO 214 VVOIGT=ABS(WAVE-WL)/DOPWL KAPPA=KAPPA0*VOIGT(VVOIGT,ADAMP) C KAPPA=KAPPA0*VOIGT(ABS(WAVE-WL)/DOPWL,ADAMP) IF(WAVE.LT.WTAIL)KAPPA=KAPPA*(WAVE-WCON)/(WTAIL-WCON) BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 900 214 CONTINUE GO TO 900 C C PRD LINE 300 GO TO 200 C C CORONAL LINE 500 GO TO 900 C C HYDROGEN LINE C 600 KAPPA0=CGF*XNFPEL(1)/DOPPLE(1) 600 KAPPA0=CGF*XNFDOP(1) KAPMIN=CONTINUUM(MIN(MAX(NBUFF,1),LENGTH))*CUTOFF IF(NBUP.EQ.2)KAPMIN=CONTINUUM(LENGTH)*CUTOFF IF(KAPPA0.LT.KAPMIN)GO TO 900 C IF(ELO.EQ.OLDELOH)GO TO 610 C BOLTH=EXP(-ELO*HCKT(J)) BOLTH=FASTEX(ELO*HCKT(J)) OLDELOH=ELO DOPPH(J)=DOPPLE(1) C DEUTERIUM IF(TYPE.EQ.-2)DOPPH(J)=DOPPH(J)/1.4142D0 610 KAPPA0=KAPPA0*BOLTH IF(KAPPA0.LT.KAPMIN)GO TO 900 IF(LINOUT.GE.0)WRITE(15)ILINE,KAPPA0 MLINES=MLINES+1 IF(NCON.EQ.0)GO TO 620 IF(NBUP.EQ.NBLO+1)GO TO 620 IF(NBUP.EQ.NBLO+2)GO TO 630 WSHIFT=1.D7/(CONTH(NCON)-109677.576D0/81.D0**2) WMERGE=1.D7/(CONTH(NCON)-EMERGEH(J)) IF(WMERGE.LT.0.)WMERGE=WSHIFT+WSHIFT WCON=MAX(WSHIFT,WMERGE) WTAIL=1.D7/(1.D7/WCON-500.D0) WCON=MIN(WSHIFT+WSHIFT,WCON) IF(WTAIL.LT.0.)WTAIL=WCON+WCON WTAIL=MIN(WCON+WCON,WTAIL) IF(IFVAC.EQ.0)THEN WCON=VACAIR(WCON) WTAIL=VACAIR(WTAIL) ENDIF WCON=WCON*DOPRATIO IF(IFVAC.EQ.0)WL=VACAIR(1.D7/(EHYD(NBUP)-EHYD(NBLO)))*DOPRATIO IF(WL.GT.WLEND)GO TO 613 C RED WING IF(WBEGIN.GT.ALPHAHYD(NBLO))GO TO 613 REDCUT=1.D7/(109678.764D0-109677.576D0/(NBUP-0.8D0)**2-EHYD(NBLO)) IF(IFVAC.EQ.0)REDCUT=VACAIR(REDCUT) REDCUT=REDCUT*DOPRATIO WLMINUS1=1.D7/(EHYD(NBUP-1)-EHYD(NBLO)) IF(IFVAC.EQ.0)WLMINUS1=VACAIR(WLMINUS1) WLMINUS1=WLMINUS1*DOPRATIO WLMINUS2=1.D7/(EHYD(NBUP-2)-EHYD(NBLO)) IF(IFVAC.EQ.0)WLMINUS2=VACAIR(WLMINUS2) WLMINUS2=WLMINUS2*DOPRATIO KAPPA0RED=KAPPA0*HFNM(NBLO,NBUP-2)/HFNM(NBLO,NBUP)/ 1 (EHYD(NBUP-2)-EHYD(NBLO))*(EHYD(NBUP)-EHYD(NBLO)) MINRED=MAX0(1,NBUFF) WAVE=WBEGIN*RATIO**(MINRED-1) DO 611 IBUFF=MINRED,LENGTH IF(WAVE.LT.WCON)GO TO 611 IF(WAVE.GT.WLMINUS1)GO TO 612 KAPPA=KAPPA0*HPROF4(NBLO,NBUP,J,WAVE-WL,DOPPH) IF(WAVE.LT.WTAIL)KAPPA=KAPPA*(WAVE-WCON)/(WTAIL-WCON) IF(WAVE.GT.REDCUT)THEN KAPPARED=KAPPA0RED*HPROF4(NBLO,NBUP-2,J,WAVE-WLMINUS2,DOPPH) IF(WAVE.LT.WTAIL)KAPPARED=KAPPARED*(WAVE-WCON)/(WTAIL-WCON) IF(KAPPARED.GE.KAPPA)GO TO 612 ENDIF BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 612 611 WAVE=WAVE*RATIO 612 IF(MINRED.EQ.1)GO TO 900 IF(WL.LT.WBEGIN)GO TO 900 C BLUE WING 613 BLUECUT=1.D7/(109678.764D0-109677.576D0/(NBUP+0.8D0)**2- 1 EHYD(NBLO)) IF(IFVAC.EQ.0)BLUECUT=VACAIR(BLUECUT) BLUECUT=BLUECUT*DOPRATIO WLPLUS1=1.D7/(EHYD(NBUP+1)-EHYD(NBLO)) IF(IFVAC.EQ.0)WLPLUS1=VACAIR(WLPLUS1) WLPLUS1=WLPLUS1*DOPRATIO WLPLUS2=1.D7/(EHYD(NBUP+2)-EHYD(NBLO)) IF(IFVAC.EQ.0)WLPLUS2=VACAIR(WLPLUS2) WLPLUS2=WLPLUS2*DOPRATIO KAPPA0BLUE=KAPPA0*HFNM(NBLO,NBUP+2)/HFNM(NBLO,NBUP)/ 1 (EHYD(NBUP+2)-EHYD(NBLO))*(EHYD(NBUP)-EHYD(NBLO)) IBUFF=MIN0(LENGTH+1,NBUFF) MAXBLUE=IBUFF-1 WAVE=WBEGIN*RATIO**(IBUFF-1) DO 614 I=1,MAXBLUE IBUFF=IBUFF-1 WAVE=WAVE/RATIO IF(WAVE.LT.WCON)GO TO 900 IF(WAVE.LT.WLPLUS1)GO TO 900 KAPPA=KAPPA0*HPROF4(NBLO,NBUP,J,WAVE-WL,DOPPH) IF(WAVE.LT.WTAIL)KAPPA=KAPPA*(WAVE-WCON)/(WTAIL-WCON) IF(WAVE.LT.BLUECUT)THEN KAPPABLUE=KAPPA0BLUE*HPROF4(NBLO,NBUP+2,J,WAVE-WLPLUS2,DOPPH) IF(WAVE.LT.WTAIL)KAPPABLUE=KAPPABLUE*(WAVE-WCON)/(WTAIL-WCON) IF(KAPPABLUE.GT.KAPPA)GO TO 900 ENDIF BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 900 614 CONTINUE GO TO 900 C ALPHA PRESUMED ISOLATED LINES AND BETA BLUE WINGS 620 IF(WL.GT.WLEND)GO TO 623 C RED WING MINRED=MAX0(1,NBUFF) WAVE=WBEGIN*RATIO**(MINRED-1) DO 621 IBUFF=MINRED,LENGTH KAPPA=KAPPA0*HPROF4(NBLO,NBUP,J,WAVE-WL,DOPPH) BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 622 621 WAVE=WAVE*RATIO 622 IF(MINRED.EQ.1)GO TO 900 IF(WL.LT.WBEGIN)GO TO 900 C ALPHA OR BETA BLUE WING 623 IBUFF=MIN0(LENGTH+1,NBUFF) MAXBLUE=IBUFF-1 WAVE=WBEGIN*RATIO**(IBUFF-1) DO 624 I=1,MAXBLUE IBUFF=IBUFF-1 WAVE=WAVE/RATIO KAPPA=KAPPA0*HPROF4(NBLO,NBUP,J,WAVE-WL,DOPPH) BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 900 624 CONTINUE GO TO 900 C BETA LINES RED WING 630 IF(WL.GT.WLEND)GO TO 623 C RED WING MINRED=MAX0(1,NBUFF) WAVE=WBEGIN*RATIO**(MINRED-1) DO 631 IBUFF=MINRED,LENGTH IF(WAVE.GT.ALPHAHYD(NBLO))GO TO 633 KAPPA=KAPPA0*HPROF4(NBLO,NBUP,J,WAVE-WL,DOPPH) BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 622 631 WAVE=WAVE*RATIO GO TO 622 633 IBUFFALPHA=IBUFF IF(NBUFF.LT.1)GO TO 900 IBUFF=NBUFF MAXBLUE=IBUFF-1 WAVE=WBEGIN*RATIO**(IBUFF-1) DO 634 I=1,MAXBLUE IBUFF=IBUFF-1 WAVE=WAVE/RATIO KAPPA=KAPPA0*HPROF4(NBLO,NBUP,J,WAVE-WL,DOPPH) BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 900 634 CONTINUE GO TO 900 C C AUTOIONIZING LINE 700 KAPPA0=BSHORE*G*XNFPEL(NELION) KAPMIN=CONTINUUM(MIN(MAX(NBUFF,1),LENGTH))*CUTOFF IF(KAPPA0.LT.KAPMIN)GO TO 900 KAPPA0=KAPPA0*FASTEX(ELO*HCKT(J)) C KAPPA0=KAPPA0*EXP(-ELO*HCKT(J)) IF(KAPPA0.LT.KAPMIN)GO TO 900 IF(LINOUT.GE.0)WRITE(15)ILINE,KAPPA0 MLINES=MLINES+1 FRELIN=2.99792458D17/WL IF(WL.GT.WLEND)GO TO 713 C RED WING MINRED=MAX0(1,NBUFF) FREQ=2.99792458D17/(WBEGIN*RATIO**(MINRED-1)) DO 711 IBUFF=MINRED,LENGTH EPSIL=2.*(FREQ-FRELIN)/GAMMAR KAPPA=KAPPA0*(ASHORE*EPSIL+BSHORE)/(EPSIL**2+1.)/BSHORE BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 712 711 FREQ=FREQ/RATIO 712 IF(NBUFF.EQ.1)GO TO 900 IF(WL.LT.WBEGIN)GO TO 900 C BLUE WING 713 IBUFF=MIN0(LENGTH+1,NBUFF) MAXBLUE=IBUFF-1 FREQ=2.99792458D17/(WBEGIN*RATIO**(IBUFF-1)) DO 714 I=1,MAXBLUE IBUFF=IBUFF-1 FREQ=FREQ*RATIO EPSIL=2.*(FREQ-FRELIN)/GAMMAR KAPPA=KAPPA0*(ASHORE*EPSIL+BSHORE)/(EPSIL**2+1.)/BSHORE BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 900 714 CONTINUE GO TO 900 c c He I c C LINE=1 4471 C LINE=2 4026 C LINE=3 4387 C LINE=4 4921 C LINE>4 OTHERS 800 KAPPA0=CGF*XNFPEL(NELION)/DOPPLE(NELION) C 3HE IF(TYPE.EQ.-4)KAPPA0=KAPPA0/1.155 KAPMIN=CONTINUUM(MIN(MAX(NBUFF,1),LENGTH))*CUTOFF IF(KAPPA0.LT.KAPMIN)GO TO 900 BOLT=FASTEX(ELO*HCKT(J)) KAPPA0=KAPPA0*BOLT IF(KAPPA0.LT.KAPMIN)GO TO 900 c DOPWL=DOPPLE(7)*WL DOPWL=DOPPLE(7)*WL4 IF(TYPE.EQ.-4)DOPWL=DOPWL*1.155 c KAPCEN=KAPPA0*HE1PROF(J,WL,WL,DOPWL,GAMMAR,GAMMAS) KAPCEN=KAPPA0*HE1PROF(J,WL4,WL4,DOPWL,GAMMAR,GAMMAS) WRITE(15)ILINE,KAPCEN MLINES=MLINES+1 IF(WL.GT.WLEND)GO TO 813 C RED WING REDCUT=WLEND MINRED=MAX0(1,NBUFF) WAVE=WBEGIN*RATIO**(MINRED-1) wave4=wave DO 811 IBUFF=MINRED,LENGTH IF(WAVE.GT.REDCUT)GO TO 812 KAPPA=KAPPA0*HE1PROF(J,WAVE4,WL4,DOPWL,GAMMAR,GAMMAS) IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 812 BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA WAVE=WAVE*RATIO 811 wave4=wave 812 IF(NBUFF.EQ.1)GO TO 900 IF(WL.LT.WLBEG)GO TO 900 C BLUE WING 813 BLUECUT=WLBEG IBUFF=MIN0(LENGTH+1,NBUFF) MAXBLUE=IBUFF-1 WAVE=WBEGIN*RATIO**(IBUFF-1) DO 814 I=1,MAXBLUE IBUFF=IBUFF-1 WAVE=WAVE/RATIO wave4=wave IF(WAVE.LT.BLUECUT)GO TO 900 KAPPA=KAPPA0*HE1PROF(J,WAVE4,WL4,DOPWL,GAMMAR,GAMMAS) BUFFER(IBUFF)=BUFFER(IBUFF)+KAPPA IF(KAPPA.LT.CONTINUUM(IBUFF)*CUTOFF)GO TO 900 814 CONTINUE GO TO 900 850 CONTINUE 900 CONTINUE RETURN END FUNCTION HPROF4(N,M,J,DELW,DOPPH) C FUNCTION HPROFL(N,M,J,DELW) C VERSION FINE STRUCTURE LIKE GENERAL BUT APPROXIMATELY INCLUDES FINE C STRUCTURE IN THE DOPPLER CORES. EXACT PATTERN C IS USED FOR ALPHA LINES, M INFINITE PATTERN C IS USED FOR ALL OTHER LINES. C FROM DEANE PETERSON C REQUIRES VCSE1F AND SOFBET PARAMETER (kw=99,mw=139,mw6=mw*6) REAL*8 DELW,EMERGE REAL*4 DOPPH(kw) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) COMMON /RHOX/RHOX(kw),NRHOX COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /TXNXN/EMERGE(kw),TXNXN(kw),BSTIM(kw),XNFH2(kw) COMMON /EXTAB/EXTAB(1001),EXTABF(1001),E1TAB(2000) DIMENSION PP(kw),FO(kw),GCON1(kw),GCON2(kw),Y1B(kw),Y1S(kw), 1C1D(kw),C2D(kw),Y1WTM(2,2),XKNMTB(4,3) DIMENSION T3NHE(kw),T3NH2(kw) DIMENSION STCOMP(5,4),STALPH(34),ISTAL(4),LNGHAL(4),STWTAL(34), 1STCPWT(5,4),LNCOMP(4),FINEST(14),FINSWT(14) REAL*4 LORWING,ASUM(100),ASUMLYMAN(100) REAL*4 CUTOFFH2PLUS(111),CUTOFFH2(91) C DATA XKNMTB/.0001716,.009019,.1001,.5820,.0005235,.01772,.171,.866 1,.0008912,.02507,.223,1.02/ DATA Y1WTM/1.E18,1.E17,1.E16,1.E14/ DATA ITEMP1/0/,N1/0/,M1/0/,RYDH/3.2880515E15/ C FINE STRUCTURE COMPONENTS FOR ALPHA LINES IN FREQ*10**-7 DATA STALPH/-730.,370.,188.,515.,327.,619.,-772.,-473.,-369.,120., 1256.,162.,285.,-161.,-38.3,6.82,-174.,-147.,-101.,-77.5,55.,126., 275.,139.,-60.,3.7,27.,-69.,-42.,-18.,-5.5,-9.1,-33.,-24./ C ALPHA COMPONENT WEIGHTS DATA STWTAL/1.,2.,1.,2.,1.,2.,1.,2.,3.,1.,2.,1.,2.,1.,4.,6.,1.,2., 13.,4.,1.,2.,1.,2.,1.,4.,6.,1.,7.,6.,4.,4.,4.,5./ DATA ISTAL/1,3,10,21/, LNGHAL/2,7,11,14/ C FINE STRUCTURE FOR M.EQ.INFINITY IN FREQ*10**-7 DATA STCOMP/0.,0.,0.,0.,0.,468.,576.,-522.,0.,0.,260.,290.,-33., 1-140.,0.0,140.,150.,18.,-27.,-51./ C WEIGHTS DATA STCPWT/1.,0.,0.,0.,0.,1.,1.,2.,0.,0.,1.,1.,4.,3.,0.,1.,1., 14.,6.,4./ DATA LNCOMP/1,3,4,5/ c revised by Fiorella Castelli c Allard et al. (1998) A&A 372,260. Castelli & Kurucz (2001)a&A 372, 360. C LYMAN ALPHA QUASI H2+ CUTOFF C DELTA WAVENO = -15000+100*(N-1) N=1,111 UP TO -4000 DATA CUTOFFH2PLUS/ 1-15.14,-15.06,-14.97,-14.88,-14.80,-14.71,-14.62,-14.53, 2-14.44,-14.36,-14.27,-14.18,-14.09,-14.01,-13.92,-13.83, 3-13.74,-13.65,-13.57,-13.48,-13.39,-13.30,-13.21,-13.13, 4-13.04,-12.95,-12.86,-12.77,-12.69,-12.60,-12.51,-12.40, 5-12.29,-12.15,-12.02,-11.90,-11.76,-11.63,-11.53,-11.41, 6-11.30,-11.22,-11.15,-11.09,-11.07,-11.06,-11.07,-11.09, 7-11.12,-11.16,-11.19,-11.21,-11.24,-11.27,-11.30,-11.33, 8-11.36,-11.39,-11.42,-11.45,-11.48,-11.48,-11.48,-11.48, 9-11.48,-11.48,-11.48,-11.48,-11.48,-11.48,-11.48,-11.48, A-11.48,-11.48,-11.48,-11.48,-11.41,-11.40,-11.39,-11.38, 1-11.37,-11.36,-11.35,-11.34,-11.33,-11.32,-11.30,-11.29, 2-11.28,-11.27,-11.27,-11.27,-11.26,-11.25,-11.24,-11.23, 3-11.22,-11.21,-11.20,-11.19,-11.18,-11.17,-11.15,-11.14, 4-11.13,-11.12,-11.11,-11.10,-11.09,-11.08,-11.07/ C DATA CUTOFFH2PLUS/ C 1-17.15,-17.00,-16.86,-16.71,-16.56,-16.41,-16.27,-16.12, C 2-15.97,-15.82,-15.68,-15.53,-15.38,-15.23,-15.09,-14.94, C 3-14.79,-14.64,-14.50,-14.35,-14.20,-14.05,-13.91,-13.76, C 4-13.61,-13.46,-13.32,-13.17,-13.02,-12.87,-12.73,-12.58, C 5-12.43,-12.28,-12.14,-11.99,-11.85,-11.72,-11.60,-11.49, C 6-11.40,-11.36,-11.335,-11.33,-11.33,-11.335,-11.35,-11.37, C 7-11.40,-11.42,-11.45,-11.48,-11.52,-11.55,-11.59,-11.61, C 8-11.61,-11.61,-11.60,-11.59,-11.58,-11.57,-11.56,-11.55, C 9-11.54,-11.53,-11.52,-11.51,-11.49,-11.48,-11.47,-11.46, C A-11.45,-11.44,-11.43,-11.42,-11.41,-11.40,-11.39,-11.38, C 1-11.37,-11.36,-11.35,-11.34,-11.33,-11.32,-11.30,-11.29, C 2-11.28,-11.27,-11.26,-11.25,-11.24,-11.23,-11.22,-11.21, C 3-11.20,-11.19,-11.18,-11.17,-11.16,-11.15,-11.13,-11.12, C 4-11.11,-11.10,-11.09,-11.08,-11.07,-11.06,-11.05/ C LYMAN ALPHA QUASI H2 CUTOFF C DELTA WAVENO = -22000+200*(N-1) N=1,91 -4000 DATA CUTOFFH2/ 1-13.64,-13.52,-13.39,-13.27,-13.14,-13.01,-12.87,-12.74, 2-12.63,-12.56,-12.51,-12.48,-12.47,-12.49,-12.52,-12.55, 3-12.57,-12.61,-12.65,-12.69,-12.72,-12.76,-12.79,-12.82, 4-12.84,-12.85,-12.87,-12.90,-12.93,-12.94,-12.93,-12.95, 5-12.95,-12.96,-12.97,-12.96,-12.96,-12.95,-12.95,-12.96, 6-12.98,-12.99,-12.95,-12.96,-13.00,-13.00,-12.98,-12.97, 7-13.00,-13.00,-13.00,-13.00,-13.00,-13.00,-13.00,-13.00, 8-13.00,-13.00,-13.00,-13.00,-13.00,-13.00,-13.00,-13.00, 9-13.00,-13.00,-13.00,-13.00,-13.00,-13.00,-12.89,-12.88, A-12.87,-12.86,-12.85,-12.84,-12.83,-12.81,-12.80,-12.79, 1-12.78,-12.76,-12.74,-12.72,-12.70,-12.68,-12.65,-12.62, 2-12.59,-12.56,-12.53/ cc DATA CUTOFFH2/ cc 1-13.43,-13.32,-13.21,-13.10,-12.98,-12.86,-12.79,-12.72, cc 2-12.65,-12.58,-12.51,-12.47,-12.45,-12.45,-12.48,-12.51, cc 3-12.53,-12.56,-12.59,-12.62,-12.65,-12.69,-12.73,-12.77, cc 4-12.81,-12.85,-12.87,-12.89,-12.90,-12.90,-12.90,-12.90, cc 5-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90, cc 6-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90, cc 7-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90, cc 8-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.90, cc 9-12.90,-12.90,-12.90,-12.90,-12.90,-12.90,-12.89,-12.88, cc A-12.87,-12.86,-12.85,-12.84,-12.83,-12.81,-12.80,-12.79, cc 1-12.78,-12.76,-12.74,-12.72,-12.70,-12.68,-12.65,-12.62, cc 2-12.59,-12.56,-12.53/ cc C DATA CUTOFFH2/ C 1-13.87,-13.73,-13.59,-13.45,-13.31,-13.17,-13.05,-12.93, C 2-12.83,-12.74,-12.67,-12.63,-12.60,-12.60,-12.63,-12.65, C 3-12.67,-12.69,-12.71,-12.73,-12.75,-12.77,-12.79,-12.81, C 4-12.83,-12.85,-12.86,-12.87,-12.87,-12.86,-12.85,-12.84, C 5-12.83,-12.82,-12.80,-12.79,-12.78,-12.77,-12.76,-12.75, C 6-12.74,-12.72,-12.71,-12.70,-12.69,-12.68,-12.67,-12.66, C 7-12.64,-12.63,-12.62,-12.61,-12.60,-12.59,-12.58,-12.57, C 8-12.55,-12.54,-12.53,-12.52,-12.51,-12.50,-12.49,-12.47, C 9-12.46,-12.45,-12.44,-12.43,-12.42,-12.41,-12.39,-12.38, C A-12.37,-12.36,-12.35,-12.34,-12.33,-12.31,-12.30,-12.29, C 1-12.28,-12.26,-12.24,-12.22,-12.20,-12.18,-12.15,-12.12, C 2-12.09,-12.06,-12.03/ DATA ASUMLYMAN/ 1 0.000E+00, 6.265E+08, 1.897E+08, 8.126E+07, 4.203E+07, 2.450E+07, 2 1.236E+07, 8.249E+06, 5.782E+06, 4.208E+06, 3.158E+06, 2.430E+06, 3 1.910E+06, 1.567E+06, 1.274E+06, 1.050E+06, 8.752E+05, 7.373E+05, 4 6.269E+05, 5.375E+05, 4.643E+05, 4.038E+05, 3.534E+05, 3.111E+05, 5 2.752E+05, 2.447E+05, 2.185E+05, 1.959E+05, 1.763E+05, 1.593E+05, 6 1.443E+05, 1.312E+05, 1.197E+05, 1.094E+05, 1.003E+05, 9.216E+04, 7 8.489E+04, 7.836E+04, 7.249E+04, 6.719E+04, 6.239E+04, 5.804E+04, 8 5.408E+04, 5.048E+04, 4.719E+04, 4.418E+04, 4.142E+04, 3.888E+04, 9 3.655E+04, 3.440E+04, 3.242E+04, 3.058E+04, 2.888E+04, 2.731E+04, A 2.585E+04, 2.449E+04, 2.322E+04, 2.204E+04, 2.094E+04, 1.991E+04, 1 1.894E+04, 1.804E+04, 1.720E+04, 1.640E+04, 1.566E+04, 1.496E+04, 2 1.430E+04, 1.368E+04, 1.309E+04, 1.254E+04, 1.201E+04, 1.152E+04, 3 1.105E+04, 1.061E+04, 1.019E+04, 9.796E+03, 9.419E+03, 9.061E+03, 4 8.721E+03, 8.398E+03, 8.091E+03, 7.799E+03, 7.520E+03, 7.255E+03, 5 7.002E+03, 6.760E+03, 6.530E+03, 6.310E+03, 6.100E+03, 5.898E+03, 6 5.706E+03, 5.522E+03, 5.346E+03, 5.177E+03, 5.015E+03, 4.860E+03, 7 4.711E+03, 4.569E+03, 4.432E+03, 4.300E+03/ DATA ASUM/ 1 0.000E+00, 4.696E+08, 9.980E+07, 3.017E+07, 1.155E+07, 5.189E+06, 2 2.616E+06, 1.437E+06, 8.444E+05, 5.234E+05, 3.389E+05, 2.275E+05, 3 1.575E+05, 1.120E+05, 8.142E+04, 6.040E+04, 4.560E+04, 3.496E+04, 4 2.719E+04, 2.141E+04, 1.711E+04, 1.377E+04, 1.119E+04, 9.166E+03, 5 7.572E+03, 6.341E+03, 5.338E+03, 4.523E+03, 3.854E+03, 3.302E+03, 6 2.844E+03, 2.460E+03, 2.138E+03, 1.866E+03, 1.635E+03, 1.438E+03, 7 1.269E+03, 1.124E+03, 9.983E+02, 8.894E+02, 7.947E+02, 7.120E+02, 8 6.396E+02, 5.759E+02, 5.198E+02, 4.703E+02, 4.263E+02, 3.873E+02, 9 3.526E+02, 3.215E+02, 2.938E+02, 2.689E+02, 2.465E+02, 2.264E+02, A 2.082E+02, 1.918E+02, 1.769E+02, 1.634E+02, 1.512E+02, 1.400E+02, 1 1.298E+02, 1.206E+02, 1.121E+02, 1.043E+02, 9.720E+01, 9.066E+01, 2 8.465E+01, 7.912E+01, 7.403E+01, 6.933E+01, 6.498E+01, 6.097E+01, 3 5.725E+01, 5.381E+01, 5.061E+01, 4.765E+01, 4.489E+01, 4.232E+01, 4 3.994E+01, 3.771E+01, 3.563E+01, 3.369E+01, 3.188E+01, 3.019E+01, 5 2.860E+01, 2.712E+01, 2.572E+01, 2.442E+01, 2.319E+01, 2.204E+01, 6 2.096E+01, 1.994E+01, 1.898E+01, 1.808E+01, 1.722E+01, 1.642E+01, 7 1.566E+01, 1.495E+01, 1.427E+01, 1.363E+01/ FASTEX(X)=EXTAB(IFIX(X)+1)* 1EXTABF(IFIX((X-FLOAT(IFIX(X)))*1000.+1.5)) IF(ITEMP.EQ.ITEMP1)GO TO 20 C SET UP DEPTH VECTORS ITEMP1=ITEMP DO 10 K=1,NRHOX XNE16=XNE(K)**.1666667 PP(K)=XNE16*.08989/SQRT(T(K)) FO(K)=XNE16**4*1.25E-9 Y1B(K)=2./(1.+.012/T(K)*SQRT(XNE(K)/T(K))) T4=T(K)/10000. T43=T4**.3 Y1S(K)=T43/XNE16 C T3NHE(K)=T43*XNFPHE(K,1) T3NHE(K)=T43*XNFHE(K,1) T3NH2(K)=T43*XNFH2(K) C1D(K)=FO(K)*78940./T(K) C2D(K)=FO(K)**2/5.96E-23/XNE(K) GCON1(K)=.2+.09*SQRT(T4)/(1.+XNE(K)/1.E13) GCON2(K)=.2/(1.+XNE(K)/1.E15) 10 CONTINUE C SET UP FOR THIS LINE 20 IF(N.EQ.N1.AND.M.EQ.M1)GO TO 30 N1=N M1=M MMN=M-N XN=N XN2=XN*XN XM=M XM2=XM*XM XMN2=XM2*XN2 XM2MN2=XM2-XN2 GNM=XM2MN2/XMN2 IF(MMN.LE.3.AND.N.LE.4)XKNM=XKNMTB(N,MMN) IF(MMN.GT.3.OR.N.GT.4)XKNM=5.5E-5/GNM*XMN2/(1.+.13/FLOAT(MMN)) Y1NUM=320. IF(M.EQ.2)Y1NUM=550. IF(M.EQ.3)Y1NUM=380. Y1WHT=1.E13 IF(MMN.LE.3)Y1WHT=1.E14 IF(MMN.LE.2.AND.N.LE.2)Y1WHT=Y1WTM(N,MMN) FREQNM=RYDH*GNM DBETA=2.99792458D18/FREQNM**2/XKNM WAVENM=2.99792458D18/FREQNM C1CON=XKNM/WAVENM*GNM*XM2MN2 C2CON=(XKNM/WAVENM)**2 C RADAMP=1.389E9/XM**4.53/(1.+5./XM2/XM) C IF(N.NE.1)RADAMP=RADAMP+1.389E9/XN**4.53/(1.+5./XN2/XN) RADAMP=ASUM(N)+ASUM(M) IF(N.EQ.1)RADAMP=ASUMLYMAN(M) RADAMP=RADAMP/12.5664 RADAMP=RADAMP/FREQNM RESONT=HFNM(1,M)/XM/(1.-1./XM2) IF(N.NE.1)RESONT=RESONT+HFNM(1,N)/XN/(1.-1./XN2) C FUDGE TO BASCHEK*2 C RESONT=HFNM(1,M)/XM/(1.-1./XM2)*XM/3.*.791*2. C IF(N.NE.1)RESONT=RESONT+HFNM(1,N)/XN/(1.-1./XN2)*XN/3.*.791*2. C 2 IS FOR CONVERTING XNFPH TO XNFH C RESONT=RESONT*5.593E-24/GNM*2. C RESONT=RESONT*5.593E-24/GNM C error in constant corrected 26nov95 C KURUCZ CC RESONT=RESONT*3.92E-24/GNM C Castelli after Ali and Griem (1963) RESONT=RESONT*3.579E-24/GNM VDW=4.45E-26/GNM*(XM2*(7.*XM2+5.))**.4 C GUESS THAT H2 IS TWICE AS STRONG AS HE AS IN TXNXN HWVDW=VDW*T3NHE(J)+2.*VDW*T3NH2(J) HWRAD=RADAMP STARK=1.6678E-18*FREQNM*XKNM C FINE STRUCTURE COMPONENTS C C IF(N.GT.4)THEN IF(N.GT.4.OR.M.GT.10)THEN IFINS=1 FINEST(1)=0. FINSWT(1)=1. GO TO 30 ENDIF C IF(MMN.EQ.1)GO TO 22 C USE M.EQ.INF STRUCTURE IFINS=LNCOMP(N) DO 21 I=1,IFINS FINEST(I)=STCOMP(I,N)*1.E7 FINSWT(I)=STCPWT(I,N)/XN2 21 CONTINUE GO TO 30 C FOR ALPHA LINES 22 IFINS=LNGHAL(N) IPOS=ISTAL(N) DO 23 I=1,IFINS K=IPOS-1+I FINEST(I)=STALPH(K)*1.E7 FINSWT(I)=STWTAL(K)/XN2/3. 23 CONTINUE C NOW DO THIS DEPTH C 30 DEL=-10.*DELW/WAVENM*FREQNM error C FREQ=FREQNM+DEL C WAVENM IN A DELW IN NM 30 WL=WAVENM+DELW*10. FREQ=2.99792458D18/WL DEL=ABS(FREQ-FREQNM) C WL IN NM WL=WL/10. C THESE HALF-WIDTHS ARE REALLY DNU/NU HWSTK=STARK*FO(J) HWVDW=VDW*T3NHE(J)+2.*VDW*T3NH2(J) HWRAD=RADAMP C XNFPH(J,1)*2 IS THE NUMBER IN THE GROUND STATE HWRES=RESONT*XNFPH(J,1)*2. HWLOR=HWRES+HWVDW+HWRAD HWDOP=DOPPH(J) C SPECIFY LARGEST HALF WIDTH IN CASE OF CORE CALC C NWID=1, DOPPLER =2, LORENTZ =3, STARK NWID=1 IF(HWDOP.GE.HWSTK.AND.HWDOP.GE.HWLOR)GO TO 31 NWID=2 IF(HWLOR.GE.HWSTK)GO TO 31 NWID=3 31 HFWID=FREQNM*AMAX1(HWDOP,HWLOR,HWSTK) C SETS FLAG IF IN A LINE CORE C HPROFL=0. HPROF4=0. IFCORE=0 IF(ABS(DEL).LE.HFWID)IFCORE=1 DOP=FREQNM*HWDOP IF(IFCORE.EQ.1)GO TO (32,40,50),NWID C C DO DOPPLER C PUT FINE STRUCTURE IN DOPPLER CORE 32 DO 33 I=1,IFINS D=ABS(FREQ-FREQNM-FINEST(I))/DOP C IF(D.LE.7.)HPROF4=HPROF4+EXP(-D*D)/1.77245/DOP*FINSWT(I) C IF(D.LE.7.)HPROFL=HPROFL+EXP(-D*D)/1.77245/DOP*FINSWT(I) C SAME NORMALIZATION AS VOIGT FUNCTION IF(D.LE.7.)HPROF4=HPROF4+FASTEX(D*D)*FINSWT(I) 33 CONTINUE IF(IFCORE.EQ.1)RETURN C C DO LORENTZ 40 IF(N.NE.1)GO TO 48 IF(M.NE.2)GO TO 48 C Lyman alpha C near center c modify old resonance broadening to match at 4000 cm-1 HWRES=HWRES*4. HWLOR=HWRES+HWVDW+HWRAD HHW=FREQNM*HWLOR IF(FREQ.GT.(82259.10D0-4000.D0)*2.99792458D10)THEN HPROFRES=HWRES*FREQNM/3.14159/(DEL**2+HHW**2)*1.77245*DOP GO TO 44 ENDIF C only far red wing C Data from N.F. Allard, March 1997 C Insert Lyman alpha cutoff a la N.F. Allard and D. Koester, A&A, 258, C 464-468. 1992. CUTOFF=0. IF(FREQ.LT.50000.*2.99792458D10)GO TO 43 C TABULATED AT 200 CM-1 SPACING SPACING=200.*2.99792458D10 FREQ22000=(82259.10D0-22000.D0)*2.99792458D10 IF(FREQ.LT.FREQ22000)THEN CUTOFF=(CUTOFFH2(2)-CUTOFFH2(1))/SPACING*(FREQ-FREQ22000)+ 1CUTOFFH2(1) ELSE ICUT=(FREQ-FREQ22000)/SPACING CUTFREQ=ICUT*SPACING+FREQ22000 CUTOFF=(CUTOFFH2(ICUT+2)-CUTOFFH2(ICUT+1))/SPACING* 1(FREQ-CUTFREQ)+CUTOFFH2(ICUT+1) ENDIF CUTOFF=(10.**(CUTOFF-14.))*XNFPH(J,1)*2./2.99792458D10 43 HPROFRES=CUTOFF*1.77245*DOP C 44 HPROFRAD=0. C RAYLEIGH SCATTERING EXCEPT NEAR DOPPLER CORE C CROSSOVER FROM ABSORPTION TO RAYLEIGH SCATTTERING IN HRAYOP C IF(FREQ.GT.2.463E15) C IF(FREQ.GT..74*3.288051D15.AND.FREQ.LT..78*3.288051D15) C USE FREQUENCY IN CONTINUA.DAT 2.419061115 AS CUTOFF INSTEAD IF(FREQ.GT.2.4190611E15.AND.FREQ.LT..77*3.288051D15) 1 HPROFRAD=HWRAD*FREQNM/3.14159/(DEL**2+HHW**2)*1.77245*DOP C CORRECTION TO LORENTZ PROFILE ALLER P.164 NOT USED C HPROFRAD=HPROFRAD*4.*FREQ**2/(FREQ**2+FREQNM**2) C HPROFVDW=HWVDW*FREQNM/3.14159/(DEL**2+HHW**2)*1.77245*DOP C VAN DER WAALS CUTOFF FOR HE AND FOR H2 C GUESS BOTH 60000 CM-1 = 1.8D15 HZ IF(FREQ.LT.1.8D15)HPROFVDW=0. HPROFLOR=HPROFRES+HPROFRAD+HPROFVDW HPROF4=HPROF4+HPROFLOR IF(IFCORE.EQ.1)RETURN GO TO 50 C C not Lyman alpha 48 HHW=FREQNM*HWLOR TOP=HHW IF(N.NE.1.OR.M.GT.5)GO TO 49 C Lyman beta IF(M.EQ.3.AND.FREQ.GT..885*3.288051D15.AND. 1 FREQ.LT..890*3.288051D15)TOP=HHW-FREQNM*HWRAD C Lyman gamma IF(M.EQ.4.AND.FREQ.GT..936*3.288051D15.AND. 1 FREQ.LT..938*3.288051D15)TOP=HHW-FREQNM*HWRAD C Lyman delta IF(M.EQ.5.AND.FREQ.GT..959*3.288051D15.AND. 1 FREQ.LT..961*3.288051D15)TOP=HHW-FREQNM*HWRAD 49 HPROFLOR=TOP/3.14159/(DEL**2+HHW**2)*1.77245*DOP HPROF4=HPROF4+HPROFLOR IF(IFCORE.EQ.1)RETURN C C DO STARK 50 WTY1=1./(1.+XNE(J)/Y1WHT) Y1SCAL=Y1NUM*Y1S(J)*WTY1+Y1B(J)*(1.-WTY1) C1=C1D(J)*C1CON*Y1SCAL C2=C2D(J)*C2CON G1=6.77*SQRT(C1) GNOT=G1*AMAX1(0.,.2114+ALOG(SQRT(C2)/C1))*(1.-GCON1(J)-GCON2(J)) BETA=ABS(DEL)/FO(J)*DBETA Y1=C1*BETA Y2=C2*BETA**2 GAM=GNOT C IF(Y2.LE..001)GO TO 51 IF(Y2.LE.1.E-4.AND.Y1.LE.1.E-5)GO TO 51 C GAM=G1*(.5*FASTEX(AMIN1(80.,Y1))+FASTE1(Y1)-.5*FASTE1(Y2))* C GAM=G1*(.5*EXP(-AMIN1(80.,Y1))+VCSE1F(Y1)-.5*VCSE1F(Y2))* GAM=G1*(.5*FASTEX(AMIN1(80.,Y1))+VCSE1F(Y1)-.5*VCSE1F(Y2))* 1(1.-GCON1(J)/(1.+(90.*Y1)**3)-GCON2(J)/(1.+2000.*Y1)) IF(GAM.LE.1.E-20)GAM=0. 51 PRQS=SOFBET(BETA,PP(J),N,M) IF(M.GT.2)GO TO 53 C ASSUME QUASISTATIC PROFILE IS HALF PROTONS, HALF ELECTRONS PRQS=PRQS*.5 CUTOFF=0. C LYMAN ALPHA QUASI H2+ CUTOFF C Data from N.F. Allard, March 1997 IF(FREQ.LT.(82259.10D0-20000.)*2.99792458D10)GO TO 53 IF(FREQ.GT.(82259.10D0-4000.)*2.99792458D10)GO TO 52 C TABULATED AT 100 CM-1 SPACING FREQ15000=(82259.10D0-15000.)*2.99792458D10 SPACING=100.*2.99792458D10 IF(FREQ.LT.FREQ15000)THEN CUTOFF=(CUTOFFH2PLUS(2)-CUTOFFH2PLUS(1))/SPACING* 1(FREQ-FREQ15000)+CUTOFFH2PLUS(1) ELSE ICUT=(FREQ-FREQ15000)/SPACING CUTFREQ=ICUT*SPACING+FREQ15000 CUTOFF=(CUTOFFH2PLUS(ICUT+2)-CUTOFFH2PLUS(ICUT+1))/ 1SPACING*(FREQ-CUTFREQ)+CUTOFFH2PLUS(ICUT+1) ENDIF C XNFPH(J,2)=XNFH(J,2) CUTOFF=(10.**(CUTOFF-14.))/2.99792458D10*XNFPH(J,2) HPROF4=HPROF4+CUTOFF*1.77245*DOP GO TO 53 52 BETA4000=4000.*2.99792458D10/FO(J)*DBETA PRQSP4000=SOFBET(BETA4000,PP(J),N,M)*.5/FO(J)*DBETA CUTOFF4000=(10.**(-11.07-14.))/2.99792458D10*XNFPH(J,2) HPROF4=HPROF4+CUTOFF4000/PRQSP4000*PRQS/FO(J)*DBETA*1.77245*DOP 53 F=0. IF(GAM.GT.0.)F=GAM/3.14159/(GAM**2+BETA**2) P1=(.9*Y1)**2 FNS=(P1+.03*SQRT(Y1))/(P1+1.) C SAME NORMALIZATION AS VOIGT FUNCTION HPROF4=HPROF4+(PRQS*(1.+FNS)+F)/FO(J)*DBETA*1.77245*DOP RETURN END FUNCTION HFNM(N,M) C CALCULATES HYDROGEN OSCILLATOR STRENGTHS DATA NSTR/0/,MSTR/0/ HFNM=0. IF(M.LE.N)RETURN IF(N.EQ.NSTR)GO TO 10 XN=N GINF=.2027/XN**.71 GCA=.124/XN FKN=XN*1.9603 WTC=.45-2.4/XN**3*(XN-1.) NSTR=N GO TO 15 10 IF(M.EQ.MSTR)GO TO 20 15 XM=M XMN=M-N FK=FKN*(XM/(XMN*(XM+XN)))**3 XMN12=XMN**1.2 WT=(XMN12-1.)/(XMN12+WTC) FNM=FK*(1.-WT*GINF-(.222+GCA/XM)*(1.-WT)) MSTR=M 20 HFNM=FNM RETURN END FUNCTION VCSE1F(X) C ROUGH, BUT ARRANGED TO BE FAST. X.GE.0 COMMON /EXTAB/EXTAB(1001),EXTABF(1001),E1TAB(2000) FASTEX(X)=EXTAB(IFIX(X)+1)* 1EXTABF(IFIX((X-FLOAT(IFIX(X)))*1000.+1.5)) VCSE1F=0. IF(X.LE.0.)RETURN IF(X.GT..01)GO TO 10 VCSE1F=-ALOG(X)-.577215+X RETURN 10 IF(X.GT.1.)GO TO 20 VCSE1F=-ALOG(X)-.57721566D0+X*(.99999193D0+X*(-.24991055D0+X* 1 (.05519968D0+X*(-.00976004D0+X*.00107857D0)))) RETURN 20 IF(X.GT.30.)RETURN C VCSE1F=(X*(X+2.334733)+.25062)/(X*(X+3.330657)+1.681534)/X*EXP(-X) VCSE1F=(X*(X+2.334733D0)+.25062D0)/(X*(X+3.330657D0)+1.681534D0) 1 /X*FASTEX(X) RETURN END FUNCTION SOFBET(B,P,N,M) C GENERATES S(BETA,P) FOR HYDROGEN LINES. THE ALPHA AND BETA LINES C OF THE FIRST THREE SERIES ARE EXPLICITLY INCLUDED AND THE H18 C PROFILE IS USED FOR THE REST. C C THESE PROFILES HAVE BEEN RENORMALIZED TO FULL OSCILLATOR STRENGTH C C STORAGE FOR CORRECTIONS (P,BETA,IND),(P,IND),(P,IND) DIMENSION PROPBM(5,15,7),C(5,7),D(5,7) DIMENSION PP(5),BETA(15) DIMENSION PROB1(75),PROB2(75),PROB3(75),PROB4(75),PROB5(75) DIMENSION PROB6(75),PROB7(75) DIMENSION C1(5),C2(5),C3(5),C4(5),C5(5),C6(5),C7(5) DIMENSION D1(5),D2(5),D3(5),D4(5),D5(5),D6(5),D7(5) EQUIVALENCE (PROPBM(1),PROB1(1)),(PROPBM(76),PROB2(1)) EQUIVALENCE (PROPBM(151),PROB3(1)),(PROPBM(226),PROB4(1)) EQUIVALENCE (PROPBM(301),PROB5(1)),(PROPBM(376),PROB6(1)) EQUIVALENCE (PROPBM(451),PROB7(1)) EQUIVALENCE (C(1),C1(1)),(C(6),C2(1)),(C(11),C3(1)),(C(16),C4(1)) EQUIVALENCE (C(21),C5(1)),(C(26),C6(1)),(C(31),C7(1)) EQUIVALENCE (D(1),D1(1)),(D(6),D2(1)),(D(11),D3(1)),(D(16),D4(1)) EQUIVALENCE (D(21),D5(1)),(D(26),D6(1)),(D(31),D7(1)) C LYMAN ALPHA DATA PROB1/ 1-.980,-.967,-.948,-.918,-.873,-.968,-.949,-.921,-.879,-.821, 2-.950,-.922,-.883,-.830,-.764,-.922,-.881,-.830,-.770,-.706, 3-.877,-.823,-.763,-.706,-.660,-.806,-.741,-.682,-.640,-.625, 4-.691,-.628,-.588,-.577,-.599,-.511,-.482,-.484,-.514,-.568, 5-.265,-.318,-.382,-.455,-.531,-.013,-.167,-.292,-.394,-.478, 6 .166,-.056,-.216,-.332,-.415, .251, .035,-.122,-.237,-.320, 7 .221, .059,-.068,-.168,-.247, .160, .055,-.037,-.118,-.189, 8 .110, .043,-.022,-.085,-.147/ DATA C1 /-18.396, 84.674,-96.273, 3.927, 55.191/ DATA D1 / 11.801, 9.079, -.651,-11.071,-26.545/ C LYMAN BETA DATA PROB2/ 1-.242, .060, .379, .671, .894, .022, .314, .569, .746, .818, 2 .273, .473, .605, .651, .607, .432, .484, .489, .442, .343, 3 .434, .366, .294, .204, .091, .304, .184, .079,-.025,-.135, 4 .167, .035,-.082,-.189,-.290, .085,-.061,-.183,-.287,-.374, 5 .032,-.127,-.249,-.344,-.418,-.024,-.167,-.275,-.357,-.420, 6-.061,-.170,-.257,-.327,-.384,-.047,-.124,-.192,-.252,-.306, 7-.043,-.092,-.142,-.190,-.238,-.038,-.070,-.107,-.146,-.187, 8-.030,-.049,-.075,-.106,-.140/ DATA C2 / 95.740, 18.489, 14.902, 24.466, 42.456/ DATA D2 / -6.665, -7.136,-10.605,-15.882,-23.632/ C BALMER ALPHA DATA PROB3/ 1-.484,-.336,-.206,-.111,-.058,-.364,-.264,-.192,-.154,-.144, 2-.299,-.268,-.250,-.244,-.246,-.319,-.333,-.337,-.336,-.337, 3-.397,-.414,-.415,-.413,-.420,-.456,-.455,-.451,-.456,-.478, 4-.446,-.441,-.446,-.469,-.512,-.358,-.381,-.415,-.463,-.522, 5-.214,-.288,-.360,-.432,-.503,-.063,-.196,-.304,-.394,-.468, 6 .063,-.108,-.237,-.334,-.409, .151,-.019,-.148,-.245,-.319, 7 .149, .016,-.091,-.177,-.246, .115, .023,-.056,-.126,-.189, 8 .078, .021,-.036,-.091,-.145/ DATA C3 /-25.088,145.882,-50.165, 7.902, 51.003/ DATA D3 / 7.872, 5.592, -2.716,-12.180,-25.661/ C BALMER BETA DATA PROB4/ 1-.082, .163, .417, .649, .829, .096, .316, .515, .660, .729, 2 .242, .393, .505, .556, .534, .320, .373, .394, .369, .290, 3 .308, .274, .226, .152, .048, .232, .141, .052,-.046,-.154, 4 .148, .020,-.094,-.200,-.299, .083,-.070,-.195,-.299,-.385, 5 .031,-.130,-.253,-.348,-.422,-.023,-.167,-.276,-.359,-.423, 6-.053,-.165,-.254,-.326,-.384,-.038,-.119,-.190,-.251,-.306, 7-.034,-.088,-.140,-.190,-.239,-.032,-.066,-.103,-.144,-.186, 8-.027,-.048,-.075,-.106,-.142/ DATA C4 / 93.783, 10.066, 9.224, 20.685, 40.136/ DATA D4 / -5.918, -6.501,-10.130,-15.588,-23.570/ C PASCHEN ALPHA DATA PROB5/ 1-.819,-.759,-.689,-.612,-.529,-.770,-.707,-.638,-.567,-.498, 2-.721,-.659,-.595,-.537,-.488,-.671,-.617,-.566,-.524,-.497, 3-.622,-.582,-.547,-.523,-.516,-.570,-.545,-.526,-.521,-.537, 4-.503,-.495,-.496,-.514,-.551,-.397,-.418,-.448,-.492,-.547, 5-.246,-.315,-.384,-.453,-.522,-.080,-.210,-.316,-.406,-.481, 6 .068,-.107,-.239,-.340,-.418, .177,-.006,-.143,-.246,-.324, 7 .184, .035,-.082,-.174,-.249, .146, .042,-.046,-.123,-.190, 8 .103, .036,-.027,-.088,-.146/ DATA C5 /-19.819, 94.981,-79.606, 3.159, 52.106/ DATA D5 / 10.938, 8.028, -1.267,-11.375,-26.047/ C PASCHEN BETA DATA PROB6/ 1-.073, .169, .415, .636, .809, .102, .311, .499, .639, .710, 2 .232, .372, .479, .531, .514, .294, .349, .374, .354, .279, 3 .278, .253, .212, .142, .040, .215, .130, .044,-.051,-.158, 4 .141, .015,-.097,-.202,-.300, .080,-.072,-.196,-.299,-.385, 5 .029,-.130,-.252,-.347,-.421,-.022,-.166,-.275,-.359,-.423, 6-.050,-.164,-.253,-.325,-.384,-.035,-.118,-.189,-.252,-.306, 7-.032,-.087,-.139,-.190,-.240,-.029,-.064,-.102,-.143,-.185, 8-.025,-.046,-.074,-.106,-.142/ DATA C6 /111.107, 11.910, 9.857, 21.371, 41.006/ DATA D6 / -5.899, -6.381,-10.044,-15.574,-23.644/ C BALMER 18 DATA PROB7/ 1 .005, .128, .260, .389, .504, .004, .109, .220, .318, .389, 2-.007, .079, .162, .222, .244,-.018, .041, .089, .106, .080, 3-.026,-.003, .003,-.023,-.086,-.025,-.048,-.087,-.148,-.234, 4-.008,-.085,-.165,-.251,-.343, .018,-.111,-.223,-.321,-.407, 5 .032,-.130,-.255,-.354,-.431, .014,-.148,-.269,-.359,-.427, 6-.005,-.140,-.243,-.323,-.386, .005,-.095,-.178,-.248,-.307, 7-.002,-.068,-.129,-.187,-.241,-.007,-.049,-.094,-.139,-.186, 8-.010,-.036,-.067,-.103,-.143/ DATA C7 /511.318, 1.532, 4.044, 19.266, 41.812/ DATA D7 / -6.070, -4.528, -8.759,-14.984,-23.956/ DATA PP/0.,.2,.4,.6,.8/ DATA BETA/1.,1.259,1.585,1.995,2.512,3.162,3.981,5.012,6.310,7.943 1,10.,12.59,15.85,19.95,25.12/ CORR=1. B2=B*B SB=SQRT(B) IF(B.GT.500.)GO TO 40 INDX=7 MMN=M-N IF(N.LE.3.AND.MMN.LE.2)INDX=2*(N-1)+MMN C DETERMINE RELEVANT DEBYE RANGE IM=MIN0(INT(5.*P)+1,4) IP=IM+1 WTPP=5.*(P-PP(IM)) WTPM=1.-WTPP IF(B.GT.25.12)GO TO 30 DO 10 J=2,15 IF(B.LE.BETA(J))GO TO 20 10 CONTINUE 20 JM=J-1 JP=J WTBP=(B-BETA(JM))/(BETA(JP)-BETA(JM)) WTBM=1.-WTBP CBP=PROPBM(IP,JP,INDX)*WTPP+PROPBM(IM,JP,INDX)*WTPM CBM=PROPBM(IP,JM,INDX)*WTPP+PROPBM(IM,JM,INDX)*WTPM CORR=1.+CBP*WTBP+CBM*WTBM C GET INNER APPROXIMATE PROFILE PR1=0. PR2=0. WT=AMAX1(AMIN1(.5*(10.-B),1.),0.) IF(B.LE.10.)PR1=8./(83.+(2.+.95*B2)*B) IF(B.GE.8.)PR2=(1.5/SB+27./B2)/B2 SOFBET=(PR1*WT+PR2*(1.-WT))*CORR RETURN C ASYMPTOTIC PARTS 30 CC=C(IP,INDX)*WTPP+C(IM,INDX)*WTPM DD=D(IP,INDX)*WTPP+D(IM,INDX)*WTPM CORR=1.+DD/(CC+B*SB) 40 SOFBET=(1.5/SB+27./B2)/B2*CORR RETURN END SUBROUTINE TABVOIGT(VSTEPS,N) COMMON /H1TAB/H0TAB(2001),H1TAB(2001),H2TAB(2001) DIMENSION TABVI(81),TABH1(81) DATA TABVI/0.,.1,.2,.3,.4,.5,.6,.7,.8,.9,1.,1.1,1.2,1.3,1.4,1.5, 11.6,1.7,1.8,1.9,2.,2.1,2.2,2.3,2.4,2.5,2.6,2.7,2.8,2.9,3.,3.1,3.2, 2 3.3,3.4,3.5,3.6,3.7,3.8,3.9,4.0,4.2,4.4,4.6,4.8,5.0,5.2,5.4,5.6, 3 5.8,6.0,6.2,6.4,6.6,6.8,7.0,7.2,7.4,7.6,7.8,8.0,8.2,8.4,8.6,8.8, 4 9.0,9.2,9.4,9.6,9.8,10.0,10.2,10.4,10.6,10.8,11.0,11.2,11.4,11.6, 5 11.8,12.0/ DATA TABH1/-1.12838,-1.10596,-1.04048,-.93703,-.80346,-.64945, 1-.48552,-.32192,-.16772,-.03012,.08594,.17789,.24537,.28981, 2.31394,.32130,.31573,.30094,.28027,.25648,.231726,.207528,.184882, 3.164341,.146128,.130236,.116515,.104739,.094653,.086005,.078565, 4 .072129,.066526,.061615,.057281,.053430,.049988,.046894,.044098, 5 .041561,.039250,.035195,.031762,.028824,.026288,.024081,.022146, 6 .020441,.018929,.017582,.016375,.015291,.014312,.013426,.012620, 7 .0118860,.0112145,.0105990,.0100332,.0095119,.0090306,.0085852, 8 .0081722,.0077885,.0074314,.0070985,.0067875,.0064967,.0062243, 9 .0059688,.0057287,.0055030,.0052903,.0050898,.0049006,.0047217, T .0045526,.0043924,.0042405,.0040964,.0039595/ C PRETABULATE VOIGT FUNCTION C 100 STEPS PER DOPPLER WIDTH GIVES 2 PER CENT ACCURACY DO 1 I=1,N 1 H0TAB(I)=FLOAT(I-1)/VSTEPS CALL MAP1(TABVI,TABH1,81,H0TAB,H1TAB,N) DO 2 I=1,N VV=(FLOAT(I-1)/VSTEPS)**2 H0TAB(I)=EXP(-VV) 2 H2TAB(I)=H0TAB(I)-(VV+VV)*H0TAB(I) RETURN END FUNCTION VOIGT(V,A) C FAST VOIGT COMMON /H1TAB/H0TAB(2001),H1TAB(2001),H2TAB(2001) IV=V*200.+1.5 IF(A.LT..2)GO TO 10 IF(A.GT.1.4)GO TO 2 IF(A+V.GT.3.2)GO TO 2 VV=V*V HH1=H1TAB(IV)+H0TAB(IV)*1.12838 HH2=H2TAB(IV)+HH1*1.12838-H0TAB(IV) HH3=(1.-H2TAB(IV))*.37613-HH1*.66667*VV+HH2*1.12838 HH4=(3.*HH3-HH1)*.37613+H0TAB(IV)*.66667*VV*VV VOIGT=((((HH4*A+HH3)*A+HH2)*A+HH1)*A+H0TAB(IV))* 1 (((-.122727278D0*A+.532770573D0)*A-.96284325D0)*A+ 2 .979895032D0) RETURN 2 AA=A*A VV=V*V U=(AA+VV)*1.4142 VOIGT=A*.79788/U IF(A.GT.100.)RETURN AAU=AA/U VVU=VV/U UU=U*U VOIGT= A((((AAU-10.*VVU)*AAU*3.+15.*VVU*VVU)+3.*VV-AA)/UU+1.)*VOIGT C A ((((AA-10.*VV)*AA*3.+15.*VV*VV)/UU+3.*VV-AA)/UU+1.)*A*.79788/U RETURN 10 IF(V.GT.10.)GO TO 12 11 VOIGT=(H2TAB(IV)*A+H1TAB(IV))*A+H0TAB(IV) RETURN 12 VOIGT=.5642*A/V**2 RETURN END FUNCTION EXPI(N,X) C LOW PRECISION VERSION 1.E-5 C EXPONENTIAL INTEGRAL FOR POSITIVE ARGUMENTS AFTER CODY AND C THACHER, MATH. OF COMP.,22,641(1968) DATA X1/-1.E20/ DATA A0,A1,A2,B0,B1/-4.43668255D0,4.42054938D0,3.16274620D0, 1 7.68641124D0,5.65655216D0/ DATA C0,C1,C2,D1,D2/.0012102205D0,.98147989D0,.75339742D0, 1 1.6198645D0,.29135151D0/ DATA E0,E1,F1/-.9969698D0,-.4257849D0,2.318261D0/ IF(X.EQ.X1)GO TO 40 EX=EXP(-X) X1=X IF(X.GT.4.)GO TO 10 IF(X.GT.1.)GO TO 20 IF(X.GT.0.)GO TO 30 EX1=0. GO TO 40 10 EX1=(EX+EX*(E0+E1/X)/(X+F1))/X GO TO 40 20 EX1=EX*(C2+(C1+C0*X)*X)/(D2+(D1+X)*X) GO TO 40 30 EX1=(A0+(A1+A2*X)*X)/(B0+(B1+X)*X)-ALOG(X) 40 EXPI=EX1 IF(N.EQ.1)RETURN N1=N-1 DO 41 I=1,N1 41 EXPI=(EX-X*EXPI)/FLOAT(I) RETURN END FUNCTION FASTE1(X) COMMON /EXTAB/EXTAB(1001),EXTABF(1001),E1TAB(2000) C DO 3457 I=1,2000 C3457 E1TAB(I)=EXPI(1,FLOAT(I)*.01) FASTE1=0. IF(X.GT.20)RETURN IF(X.LT..5)GO TO 1 FASTE1=E1TAB(IFIX(X*100.+.5)) RETURN 1 IF(X.LE.0.)RETURN FASTE1=(1.-.22464*X)*X-ALOG(X)-.57721 RETURN END SUBROUTINE MAP1(XOLD,FOLD,NOLD,XNEW,FNEW,NNEW) DIMENSION XOLD(1),FOLD(1),XNEW(1),FNEW(1) L=2 LL=0 DO 50 K=1,NNEW 10 IF(XNEW(K).LT.XOLD(L))GO TO 20 L=L+1 IF(L.GT.NOLD)GO TO 30 GO TO 10 20 IF(L.EQ.LL)GO TO 50 IF(L.EQ.2)GO TO 30 L1=L-1 IF(L.GT.LL+1.OR.L.EQ.3)GO TO 21 CBAC=CFOR BBAC=BFOR ABAC=AFOR IF(L.EQ.NOLD)GO TO 22 GO TO 25 21 L2=L-2 D=(FOLD(L1)-FOLD(L2))/(XOLD(L1)-XOLD(L2)) CBAC=FOLD(L)/((XOLD(L)-XOLD(L1))*(XOLD(L)-XOLD(L2)))+ 1(FOLD(L2)/(XOLD(L)-XOLD(L2))-FOLD(L1)/(XOLD(L)-XOLD(L1)))/ 2(XOLD(L1)-XOLD(L2)) BBAC=D-(XOLD(L1)+XOLD(L2))*CBAC ABAC=FOLD(L2)-XOLD(L2)*D+XOLD(L1)*XOLD(L2)*CBAC IF(L.LT.NOLD)GO TO 25 22 C=CBAC B=BBAC A=ABAC LL=L GO TO 50 25 D=(FOLD(L)-FOLD(L1))/(XOLD(L)-XOLD(L1)) CFOR=FOLD(L+1)/((XOLD(L+1)-XOLD(L))*(XOLD(L+1)-XOLD(L1)))+ 1(FOLD(L1)/(XOLD(L+1)-XOLD(L1))-FOLD(L)/(XOLD(L+1)-XOLD(L)))/ 2(XOLD(L)-XOLD(L1)) BFOR=D-(XOLD(L)+XOLD(L1))*CFOR AFOR=FOLD(L1)-XOLD(L1)*D+XOLD(L)*XOLD(L1)*CFOR WT=0. IF(ABS(CFOR).NE.0.)WT=ABS(CFOR)/(ABS(CFOR)+ABS(CBAC)) A=AFOR+WT*(ABAC-AFOR) B=BFOR+WT*(BBAC-BFOR) C=CFOR+WT*(CBAC-CFOR) LL=L GO TO 50 30 IF(L.EQ.LL)GO TO 50 L=AMIN0(NOLD,L) C=0. B=(FOLD(L)-FOLD(L-1))/(XOLD(L)-XOLD(L-1)) A=FOLD(L)-XOLD(L)*B LL=L 50 FNEW(K)=A+(B+C*XNEW(K))*XNEW(K) C MAP1=LL-1 RETURN END FUNCTION AIRVAC(W) IMPLICIT REAL*8 (A-H,O-Z) C W IS AIR WAVELENGTH IN NM C WAVEN IS AIR WAVENUMBER WHICH IS USUALLY GOOD ENOUGH C MUST ITERATE FOR EXACT SOLUTION WAVEN=1.D7/W WNEW=W*(1.0000834213D0+ 1 2406030.D0/(1.30D10-WAVEN**2)+15997.D0/(3.89D9-WAVEN**2)) WAVEN=1.D7/WNEW WNEW=W*(1.0000834213D0+ 1 2406030.D0/(1.30D10-WAVEN**2)+15997.D0/(3.89D9-WAVEN**2)) WAVEN=1.D7/WNEW AIRVAC=W*(1.0000834213D0+ 1 2406030.D0/(1.30D10-WAVEN**2)+15997.D0/(3.89D9-WAVEN**2)) RETURN END FUNCTION VACAIR(W) IMPLICIT REAL*8 (A-H,O-Z) C W IS VACUUM WAVELENGTH IN NM WAVEN=1.D7/W VACAIR=W/(1.0000834213D0+ 1 2406030.D0/(1.30D10-WAVEN**2)+15997.D0/(3.89D9-WAVEN**2)) RETURN END FUNCTION HE1PROF(J,WAVE,WL,DOPWL,GAMMAR,GAMMAS) c REAL*8 WAVE,WL,WLSAVE LINE=WL+1. IF(LINE.EQ.448)THEN HE1PROF=HE4471(J,WAVE,WL,DOPWL) RETURN ENDIF IF(LINE.EQ.403)THEN LINE=WL+.4 IF(LINE.EQ.402)then line=wl+1. go to 8 endif HE1PROF=HE4026(J,WAVE,WL,DOPWL) RETURN ENDIF IF(LINE.EQ.439)THEN HE1PROF=HE4387(J,WAVE,WL,DOPWL) RETURN ENDIF IF(LINE.EQ.493)THEN HE1PROF=HE4921(J,WAVE,WL,DOPWL) RETURN ENDIF 8 continue C HE1=381.96, 386.7, 392.6, 400.9, 402.3, 414.37, 416.8 if(line.eq.382.OR.LINE.EQ.387.or.line.eq.393. 1 or.line.eq.401.or.LINE.eq.403.or.LINE.EQ.415. 2 or. LINE.EQ.417)then he1prof=dimitri(j,wave,wl,DOPWL,GAMMAR,GAMMAS) RETURN endif 1 HE1PROF=GRIEM(J,WAVE,WL,DOPWL,GAMMAR,GAMMAS) RETURN END FUNCTION HE4471(J,WAVE,WL,DOPWL) PARAMETER (kw=99,mw=139,mw6=mw*6) DIMENSION WS(4),DS(4),ALFS(4),FORB1(4),FORB2(4),TS(4) COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) c REAL*8 WL,wave C STANDARD ISOLATED LINE BROADENING PARAMETERS c From Barnard,Cooper and Smith J.Q.S.R.T. 14,1025,1974 c ws=we(A),ds=de/we, alfs=alpha; data for Ne=10**13 cm(-3) DATA WS/0.001460,0.001269,0.001079,0.000898/ DATA DS/0.036,-0.005,-0.026,-0.034/ DATA ALFS/0.107,0.119,0.134,0.154/ DATA DEN/1.0E13/ c data forb1/?,7.66E-3,9.04E-3,1.01E-2/ ???? DATA FORB1/0.,0.,0.,0./ DATA FORB2/0.,0.,0.,0./ C NANOMETERS DATA DLP/0.021/ DATA DLF1/-0.150/ DATA DLF2/0./ DATA TS/ 5.0E3,1.0E4,2.0E4,4.0E4/ c c 447.1469 -2.198 2.0 169086.864 1.0 191444.603 2.002p 3P 4d 3D c 447.1469 7 9.262-3.690 NBS 415 5 c 447.1473 -1.028 2.0 169086.864 2.0 191444.585 2.002p 3P 4d 3D c 447.1473 7 -3.690 NBS 415 4 c 447.1473 -0.278 2.0 169086.864 3.0 191444.583 2.002p 3P 4d 3D c 447.1473 7 -3.690 NBS 415 4 c 447.1485 -1.028 1.0 169086.940 1.0 191444.603 2.002p 3P 4d 3D c 447.1485 7 -3.690 NBS 415 4 c 447.1488 -0.548 1.0 169086.940 2.0 191444.585 2.002p 3P 4d 3D c 447.1488 7 -3.690 NBS 415 4 c 447.1682 -0.898 0.0 169087.928 1.0 191444.603 2.002p 3P 4d 3D c 447.1682 7 -3.690 NBS 415 4 c c 447.1498 0.052 4.0 169087.008 7.0 191444.588 2.002p 3P 4d 3D c 447.1498 7 7.502 -3.69 -7.22NBS 415 4 c HE4471=0. E=XNE(J) TEMP=T(J) C NUMERO PROTONI=N(H+)/U(H+) U(H+)=1 XNFHP=XNFPH(J,2) XNFHEP=XNFHE(J,2) DL=WAVE-WL TEMP=AMAX1(TEMP,5.0E3) TEMP=AMIN1(TEMP,4.0E4) IFORB=0. DO 10 IT=1,4 IF(FORB1(IT).LE.0.)GO TO 10 IFORB=1 10 CONTINUE IF(E.LE.1.0E13)GO TO 499 CALL READBCS(1,J,TEMP,XNFHP,XNFHEP,E,DL,PHIHE) HE4471=1.772453*PHIHE*DOPWL*10. RETURN 499 CONTINUE DO 2 I=2,4 IT=I IF(TS(I).GT.TEMP)GO TO 3 2 CONTINUE 3 X=(TEMP-TS(IT-1))/(TS(IT)-TS(IT-1)) XX=E/DEN C DAMPING WIDTH W=XX*(X*WS(IT)+(1.0-X)*WS(IT-1)) C RATIO OF SHIFT TO WIDTH D=X*DS(IT)+(1.0-X)*DS(IT-1) C ION BROADENING PARAMETER ALF=XX**0.25*(X*ALFS(IT)+(1.0-X)*ALFS(IT-1)) C FORBIDDEN COMPONENTS INTENSITIES F1=XX*(X*FORB1(IT)+(1.0-X)*FORB1(IT-1)) F2=XX*(X*FORB2(IT)+(1.0-X)*FORB2(IT-1)) C RECIPROCAL PERTURBER VELOCITY C KM! XX=XNFHP/E VM1=8.78E0*(XX+2.0*(1.0-XX))/SQRT(TEMP) C MEAN INTERPARTICLE DISTANCE RHOM=1.0/(4.19*E)**(1.0/3.0) C ION VELOCITY PARAMETER SIGMA=1.885E14*W*RHOM*VM1/(WL*10.)**2 C 1.885E14=2*PAI*C*1.E8 1.E8 TRASFORMA RHOM DA CM ad A X=ALF**(8.0/9.0)/SIGMA**(1.0/3.0) C TOTAL WIDTHIS ANGSTROMS, then in nm WTOT=W*(1.0+1.36*X) wtot=wtot*0.1 C TOTAL SHIFT IN ANGSTROM, then in nm DTOT=W*D*(1.0+2.36*X/ABS(D)) dtot=dtot*0.1 C VOIGT PARAMETERS A=WTOT/DOPWL C NORMALIZATION CONSTANT c CON=0.564189583547756E0/(1.0+F1+F2)/(DOPPLE(7)*WL4) con=1. WWD=WAVE-WL-DTOT C ALLOW FOR FINE STRUCTURE SPLITTING HE4471=VOIGT(ABS(WWD-.0184)/DOPWL,A)/9.+ 1 VOIGT(ABS(WWD+.0013)/DOPWL,A)/12.+ 2 VOIGT(ABS(WWD+.0010)/DOPWL,A)/4.+ 3 VOIGT(ABS(WWD+.0029)/DOPWL,A)/180.+ 4 VOIGT(ABS(WWD+.0025)/DOPWL,A)*11./20. IF(F1.LE.0) GO TO 4 C ADD IN P TO F FORBIDDEN COMPONENT V=ABS((WAVE-WL)-DLF1)/DOPWL HE4471=HE4471+F1*VOIGT(V,A) IF(F2.LE.0) GO TO 4 C ADD P TO G FORBIDDEN COMPONENT V=ABS((WAVE-WL)-DLF2)/DOPWL HE4471=HE4471+F2*VOIGT(V,A) 4 HE4471=HE4471*CON C TYPE*,HE4471 RETURN END FUNCTION HE4026(J,WAVE,WL,DOPWL) PARAMETER (kw=99,mw=139,mw6=mw*6) DIMENSION WS(4),DS(4),ALFS(4),FORB1(4),FORB2(4),TS(4) COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) c REAL*8 WL,WAVE C STANDARD ISOLATED LINE BROADENING PARAMETERS C FROM GRIEM 1974-book-Spectral line broadening by plasmas c ws=we(A), ds=de/we, alfs=alpha, data for Ne=10**16 cm(-3) DATA WS/4.04,3.49,2.96,2.47/ DATA DS/0.1339,0.0960,0.0780,0.0709/ DATA ALFS/0.969,1.083,1.225,1.403/ DATA DEN/1.0E16/ C c data forb1/?,7.66E-3,9.04E-3,1.01E-2/ ???? DATA FORB1/0.,0.,0.,0./ DATA FORB2/0.,0.,0.,0./ C NANOMETERS DATA DLP/0.017/ DATA DLF1/-0.080/ DATA DLF2/0./ DATA TS/5000.,10000.,20000.,40000./ c c 402.6185 -2.620 2.0 169086.864 1.0 193917.253 2.002p 3P 5d 3D c 402.6185 7 7.216-3.160-7.070NBS 423 4 c 402.6187 -1.450 2.0 169086.864 2.0 193917.243 2.002p 3P 5d 3D c 402.6187 7 -3.160 NBS 423 4 c 402.6187 -0.700 2.0 169086.864 3.0 193917.243 2.002p 3P 5d 3D c 402.6187 7 -3.160 NBS 423 4 c 402.6198 -1.450 1.0 169086.940 1.0 193917.253 2.002p 3P 5d 3D c 402.6198 7 -3.160 NBS 423 4 c 402.6199 -0.970 1.0 169086.940 2.0 193917.243 2.002p 3P 5d 3D c 402.6199 7 -3.160 NBS 423 4 c 402.6358 -1.320 0.0 169087.928 1.0 193917.253 2.002p 3P 5d 3D c 402.6358 7 -3.160 NBS 423 4 c c 402.6210 -0.370 4.0 169087.008 7.0 193917.245 2.002p 3P 5d 3D c 402.6210 7 7.216 -3.16 -7.07NBS 415 4 c HE4026=0. E=XNE(J) TEMP=T(J) C NUMERO PROTONI=N(H+)/U(H+) U(H+)=1 XNFHP=XNFPH(J,2) XNFHEP=XNFHE(J,2) DL=WAVE-WL TEMP=AMAX1(TEMP,5.0E3) TEMP=AMIN1(TEMP,4.0E4) IFORB=0. DO 10 IT=1,4 IF(FORB1(IT).LE.0.)GO TO 10 IFORB=1 10 CONTINUE IF(E.LE.1.E14)GO TO 499 CALL READBCS(2,J,TEMP,XNFHP,XNFHEP,E,DL,PHIHE) HE4026=1.772453*PHIHE*DOPWL*10. RETURN 499 CONTINUE DO 2 I=2,4 IT=I IF(TS(I).GT.TEMP)GO TO 3 2 CONTINUE 3 X=(TEMP-TS(IT-1))/(TS(IT)-TS(IT-1)) XX=E/DEN C DAMPING WIDTH W=XX*(X*WS(IT)+(1.0-X)*WS(IT-1)) C RATIO OF SHIFT TO WIDTH D=X*DS(IT)+(1.0-X)*DS(IT-1) C ION BROADENING PARAMETER ALF=XX**0.25*(X*ALFS(IT)+(1.0-X)*ALFS(IT-1)) C FORBIDDEN COMPONENTS INTENSITIES F1=XX*(X*FORB1(IT)+(1.0-X)*FORB1(IT-1)) F2=XX*(X*FORB2(IT)+(1.0-X)*FORB2(IT-1)) C RECIPROCAL PERTURBER VELOCITY C KM! XX=XNFHP/E VM1=8.78E0*(XX+2.0*(1.0-XX))/SQRT(TEMP) C MEAN INTERPARTICLE DISTANCE RHOM=1.0/(4.19*E)**(1.0/3.0) C ION VELOCITY PARAMETER SIGMA=1.885E14*W*RHOM*VM1/(WL*10.)**2 C 1.885E14=2*PAI*C*1.E8 1.E8 TRASFORMA RHOM DA CM ad A X=ALF**(8.0/9.0)/SIGMA**(1.0/3.0) C TOTAL WIDTHIS ANGSTROMS, then in nm WTOT=W*(1.0+1.36*X) wtot=wtot*0.1 C TOTAL SHIFT IN ANGSTROM, then in nm DTOT=W*D*(1.0+2.36*X/ABS(D)) dtot=dtot*0.1 C VOIGT PARAMETERS A=WTOT/DOPWL C NORMALIZATION CONSTANT c CON=0.564189583547756E0/(1.0+F1+F2)/(DOPPLE(7)*WL4) con=1. WWD=WAVE-WL-DTOT C ALLOW FOR FINE STRUCTURE SPLITTING HE4026=VOIGT(ABS(WWD-.0148)/DOPWL,A)/9.+ 1 VOIGT(ABS(WWD+.0012)/DOPWL,A)/12.+ 2 VOIGT(ABS(WWD+.0011)/DOPWL,A)/4.+ 3 VOIGT(ABS(WWD+.0025)/DOPWL,A)/180.+ 4 VOIGT(ABS(WWD+.0023)/DOPWL,A)*11./20. IF(F1.LE.0) GO TO 4 C ADD IN P TO F FORBIDDEN COMPONENT V=ABS((WAVE-WL)-DLF1)/DOPWL HE4026=HE4026+F1*VOIGT(V,A) IF(F2.LE.0) GO TO 4 C ADD P TO G FORBIDDEN COMPONENT V=ABS((WAVE-WL)-DLF2)/DOPWL HE4026=HE4026+F2*VOIGT(V,A) 4 HE4026=HE4026*CON C TYPE*,HE4026 RETURN END FUNCTION HE4387(J,WAVE,WL,DOPWL) PARAMETER (kw=99,mw=139,mw6=mw*6) DIMENSION WS(4),DS(4),ALFS(4),FORB1(4),FORB2(4),TS(4) COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) c REAL*8 WL,WAVE C STANDARD ISOLATED LINE BROADENING PARAMETERS C FROM GRIEM DATA WS/6.13,5.15,4.24,3.45/ DATA DS/0.411,0.363,0.325,0.293/ DATA ALFS/1.159,1.321,1.527,1.783/ DATA DEN/1.0E16/ C c data forb1/?,7.66E-3,9.04E-3,1.01E-2/ ???? DATA FORB1/0.,0.,0.,0./ DATA FORB2/0.,0.,0.,0./ C NANOMETERS DATA DLP/0.017/ DATA DLF1/-0.080/ DATA DLF2/0./ DATA TS/5000.,10000.,20000.,40000./ c 438.7929 -0.883 1.0 171135.000 2.0 193918.391 2.002p 1P 5d 1D c 438.7929 7 9.258-3.080 NBS 524 5 HE4387=0. E=XNE(J) TEMP=T(J) C NUMERO PROTONI=N(H+)/U(H+) U(H+)=1 XNFHP=XNFPH(J,2) XNFHEP=XNFHE(J,2) DL=WAVE-WL TEMP=AMAX1(TEMP,5.0E3) TEMP=AMIN1(TEMP,4.0E4) IFORB=0. DO 10 IT=1,4 IF(FORB1(IT).LE.0.)GO TO 10 IFORB=1 10 CONTINUE IF(E.LE.1.E14)GO TO 499 CALL READBCS(3,J,TEMP,XNFHP,XNFHEP,E,DL,PHIHE) HE4387=1.772453*PHIHE*DOPWL*10. RETURN 499 CONTINUE DO 2 I=2,4 IT=I IF(TS(I).GT.TEMP)GO TO 3 2 CONTINUE 3 X=(TEMP-TS(IT-1))/(TS(IT)-TS(IT-1)) XX=E/DEN C DAMPING WIDTH W=XX*(X*WS(IT)+(1.0-X)*WS(IT-1)) C RATIO OF SHIFT TO WIDTH D=X*DS(IT)+(1.0-X)*DS(IT-1) C ION BROADENING PARAMETER ALF=XX**0.25*(X*ALFS(IT)+(1.0-X)*ALFS(IT-1)) C FORBIDDEN COMPONENTS INTENSITIES F1=XX*(X*FORB1(IT)+(1.0-X)*FORB1(IT-1)) F2=XX*(X*FORB2(IT)+(1.0-X)*FORB2(IT-1)) C RECIPROCAL PERTURBER VELOCITY C KM! XX=XNFHP/E VM1=8.78E0*(XX+2.0*(1.0-XX))/SQRT(TEMP) C MEAN INTERPARTICLE DISTANCE RHOM=1.0/(4.19*E)**(1.0/3.0) C ION VELOCITY PARAMETER SIGMA=1.885E14*W*RHOM*VM1/(WL*10.)**2 C 1.885E14=2*PAI*C*1.E8 1.E8 TRASFORMA RHOM DA CM ad A X=ALF**(8.0/9.0)/SIGMA**(1.0/3.0) C TOTAL WIDTHIS ANGSTROMS, then in nm WTOT=W*(1.0+1.36*X) wtot=wtot*0.1 C TOTAL SHIFT IN ANGSTROM, then in nm DTOT=W*D*(1.0+2.36*X/ABS(D)) dtot=dtot*0.1 C VOIGT PARAMETERS A=WTOT/DOPWL C NORMALIZATION CONSTANT c CON=0.564189583547756E0/(1.0+F1+F2)/(DOPWL) con=1. HE4387=VOIGT(ABS(WAVE-WL-DTOT)/DOPWL,A) RETURN END FUNCTION HE4921(J,WAVE,WL,DOPWL) PARAMETER (kw=99,mw=139,mw6=mw*6) DIMENSION WS(4),DS(4),ALFS(4),FORB1(4),FORB2(4),TS(4) COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) c REAL*8 WL,wave C STANDARD ISOLATED LINE BROADENING PARAMETERS c From Barnard,Cooper and Smith J.Q.S.R.T. 15, 429, 1975 c ws=we(A),ds=de/we, alfs=alpha; data for Ne=10**13 cm(-3) DATA WS/0.002312,0.001963,0.001624,0.001315/ DATA DS/0.3932,0.3394,0.2950,0.2593/ DATA ALFS/0.1207,0.1365,0.1564,0.1844/ DATA DEN/1.0E13/ c data forb1/?,7.66E-3,9.04E-3,1.01E-2/ ???? DATA FORB1/0.,0.,0.,0./ DATA FORB2/0.,0.,0.,0./ C NANOMETERS DATA DLP/0.021/ DATA DLF1/-0.150/ DATA DLF2/0./ DATA TS/ 5.0E3,1.0E4,2.0E4,4.0E4/ c c 492.1931 -0.435 1.0 171135.000 2.0 191446.559 2.002p 1P 4d 1D c 492.1931 7 9.262-3.600 NBS 516 5 c HE4921=0. E=XNE(J) TEMP=T(J) C NUMERO PROTONI=N(H+)/U(H+) U(H+)=1 XNFHP=XNFPH(J,2) XNFHEP=XNFHE(J,2) DL=WAVE-WL TEMP=AMAX1(TEMP,5.0E3) TEMP=AMIN1(TEMP,4.0E4) IFORB=0. DO 10 IT=1,4 IF(FORB1(IT).LE.0.)GO TO 10 IFORB=1 10 CONTINUE IF(E.LE.1.0E13)GO TO 499 CALL READBCS(4,J,TEMP,XNFHP,XNFHEP,E,DL,PHIHE) HE4921=1.772453*PHIHE*DOPWL*10. RETURN 499 CONTINUE DO 2 I=2,4 IT=I IF(TS(I).GT.TEMP)GO TO 3 2 CONTINUE 3 X=(TEMP-TS(IT-1))/(TS(IT)-TS(IT-1)) XX=E/DEN C DAMPING WIDTH W=XX*(X*WS(IT)+(1.0-X)*WS(IT-1)) C RATIO OF SHIFT TO WIDTH D=X*DS(IT)+(1.0-X)*DS(IT-1) C ION BROADENING PARAMETER ALF=XX**0.25*(X*ALFS(IT)+(1.0-X)*ALFS(IT-1)) C FORBIDDEN COMPONENTS INTENSITIES F1=XX*(X*FORB1(IT)+(1.0-X)*FORB1(IT-1)) F2=XX*(X*FORB2(IT)+(1.0-X)*FORB2(IT-1)) C RECIPROCAL PERTURBER VELOCITY C KM! XX=XNFHP/E VM1=8.78E0*(XX+2.0*(1.0-XX))/SQRT(TEMP) C MEAN INTERPARTICLE DISTANCE RHOM=1.0/(4.19*E)**(1.0/3.0) C ION VELOCITY PARAMETER SIGMA=1.885E14*W*RHOM*VM1/(WL*10.)**2 C 1.885E14=2*PAI*C*1.E8 1.E8 TRASFORMA RHOM DA CM ad A X=ALF**(8.0/9.0)/SIGMA**(1.0/3.0) C TOTAL WIDTHIS ANGSTROMS, then in nm WTOT=W*(1.0+1.36*X) wtot=wtot*0.1 C TOTAL SHIFT IN ANGSTROM, then in nm DTOT=W*D*(1.0+2.36*X/ABS(D)) dtot=dtot*0.1 C VOIGT PARAMETERS A=WTOT/DOPWL C NORMALIZATION CONSTANT c CON=0.564189583547756E0/(1.0+F1+F2)/(DOPPLE(7)*WL4) con=1. WWD=WAVE-WL-DTOT C ALLOW FOR FINE STRUCTURE SPLITTING HE4921=VOIGT(ABS(WWD)/DOPWL,A) IF(F1.LE.0) GO TO 4 C ADD IN P TO F FORBIDDEN COMPONENT V=ABS((WAVE-WL)-DLF1)/DOPWL HE4921=HE4921+F1*VOIGT(V,A) IF(F2.LE.0) GO TO 4 C ADD P TO G FORBIDDEN COMPONENT V=ABS((WAVE-WL)-DLF2)/DOPWL HE4921=HE4921+F2*VOIGT(V,A) 4 HE4921=HE4921*CON C TYPE*,HE4921 RETURN END FUNCTION GRIEM(J,WAVESYN,WL,DOPWL,GAMMAR,GAMMAS) PARAMETER (kw=99,mw=139,mw6=mw*6) DIMENSION WS(4),DS(4),ALFS(4),FORB1(4),FORB2(4),TS(4) COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) c REAL*8 WL,WAVESYN DIMENSION WIDTH(4,999),SHIFT(4,999),ALPHA(4,999),BETA(4,999) DIMENSION CODE(999),XNELOG(999),TTAB(4,999),WAVE(999) CHARACTER*10 TRANS(999) CHARACTER*60 GRIEM0200(210) DATA (GRIEM0200(I),I= 1, 5)/ 1' 2.00 52.2213 1s1S-4p1P 16.0 ', 2' 5000. .0179 -.0112 .275 .000016 ', 3' 10000. .0168 -.00872 .290 .000032 ', 4' 20000. .0152 -.00647 .311 .000064 ', 5' 40000. .0135 -.00460 .341 .00013 '/ DATA (GRIEM0200(I),I= 6, 10)/ 1' 2.00 53.7030 1s1S-3p1P 16.0 ', 2' 5000. .00432 -.00277 .153 .000054 ', 3' 10000. .00409 -.00216 .160 .00011 ', 4' 20000. .00378 -.00159 .169 .00022 ', 5' 40000. .00341 -.00111 .183 .00043 '/ DATA (GRIEM0200(I),I= 11, 15)/ 1' 2.00 58.4334 1s1S-2p1P 16.0 ', 2' 5000. .000121 -.0000299 .012 .0024 ', 3' 10000. .000158 -.00000567 .010 .0049 ', 4' 20000. .000199 .0000220 .008 .0098 ', 5' 40000. .000234 .0000460 .007 .020 '/ DATA (GRIEM0200(I),I= 16, 20)/ 1' 2.00 282.9076 2s3S-6p3P 16.0 ', 2' 5000. 1.79 1.07 .285 .0014 ', 3' 10000. 1.87 .829 .276 .0027 ', 4' 20000. 1.84 .619 .279 .0054 ', 5' 40000. 1.72 .455 .294 .011 '/ DATA (GRIEM0200(I),I= 21, 25)/ 1' 2.00 294.5104 2s3S-5p3P 16.0 ', 2' 5000. .808 .522 .204 .0030 ', 3' 10000. .857 .412 .195 .0059 ', 4' 20000. .857 .311 .195 .012 ', 5' 40000. .811 .231 .203 .024 '/ DATA (GRIEM0200(I),I= 26, 30)/ 1' 2.00 318.7746 2s3S-4p3P 16.0 ', 2' 5000. .313 .219 .134 .0087 ', 3' 10000. .338 .176 .127 .017 ', 4' 20000. .344 .134 .125 .035 ', 5' 40000. .332 .101 .128 .069 '/ DATA (GRIEM0200(I),I= 31, 35)/ 1' 2.00 388.8649 2s3S-3p3P 16.0 ', 2' 5000. .102 .0744 .075 .050 ', 3' 10000. .112 .0603 .070 .099 ', 4' 20000. .117 .0464 .067 .20 ', 5' 40000. .117 .0348 .067 .40 '/ DATA (GRIEM0200(I),I= 36, 40)/ 1' 2.00 396.4729 2s1S-4p1P 16.0 ', 2' 5000. 1.03 -.697 .275 .0071 ', 3' 10000. .996 -.504 .290 .014 ', 4' 20000. .877 -.374 .311 .028 ', 5' 40000. .776 -.266 .341 .056 '/ DATA (GRIEM0200(I),I= 41, 45)/ 1' 2.00 402.6187 2p3P-5d3D 16.0 ', 2' 5000. 4.04 .541 .969 .0016 ', 3' 10000. 3.49 .335 1.083 .0033 ', 4' 20000. 2.96 .231 1.225 .0066 ', 5' 40000. 2.47 .175 1.403 .013 '/ DATA (GRIEM0200(I),I= 46, 50)/ 1' 2.00 412.0811 2p3P-5s3S 16.0 ', 2' 5000. .785 .897 .171 .013 ', 3' 10000. .897 .894 .155 .026 ', 4' 20000. .984 .808 .144 .052 ', 5' 40000. 1.01 .670 .141 .10 '/ DATA (GRIEM0200(I),I= 51, 55)/ 1' 2.00 438.7929 2p1P-5d1D 16.0 ', 2' 5000. 6.13 2.52 1.159 .0017 ', 3' 10000. 5.15 1.87 1.321 .0033 ', 4' 20000. 4.24 1.38 1.527 .0067 ', 5' 40000. 3.45 1.01 1.783 .013 '/ DATA (GRIEM0200(I),I= 56, 60)/ 1' 2.00 443.7551 2p1P-5s1S 16.0 ', 2' 5000. 1.41 1.51 .199 .012 ', 3' 10000. 1.57 1.43 .184 .024 ', 4' 20000. 1.65 1.24 .177 .047 ', 5' 40000. 1.62 .996 .179 .094 '/ DATA (GRIEM0200(I),I= 61, 65)/ 1' 2.00 447.1488 2p3P-4d3D 16.0 ', 2' 5000. 1.44 .136 .589 .0058 ', 3' 10000. 1.26 .0804 .650 .012 ', 4' 20000. 1.09 .0614 .726 .023 ', 5' 40000. .927 .0549 .819 .047 '/ DATA (GRIEM0200(I),I= 66, 70)/ 1' 2.00 471.3139 2p3P-4s3S 16.0 ', 2' 5000. .342 .402 .115 .044 ', 3' 10000. .393 .416 .103 .088 ', 4' 20000. .437 .390 .095 .18 ', 5' 40000. .459 .335 .092 .35 '/ DATA (GRIEM0200(I),I= 71, 75)/ 1' 2.00 492.1931 2p1P-4d1D 16.0 ', 2' 5000. 2.30 1.02 .683 .0061 ', 3' 10000. 1.96 .773 .773 .012 ', 4' 20000. 1.63 .584 .885 .024 ', 5' 40000. 1.35 .440 1.023 .049 '/ DATA (GRIEM0200(I),I= 76, 80)/ 1' 2.00 501.5678 2s1S-3p1P 16.0 ', 2' 5000. .378 -.250 .154 .044 ', 3' 10000. .359 -.200 .160 .088 ', 4' 20000. .334 -.152 .169 .18 ', 5' 40000. .306 -.111 .180 .35 '/ DATA (GRIEM0200(I),I= 81, 85)/ 1' 2.00 504.7738 2p1P-4s1S 16.0 ', 2' 5000. .625 .699 .134 .038 ', 3' 10000. .705 .685 .123 .077 ', 4' 20000. .756 .611 .117 .15 ', 5' 40000. .760 .504 .116 .31 '/ DATA (GRIEM0200(I),I= 86, 90)/ 1' 2.00 587.5615 2p3P-3d3D 16.0 ', 2' 5000. .159 -.0881 .064 .23 ', 3' 10000. .170 -.0553 .061 .46 ', 4' 20000. .176 -.0256 .059 .92 ', 5' 40000. .177 -.00504 .059 1.8 '/ DATA (GRIEM0200(I),I= 91, 95)/ 1' 2.00 667.8154 2p1P-3d1D 16.0 ', 2' 5000. .423 .275 .146 .14 ', 3' 10000. .386 .233 .157 .27 ', 4' 20000. .349 .196 .169 .54 ', 5' 40000. .318 .161 .181 1.1 '/ DATA (GRIEM0200(I),I= 96,100)/ 1' 2.00 706.5176 2p3P-3s3S 16.0 ', 2' 5000. .180 .215 .067 .44 ', 3' 10000. .207 .231 .060 .87 ', 4' 20000. .235 .227 .055 1.7 ', 5' 40000. .254 .203 .052 3.5 '/ DATA (GRIEM0200(I),I=101,105)/ 1' 2.00 728.1349 2p1P-3s1S 16.0 ', 2' 5000. .320 .374 .081 .33 ', 3' 10000. .365 .382 .073 .65 ', 4' 20000. .403 .355 .068 1.3 ', 5' 40000. .419 .303 .066 2.6 '/ DATA (GRIEM0200(I),I=106,110)/ 1' 2.00 836.1694 3s3S-6p3P 16.0 ', 2' 5000. 15.6 9.33 .285 .035 ', 3' 10000. 16.3 7.23 .276 .070 ', 4' 20000. 16.1 5.38 .279 .14 ', 5' 40000. 15.0 3.93 .293 .28 '/ DATA (GRIEM0200(I),I=111,115)/ 1' 2.00 946.3596 3s3S-5p3P 16.0 ', 2' 5000. 8.34 5.30 .203 .099 ', 3' 10000. 8.86 4.13 .194 .20 ', 4' 20000. 8.88 3.06 .194 .40 ', 5' 40000. 8.46 2.21 .201 .79 '/ DATA (GRIEM0200(I),I=116,120)/ 1' 2.00 960.3418 3s1S-6p1P 16.0 ', 2' 5000. 40.7 -24.0 .614 .023 ', 3' 10000. 37.3 -18.5 .656 .045 ', 4' 20000. 33.2 -13.7 .716 .091 ', 5' 40000. 28.8 -9.94 .796 .18 '/ DATA (GRIEM0200(I),I=121,125)/ 1' 2.00 1066.7641 3p3P-6s3S 16.0 ', 2' 5000. 12.9 14.2 .238 .12 ', 3' 10000. 14.7 13.9 .217 .23 ', 4' 20000. 16.0 12.4 .203 .46 ', 5' 40000. 16.5 10.3 .198 .92 '/ DATA (GRIEM0200(I),I=126,130)/ 1' 2.00 1083.0336 2s3S-2p3P 16.0 ', 2' 5000. .0493 -.0518 .028 8.3 ', 3' 10000. .0601 -.0557 .024 17. ', 4' 20000. .0755 -.0540 .020 33. ', 5' 40000. .0931 -.0465 .017 66. '/ DATA (GRIEM0200(I),I=131,135)/ 1' 2.00 1099.6561 3d3D-6p3P 16.0 ', 2' 5000. 27.0 16.3 .286 .08 ', 3' 10000. 28.3 12.8 .276 .16 ', 4' 20000. 27.9 9.59 .279 .32 ', 5' 40000. 26.1 7.10 .294 .64 '/ DATA (GRIEM0200(I),I=136,140)/ 1' 2.00 1101.3070 3s1S-5p1P 16.0 ', 2' 5000. 23.1 -14.3 .429 .066 ', 3' 10000. 21.4 -11.2 .454 .13 ', 4' 20000. 19.3 -8.49 .491 .26 ', 5' 40000. 16.9 -6.24 .541 .53 '/ DATA (GRIEM0200(I),I=141,145)/ 1' 2.00 1104.5003 3p1P-6d1D 16.0 ', 2' 5000. 94.5 37.7 1.742 .013 ', 3' 10000. 79.0 27.8 1.992 .026 ', 4' 20000. 64.8 20.4 2.310 .052 ', 5' 40000. 52.5 14.9 2.706 .10 '/ DATA (GRIEM0200(I),I=146,150)/ 1' 2.00 1196.9060 3p3P-5d3D 16.0 ', 2' 5000. 35.8 4.42 .967 .043 ', 3' 10000. 31.0 2.56 1.077 .086 ', 4' 20000. 26.4 1.65 1.215 .17 ', 5' 40000. 22.1 1.20 1.387 .34 '/ DATA (GRIEM0200(I),I=151,155)/ 1' 2.00 1252.7537 3s3S-4p3P 16.0 ', 2' 5000. 4.83 3.09 .130 .54 ', 3' 10000. 5.26 2.34 .122 1.1 ', 4' 20000. 5.45 1.65 .119 2.1 ', 5' 40000. 5.37 1.12 .120 4.3 '/ DATA (GRIEM0200(I),I=156,160)/ 1' 2.00 1284.5935 3p3P-5s3S 16.0 ', 2' 5000. 7.61 8.33 .165 .40 ', 3' 10000. 8.85 8.26 .147 .81 ', 4' 20000. 9.85 7.44 .136 1.6 ', 5' 40000. 10.3 6.17 .132 3.2 '/ DATA (GRIEM0200(I),I=161,165)/ 1' 2.00 1296.8439 3p1P-5d1D 16.0 ', 2' 5000. 54.3 23.1 1.149 .043 ', 3' 10000. 45.9 17.3 1.304 .086 ', 4' 20000. 38.1 12.8 1.501 .17 ', 5' 40000. 31.1 9.45 1.745 .34 '/ DATA (GRIEM0200(I),I=166,170)/ 1' 2.00 1298.4882 3d3D-5p3P 16.0 ', 2' 5000. 15.8 10.4 .205 .25 ', 3' 10000. 16.8 8.24 .196 .51 ', 4' 20000. 16.8 6.27 .195 1.0 ', 5' 40000. 16.0 4.65 .203 2.0 '/ DATA (GRIEM0200(I),I=171,175)/ 1' 2.00 1508.3656 3s1S-4p1P 16.0 ', 2' 5000. 15.1 -10.2 .277 .38 ', 3' 10000. 14.3 -8.34 .289 .77 ', 4' 20000. 13.2 -6.55 .307 1.5 ', 5' 40000. 11.9 -4.95 .331 3.1 '/ DATA (GRIEM0200(I),I=176,180)/ 1' 2.00 1700.2364 3p3P-4d3D 16.0 ', 2' 5000. 21.2 .993 .577 .32 ', 3' 10000. 18.9 .216 .629 .64 ', 4' 20000. 16.7 .0624 .692 1.3 ', 5' 40000. 14.5 .129 .769 2.6 '/ DATA (GRIEM0200(I),I=181,185)/ 1' 2.00 1868.5313 3d3D-4f3F 16.0 ', 2' 5000. 16.2 -2.77 .650 .50 ', 3' 10000. 13.7 -1.22 .734 .99 ', 4' 20000. 11.8 -.300 .823 2.0 ', 5' 40000. 10.2 .131 .914 4.0 '/ DATA (GRIEM0200(I),I=186,190)/ 1' 2.00 1869.7233 3d1D-4f1F 16.0 ', 2' 5000. 18.6 -5.39 .756 .42 ', 3' 10000. 15.6 -3.35 .862 .84 ', 4' 20000. 13.2 -1.95 .978 1.7 ', 5' 40000. 11.3 -1.10 1.101 3.4 '/ DATA (GRIEM0200(I),I=191,195)/ 1' 2.00 1908.9369 3p1P-4d1D 16.0 ', 2' 5000. 37.3 18.1 .657 .35 ', 3' 10000. 32.3 14.0 .732 .71 ', 4' 20000. 27.4 10.7 .828 1.4 ', 5' 40000. 23.0 8.03 .945 2.8 '/ DATA (GRIEM0200(I),I=196,200)/ 1' 2.00 1954.3172 3d3D-4p3P 16.0 ', 2' 5000. 12.2 8.91 .137 1.9 ', 3' 10000. 13.2 7.25 .128 3.9 ', 4' 20000. 13.6 5.56 .126 7.7 ', 5' 40000. 13.3 4.11 .128 15. '/ DATA (GRIEM0200(I),I=201,205)/ 1' 2.00 2058.1299 2s1S-2p1P 16.0 ', 2' 5000. .364 -.412 .038 33. ', 3' 10000. .433 -.430 .033 65. ', 4' 20000. .514 -.400 .029 130. ', 5' 40000. .590 -.332 .026 260. '/ DATA (GRIEM0200(I),I=206,210)/ 1' 2.00 2112.0002 3p3P-4s3S 16.0 ', 2' 5000. 7.17 6.48 .089 4.6 ', 3' 10000. 8.76 6.78 .077 9.2 ', 4' 20000. 10.1 6.47 .069 18. ', 5' 40000. 10.9 5.62 .065 37. '/ DATA IREAD/0/ IF(IREAD.EQ.1)GO TO 10 C DO 5 ILINE=1,999 C READ(21,3,END=7)CODE(iline),WAVE(iline),TRANS(iline), C 1 XNELOG(iline), (TTAB(I,iline),WIDTH(I,iline),SHIFT(I,iline), C 2 ALPHA(I,iline), BETA(I,iline),I=1,4) C PRINT 3,CODE(iline),WAVE(iline),TRANS(iline), C 1 XNELOG(iline), (TTAB(I,iline),WIDTH(I,iline),SHIFT(I,iline), C 2 ALPHA(I,iline), BETA(I,iline),I=1,4) C 3 FORMAT(F5.2,F10.4,A10,F5.1,F10.0,4F10.6/30X,F10.0,4F10.6/ C 2 30X,F10.0,4F10.6/30X,F10.0,4F10.6) C C 2.00 52.2213 1s1S-4p1P 16.0 5000. .0179 -.0112 .275 .000016 C 10000. .0168 -.00872 .290 .000032 C 20000. .0152 -.00647 .311 .000064 C 40000. .0135 -.00460 .341 .00013 C C 5 CONTINUE C 7 NLINE=ILINE-1 NLINE=42 DO 5 ILINE=1,NLINE READ(GRIEM0200(ILINE*5-4),3)CODE(iline),WAVE(iline),TRANS(iline), 1XNELOG(iline) 3 FORMAT(F5.2,F10.4,A10,F5.1,F10.0,4F10.6) DO 5 I=1,4 READ(GRIEM0200(ILINE*5-4+I),4)TTAB(I,iline),WIDTH(I,iline), 1 SHIFT(I,iline),ALPHA(I,iline), BETA(I,iline) 5 SHIFT(I,ILINE)=SHIFT(I,ILINE)/WIDTH(I,ILINE) 4 FORMAT(F10.0,4F10.6) IREAD=1 10 CONTINUE DO 11 ILINE=1,NLINE IF(WL.GT.WAVE(ILINE)-.1.AND.WL.LT.WAVE(ILINE)+.1)GO TO 12 11 CONTINUE V=ABS(WAVESYN-WL)/DOPWL C WANT DOPPLE(7) BUT DOES NOT INCLUDE ISOTOPIC MASS DOPWL/WL DOES A=(GAMMAR+GAMMAS*XNE(J))/(DOPWL/WL) GRIEM=VOIGT(V,A) RETURN 12 IL=ILINE E=XNE(J) TEMP=T(J) C NUMERO PROTONI=N(H+)/U(H+) U(H+)=1 XNFHP=XNFPH(J,2) XNFHEP=XNFHE(J,2) DL=WAVESYN-WL TEMP=AMAX1(TEMP,5.0E3) TEMP=AMIN1(TEMP,8.0E4) c DO 2 I=2,5 DO 2 I=2,4 IT=I IF(Ttab(It,il).GT.TEMP)GO TO 33 2 CONTINUE 33 X=(TEMP-Ttab(IT-1,il))/(Ttab(IT,il)-Ttab(IT-1,il)) XX=E/(10.**xnelog(il)) C DAMPING WIDTH W=XX*(X*Width(IT,il)+(1.0-X)*Width(IT-1,il)) C RATIO OF SHIFT TO WIDTH D=X*shift(IT,il)+(1.0-X)*shift(IT-1,il) C ION BROADENING PARAMETER ALF=XX**0.25*(X*ALpha(IT,il)+(1.0-X)*ALpha(IT-1,il)) C RECIPROCAL PERTURBER VELOCITY C KM! XX=XNFHP/E VM1=8.78E0*(XX+2.0*(1.0-XX))/SQRT(TEMP) C MEAN INTERPARTICLE DISTANCE RHOM=1.0/(4.19*E)**(1.0/3.0) C ION VELOCITY PARAMETER SIGMA=1.885E14*W*RHOM*VM1/(WL*10.)**2 C 1.885E14=2*PAI*C*1.E8 1.E8 TRASFORMA RHOM DA CM ad A X=ALF**(8.0/9.0)/SIGMA**(1.0/3.0) C TOTAL WIDTHIS ANGSTROMS, then in nm WTOT=W*(1.0+1.36*X) wtot=wtot*0.1 C TOTAL SHIFT IN ANGSTROM, then in nm DTOT=W*D*(1.0+2.36*X/ABS(D)) dtot=dtot*0.1 C VOIGT PARAMETERS C WANT DOPPLE(7) FOR GAMMAR BUT DOES NOT INCLUDE ISOTOPIC MASS DOPWL/WL DOES A=WTOT/DOPWL+GAMMAR/(DOPWL/WL) C NORMALIZATION CONSTANT c CON=0.564189583547756E0/(1.0+F1+F2)/DOPWL con=1. WWD=WAVESYN-WL-DTOT GRIEM=VOIGT(ABS(WWD)/DOPWL,A) RETURN END FUNCTION DIMITRI(J,WAVEsyn,WL,DOPWL,GAMMAR,GAMMAS) PARAMETER (kw=99,mw=139,mw6=mw*6) DIMENSION WS(4),DS(4),ALFS(4),FORB1(4),FORB2(4),TS(4) COMMON /STATE/P(kw),XNE(kw),XNATOM(kw),RHO(kw),PTOTAL(kw) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP COMMON /XNFDOP/XNFPEL(mw6),DOPPLE(mw6),XNFDOP(mw6) COMMON /BHE/BHE1(kw,29),AHE1(kw),SHE1(kw),BHE2(kw,6),AHE2(kw), 1 SHE2(kw),AHEMIN(kw),SIGHE(kw),XNFPHE(kw,3),XNFHE(kw,2) COMMON /BHYD/BHYD(kw,8),AHYD(kw),SHYD(kw),AH2P(kw),BMIN(kw), 1 AHMIN(kw),SHMIN(kw),SIGH(kw),SIGH2(kw),AHLINE(kw), 2 SHLINE(kw),XNFPH(kw,2),XNFH(kw) c REAL*8 WL,wavesyn DIMENSION WIDTH(4,999),SHIFT(4,999),WIDTHP(4,999),SHIFTP(4,999), 1 WIDTHHE(4,999),SHIFTHE(4,999) dimension CODE(999),XNELOG(999),TTAB(4,999),wave(999),gam(999) DIMENSION XNETAB(7) CHARACTER*10 TRANS(999) CHARACTER*61 DIMITRI0200(35) DATA (DIMITRI0200(I),I= 1, 5)/ 1' 2.00 381.9624 2p3P-6d3D 13.0 ', 2' 5000. 1.47E-02-2.04E-04 9.31E-03 7.87E-03 0.00E+00 0.00E+00', 3' 10000. 1.29E-02-4.41E-05 1.06E-02 9.31E-03 8.90E-03 7.72E-03', 4' 20000. 1.10E-02-1.37E-04 1.72E-02 1.13E-02 1.02E-02 8.99E-03', 5' 40000. 9.33E-03-2.31E-05 1.08E-02 1.32E-02 1.13E-02 1.06E-02'/ c DATA (DIMITRI0200(I),I= 6, 10)/ c 1' 2.00 386.7494 2p3P-6s3S 13.0 ', c 2' 5000. 2.74E-03 2.09E-03 6.15E-04 5.72E-04 5.29E-04 4.90E-04', c 3' 10000. 2.91E-03 2.02E-03 6.91E-04 6.48E-04 5.93E-04 5.55E-04', c 4' 20000. 2.85E-03 1.58E-03 7.75E-04 7.29E-04 6.66E-04 6.25E-04', c 5' 40000. 3.10E-03 1.10E-03 8.71E-04 8.20E-04 7.48E-04 7.04E-04'/ c DATA (DIMITRI0200(I),I= 6, 10)/ c 1' 2.00 386.7494 2p3P-6s3S 13.0 ', c 2' 5000. 2.74E-03 1.79E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', c 3' 10000. 2.91E-03 1.86E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', c 4' 20000. 2.85E-03 1.51E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', c 5' 40000. 3.10E-03 1.10E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00'/ DATA (DIMITRI0200(I),I= 6, 10)/ 1' 2.00 386.7494 2p3P-6s3S 16.0 ', 2' 5000. 2.74E+00 1.79E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 3' 10000. 2.91E+00 1.86E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 4' 20000. 2.85E+00 1.51E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 5' 40000. 3.10E+00 1.10E+00 0.00E+00 0.00E+00 0.00E+00 0.00E+00'/ DATA (DIMITRI0200(I),I= 11, 15)/ 1' 2.00 392.6544 2p1P-6d1D 13.0 ', 2' 5000 7.07E-02 7.13E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 3' 10000. 6.07E-02 4.27E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 4' 20000. 5.09E-02 1.96E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 5' 40000. 4.19E-02 5.60E-04 0.00E+00 0.00E+00 0.00E+00 0.00E+00'/ DATA (DIMITRI0200(I),I= 16, 20)/ 1' 2.00 400.9256 2p1P-7d1D 13.0 ', 2' 5000 3.96E-02 6.23E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 3' 10000. 3.42E-02 2.78E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 4' 20000. 2.88E-02 1.85E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 5' 40000. 2.38E-02 1.07E-03 3.05E-02 3.67E-02 0.00E+00 0.00E+00'/ DATA (DIMITRI0200(I),I= 21, 25)/ 1' 2.00 402.40 2p1P-7s1S 13.0 ', 2' 5000 9.24E-03 6.25E-03 2.09E-03 1.91E-03 1.79E-03 1.63E-03', 3' 10000. 8.80E-03 5.30E-03 2.34E-03 2.17E-03 2.01E-03 1.86E-03', 4' 20000. 9.18E-03 3.77E-03 2.63E-03 2.46E-03 2.42E-03 2.72E-03', 5' 40000. 9.19E-03 2.32E-03 2.96E-03 2.77E-03 2.54E-03 2.38E-03'/ DATA (DIMITRI0200(I),I= 26, 30)/ 1' 2.00 414.3759 2p1P-6d1D 13.0 ', 2' 5000. 2.21E-02 3.63E-03 0.00E+00 0.00E+00 0.00E+00 0.00E+00', 3' 10000. 1.90E-02 2.37E-03 1.85E-02 1.67E-02 0.00E+00 0.00E+00', 4' 20000. 1.59E-02 1.12E-03 1.87E-02 1.96E-02 0.00E+00 0.00E+00', 5' 40000. 1.31E-02 6.75E-04 1.65E-02 2.16E-02 1.89E-02 1.90E-02'/ DATA (DIMITRI0200(I),I= 31, 35)/ 1' 2.00 416.8972 2p1P-6s1S 13.0 ', 2' 5000. 4.83E-03 3.41E-03 1.08E-03 1.00E-03 9.29E-04 8.57E-04', 3' 10000. 4.72E-03 3.06E-03 1.21E-03 1.13E-03 1.04E-03 9.72E-04', 4' 20000. 4.84E-03 2.27E-03 1.36E-03 1.28E-03 1.17E-03 1.10E-03', 5' 40000. 4.97E-03 1.55E-03 1.53E-03 1.44E-03 1.32E-03 1.24E-03'/ DATA IREAD/0/ wl4=sngl(wl) wavesyn4=sngl(wavesyn) IF(IREAD.EQ.1)GO TO 10 c shift=d cc DO 5 ILINE=1,69 cc read(20,134)n,wave(iline),gam(iline) 134 format(i5,f10.1,f10.3) cc k=1 cc read(20,133)xnetab(k) c type*,k,xnetab(k) 133 FORMAT(10X,E7.1) C READ(20,3)TRANS(i,iline),(TTAB(I,iline),WIDTH(I,iline), C 1 SHIFT(I,iline),WIDTHP(I,iline),SHIFTP(I,iline), C 2 WIDTHHE(I,iline), SHIFTHE(I,iline),i=1,6) C 3 FORMAT(5x,A10,F8.0,6(1X,E10.2)/15x,f8.0,6(1x,e10.2)/15x, C 1 f8.0,6(1x,e10.2)/15x,f8.0,6(1x,e10.2)/15x,f8.0, C 2 6(1x,e10.2)/15x,f8.0,6(1x,e10.2)) C xnelog(iline)=alog10(xnetab(k)) NLINE=7 DO 5 ILINE=1,NLINE READ(DIMITRI0200(ILINE*5-4),3)CODE(ILINE),WAVE(ILINE), 1 TRANS(ILINE), XNELOG(ILINE) 3 FORMAT(F5.2,F10.4,A10,F5.1,31x) DO 5 I=1,4 READ(DIMITRI0200(ILINE*5-4+I),4)TTAB(I,ILINE),WIDTH(I,ILINE), 1 SHIFT(I,ILINE),WIDTHP(I,ILINE),SHIFTP(I,ILINE), 2 WIDTHHE(I,ILINE),SHIFTHE(I,ILINE) 4 FORMAT(F7.0,6E9.2) SHIFT(I,ILINE)=SHIFT(I,ILINE)/WIDTH(I,ILINE) IF(WIDTHP(I,ILINE).NE.0.) 1 SHIFTP(I,ILINE)=SHIFTP(I,ILINE)/WIDTHP(I,ILINE) IF(WIDTHHE(I,ILINE).NE.0.) 1 SHIFTHE(I,ILINE)=SHIFTHE(I,ILINE)/WIDTHHE(I,ILINE) 5 continue IREAD=1 10 continue DO 11 ILINE=1,NLINE IF(WL.GT.WAVE(ILINE)-.1.AND.WL.LT.WAVE(ILINE)+.1)GO TO 12 11 CONTINUE V=ABS(WAVESYN-WL)/DOPWL C WANT DOPPLE(7) BUT DOES NOT INCLUDE ISOTOPIC MASS DOPWL/WL DOES A=(GAMMAR+GAMMAS*XNE(J))/(DOPWL/WL) DIMITRI=VOIGT(V,A) RETURN 12 IL=ILINE E=XNE(J) TEMP=T(J) C NUMERO PROTONI=N(H+)/U(H+) U(H+)=1 XNFHP=XNFPH(J,2) XNFHEP=XNFHE(J,2) DL=WAVEsyn4-WL4 TEMP=AMAX1(TEMP,5.0E3) TEMP=AMIN1(TEMP,8.0E4) DO 2 I=2,4 IT=I IF(Ttab(It,il).GT.TEMP)GO TO 33 2 CONTINUE 33 X=(TEMP-Ttab(IT-1,il))/(Ttab(IT,il)-Ttab(IT-1,il)) 333 XX=E/(10.**xnelog(il)) XXH=XNFHP/(10.**XNELOG(IL)) XXHE=XNFHEP/(10.**XNELOG(IL)) C DAMPING WIDTHs W=XX*(X*Width(IT,il)+(1.0-X)*Width(IT-1,il)) Wp=XXH*(X*Widthp(IT,il)+(1.0-X)*Widthp(IT-1,il)) Whe=XXHE*(X*Widthhe(IT,il)+(1.0-X)*Widthhe(IT-1,il)) C RATIO SHIFTS TO WIDTH D=shift(IT,il)+(1.0-X)*shift(IT-1,il) Dp=X*shiftp(IT,il)+(1.0-X)*shiftp(IT-1,il) Dhe=X*shifthe(IT,il)+(1.0-X)*shifthe(IT-1,il) C TOTAL WIDTH IN ANGSTROMS, then in nm WTOT=W+Wp+Whe wtot=wtot*0.1 c half-half-width wtot=wtot/2. C TOTAL SHIFT IN ANGSTROM, then in nm DTOT=W*D+Wp*dp+Whe*dhe dtot=dtot*0.1 C VOIGT PARAMETERS C WANT DOPPLE(7) BUT DOES NOT INCLUDE ISOTOPIC MASS DOPWL/WL DOES A=WTOT/DOPWL+GAMMAR/(DOPWL/WL) C NORMALIZATION CONSTANT c CON=0.564189583547756E0/(1.0+F1+F2)/(DOPPLE(7)*WL4) con=1. WWD=WAVEsyn-WL-DTOT dimitri=VOIGT(ABS(WWD)/DOPWL,A) RETURN END SUBROUTINE READBCS(LINE,J,TEMP,XNFHP,XNFHEP,XNE,DLNM,PHIHE) C LINE=1 4471 C LINE=2 4026 C LINE=3 4387 C LINE=4 4921 PARAMETER (kw=99) COMMON /TEMP/T(kw),TKEV(kw),TK(kw),HKT(kw),TLOG(kw),HCKT(kw),ITEMP CHARACTER*8 TITLE1,TITLE2 DIMENSION DLAM(204,4),PHI(8),PHIHP(4,7,142),PHIHEP(4,7,142) DIMENSION PHILAM(204),PHI4026(4,8,196),PHI4387(4,8,204) DIMENSION PHI4921(4,7,142) DIMENSION NDLAM(4),NXNE(4),XNE1(4) DATA NDLAM/142,196,204,142/ DATA NXNE/7,8,8,7/ DATA XNE1/13.,14.,14.,13./ DATA ITEMP1/0/ IF(DLAM(1,1).EQ.-150.)GO TO 10 OPEN(UNIT=18,FORM='FORMATTED',STATUS='OLD',READONLY,SHARED) C 4471 READ(18,1) TITLE1 READ(18,1) TITLE2 1 FORMAT(A80) DO 22 IL=1,142 DO 20 NE=1,7 READ(18,34)FNE,DWL,(PHI(I),I=1,8) 34 FORMAT(1X,F5.1,F8.2,8F7.3) c TYPE*,FNE,DWL,(PHI(I),I=1,8) DO 21 IT=1,4 PHIHP(IT,NE,IL)=PHI(IT) 21 PHIHEP(IT,NE,IL)=PHI(IT+4) 20 CONTINUE 22 DLAM(IL,1)=DWL-150. C 4026 READ(18,1)TITLE1 READ(18,1)TITLE2 DO 32 IL=1,196 DO 30 NE=1,8 READ(18,34)FNE,DWL,(PHI4026(IT,NE,IL),IT=1,4) C TYPE*,FNE,DWL,(PHI4026(IT,NE,IL),IT=1,4) 30 CONTINUE 32 DLAM(IL,2)=DWL-150. C 4387 READ(18,1)TITLE1 READ(18,1)TITLE2 DO 35 IL=1,204 DO 33 NE=1,8 READ(18,34)FNE,DWL,(PHI4387(IT,NE,IL),IT=1,4) 33 CONTINUE 35 DLAM(IL,3)=DWL-150. C 4921 READ(18,1) TITLE1 READ(18,1) TITLE2 DO 45 IL=1,142 DO 43 NE=1,7 READ(18,34)FNE,DWL,(PHI(I),I=1,8) c TYPE*,FNE,DWL,(PHI(I),I=1,8) DO 46 IT=1,4 PHIHP(IT,NE,IL)=PHI(IT) 46 PHIHEP(IT,NE,IL)=PHI(IT+4) 43 CONTINUE 45 DLAM(IL,4)=DWL-150. CLOSE(UNIT=18) JSAVE=0 C 10 IF(J*LINE.EQ.JSAVE)GO TO 550 C TEMPERATURE AND IONS DENSITY INTERPOLATION AT=LOG10(TEMP) BT=(AT-3.698970)/.3010300+1. IT=BT+0.00001 IT=MAX(MIN(IT,3),1) WT=BT-IT AP=LOG10(XNE) AP=MAX(XNE1(LINE),AP) BP=(AP-XNE1(LINE))/0.5+1. IP=BP+0.00001 IP=MAX(MIN(IP,NXNE(LINE)-1),1) WP=BP-IP C1W1W=(1.-WP)*(1.-WT) C1WW=(1.-WP)*WT CW1W=WP*(1.-WT) CWW=WP*WT GO TO (410,420,430,440),LINE 410 XXH=XNFHP/XNE XXHE=XNFHEP/XNE DO 411 I=1,NDLAM(LINE) 411 PHILAM(I)=XXH*10.**(C1W1W*PHIHP(IT ,IP ,I)+ 1 C1WW*PHIHP(IT+1,IP ,I)+ 2 CW1W*PHIHP(IT ,IP+1,I)+ 3 CWW*PHIHP(IT+1,IP+1,I))+ 4 XXHE*10.**(C1W1W*PHIHEP(IT ,IP ,I)+ 5 C1WW*PHIHEP(IT+1,IP ,I)+ 6 CW1W*PHIHEP(IT ,IP+1,I)+ 7 CWW*PHIHEP(IT+1,IP+1,I)) GO TO 502 420 DO 421 I=1,NDLAM(LINE) 421 PHILAM(I)=10.**(C1W1W*PHI4026(IT ,IP ,I)+ 1 C1WW*PHI4026(IT+1,IP ,I)+ 2 CW1W*PHI4026(IT ,IP+1,I)+ 3 CWW*PHI4026(IT+1,IP+1,I)) GO TO 502 430 DO 431 I=1,NDLAM(LINE) 431 PHILAM(I)=10.**(C1W1W*PHI4387(IT ,IP ,I)+ 1 C1WW*PHI4387(IT+1,IP ,I)+ 2 CW1W*PHI4387(IT ,IP+1,I)+ 3 CWW*PHI4387(IT+1,IP+1,I)) GO TO 502 440 XXH=XNFHP/XNE XXHE=XNFHEP/XNE DO 441 I=1,NDLAM(LINE) 441 PHILAM(I)=XXH*10.**(C1W1W*PHIHP(IT ,IP ,I)+ 1 C1WW*PHIHP(IT+1,IP ,I)+ 2 CW1W*PHIHP(IT ,IP+1,I)+ 3 CWW*PHIHP(IT+1,IP+1,I))+ 4 XXHE*10.**(C1W1W*PHIHEP(IT ,IP ,I)+ 5 C1WW*PHIHEP(IT+1,IP ,I)+ 6 CW1W*PHIHEP(IT ,IP+1,I)+ 7 CWW*PHIHEP(IT+1,IP+1,I)) 502 CALL INTEG(DLAM(1,LINE),PHILAM,PHINORM,NDLAM(LINE),0.) DO 503 I=1,NDLAM(LINE) 503 PHILAM(I)=LOG10(PHILAM(I)/PHINORM) JSAVE=J*LINE C C NOW DLAM INTERPOLATION 550 DL=DLNM*10. DO 600 I=2,NDLAM(LINE) IF(DL.GT.DLAM(I,LINE).AND.I.LT.NDLAM(LINE))GO TO 600 A=(DLAM(I,LINE)-DL)/(DLAM(I,LINE)-DLAM(I-1,LINE)) B=(DL-DLAM(I-1,LINE))/(DLAM(I,LINE)-DLAM(I-1,LINE)) PHIHE=10.**(A*PHILAM(I-1)+B*PHILAM(I)) RETURN 600 CONTINUE RETURN END SUBROUTINE INTEG(X,F,FINT,N,START) C SUBROUTINE INTEG(X,F,FINT,N) DIMENSION X(1),F(1) DIMENSION A(1000),B(1000),C(1000) CALL PARCOE(F,X,A,B,C,N) FINT=START C FINT(1)=(A(1)+(B(1)/2.+C(1)/3.*X(1))*X(1))*X(1) C FINT(2)=(A(1)+(B(1)/2.+C(1)/3.*X(2))*X(2))*X(2) C IF(N.EQ.2)RETURN N1=N-1 C DO 10 I=2,N1 DO 10 I=1,N1 10 FINT=FINT+(A(I)+B(I)/2.*(X(I+1)+X(I))+ 1C(I)/3.*((X(I+1)+X(I))*X(I+1)+X(I)*X(I)))*(X(I+1)-X(I)) RETURN END SUBROUTINE PARCOE(F,X,A,B,C,N) DIMENSION F(1),X(1),A(1),B(1),C(1) C(1)=0. B(1)=(F(2)-F(1))/(X(2)-X(1)) A(1)=F(1)-X(1)*B(1) N1=N-1 C(N)=0. B(N)=(F(N)-F(N1))/(X(N)-X(N1)) A(N)=F(N)-X(N)*B(N) IF(N.EQ.2)RETURN DO 1 J=2,N1 J1=J-1 D=(F(J)-F(J1))/(X(J)-X(J1)) C(J)=F(J+1)/((X(J+1)-X(J))*(X(J+1)-X(J1)))-F(J)/((X(J)-X(J1))* 1(X(J+1)-X(J)))+F(J1)/((X(J)-X(J1))*(X(J+1)-X(J1))) B(J)=D-(X(J)+X(J1))*C(J) 1 A(J)=F(J1)-X(J1)*D+X(J)*X(J1)*C(J) C(2)=0. B(2)=(F(3)-F(2))/(X(3)-X(2)) A(2)=F(2)-X(2)*B(2) C(3)=0. B(3)=(F(4)-F(3))/(X(4)-X(3)) A(3)=F(3)-X(3)*B(3) DO 2 J=2,N1 IF(C(J).EQ.0.)GO TO 2 J1=J+1 WT=ABS(C(J1))/(ABS(C(J1))+ABS(C(J))) A(J)=A(J1)+WT*(A(J)-A(J1)) B(J)=B(J1)+WT*(B(J)-B(J1)) C(J)=C(J1)+WT*(C(J)-C(J1)) 2 CONTINUE A(N1)=A(N) B(N1)=B(N) C(N1)=C(N) RETURN END SUBROUTINE BLOCKE c IMPLICIT REAL*8 (A-H,O-Z) PARAMETER (kw=99) COMMON /ELEM/ABUND(99),ATMASS(99),ELEM(99) C Grevesse,N. and Anders, E. 1988. presented at the workshop C on the "Solar Interior and Atmosphere", Tucson, Nov 15-18. C Anders, E. and Grevesse, N. 1989 Geochimica et Cosmochimica Acta, C vol. 53, pp. 197-214. C H has been defined to be -.04 instead of 12 C 1H 2HE DATA ABUND/ 0.911,0.089, C 3LI 4BE 5B 6C 7N 8O 9F 10NE 1-10.88,-10.89, -9.44, -3.48, -3.99, -3.11, -7.48, -3.95, C 11NA 12MG 13AL 14SI 15P 16S 17CL 18AR 2 -5.71, -4.46, -5.57, -4.49, -6.59, -4.83, -6.54, -5.48, C 19K 20CA 21SC 22TI 23V 24CR 25MN 26FE 3 -6.92, -5.68, -8.94, -7.05, -8.04, -6.37, -6.65, -4.37, C 27CO 28NI 29CU 30ZN 31GA 33GE 33AS 34SE 4 -7.12, -5.79, -7.83, -7.44, -9.16, -8.63, -9.67, -8.69, C 35BR 36KR 37RB 38SR 39Y 40ZR 41NB 42MO 5 -9.41, -8.81, -9.44, -9.14, -9.80, -9.44,-10.62,-10.12, C 43TC 44RU 45RH 46PD 47AG 48CD 49IN 50SN 6-20.00,-10.20,-10.92,-10.35,-11.10,-10.18,-10.38,-10.04, C 51SB 52TE 53I 54XE 55CS 56BA 57LA 58CE 7-11.04, -9.80,-10.53, -9.81,-10.92, -9.91,-10.82,-10.49, C 59PR 60ND 61PM 62SM 63EU 64GD 65TB 66DY 8-11.33,-10.54,-20.00,-11.04,-11.53,-10.92,-12.14,-10.94, C 67HO 68ER 69TM 70YB 71LU 72HF 73TA 74W 9-11.78,-11.11,-12.04,-10.96,-11.28,-11.16,-11.91,-10.93, C 75RE 76OS 77IR 78PT 79AU 80HG 81TL 82PB T-11.77,-10.59,-10.69,-10.24,-11.03,-10.95,-11.14,-10.19, C 83BI 84PO 85AT 86RN 87FR 88RA 89AC 90TH 1-11.33,-20.00,-20.00,-20.00,-20.00,-20.00,-20.00,-11.92, C 91PA 92U 93NP 94PU 95AM 96CM 97BK 98CF 99ES 2-20.00,-12.51,-20.00,-20.00,-20.00,-20.00,-20.00,-20.00,-20.00/ DATA ATMASS/ 1.008,4.003, 1 6.939,9.013,10.81,12.01,14.01,16.00,19.00,20.18,22.99,24.31, 2 26.98,28.09,30.98,32.07,35.45,39.95,39.10,40.08,44.96,47.90, 3 50.94,52.00,54.94,55.85,58.94,58.71,63.55,65.37,69.72,72.60, 4 74.92,78.96,79.91,83.80,85.48,87.63,88.91,91.22,92.91,95.95, 5 99.00,101.1,102.9,106.4,107.9,112.4,114.8,118.7,121.8,127.6, 6 126.9,131.3,132.9,137.4,138.9,140.1,140.9,144.3,147.0,150.4, 7 152.0,157.3,158.9,162.5,164.9,167.3,168.9,173.0,175.0,178.5, 8 181.0,183.9,186.3,190.2,192.2,195.1,197.0,200.6,204.4,207.2, 9 209.0,210.0,211.0,222.0,223.0,226.1,227.1,232.0,231.0,238.0, T 237.0,244.0,243.0,247.0,247.0,251.0,254.0/ DATA ELEM/ 2HH , 2HHE, 1 2HLI, 2HBE, 2HB , 2HC , 2HN , 2HO , 2HF , 2HNE, 2HNA, 2HMG, 2 2HAL, 2HSI, 2HP , 2HS , 2HCL, 2HAR, 2HK , 2HCA, 2HSC, 2HTI, 3 2HV , 2HCR, 2HMN, 2HFE, 2HCO, 2HNI, 2HCU, 2HZN, 2HGA, 2HGE, 4 2HAS, 2HSE, 2HBR, 2HKR, 2HRB, 2HSR, 2HY , 2HZR, 2HNB, 2HMO, 5 2HTC, 2HRU, 2HRH, 2HPD, 2HAG, 2HCD, 2HIN, 2HSN, 2HSB, 2HTE, 6 2HI , 2HXE, 2HCS, 2HBA, 2HLA, 2HCE, 2HPR, 2HND, 2HPM, 2HSM, 7 2HEU, 2HGD, 2HTB, 2HDY, 2HHO, 2HER, 2HTM, 2HYB, 2HLU, 2HHF, 8 2HTA, 2HW , 2HRE, 2HOS, 2HIR, 2HPT, 2HAU, 2HHG, 2HTL, 2HPB, 9 2HBI, 2HPO, 2HAT, 2HRN, 2HFR, 2HRA, 2HAC, 2HTH, 2HPA, 2HU , T 2HNP, 2HPU, 2HAM, 2HCM, 2HBK, 2HCF, 2HES/ RETURN END