1 | ! |
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2 | ! $Header$ |
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3 | ! |
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4 | SUBROUTINE ozonecm(rjour, rlat, paprs, o3) |
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5 | IMPLICIT none |
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6 | C |
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7 | C The ozone climatology is based on an analytic formula which fits the |
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8 | C Krueger and Mintzner (1976) profile, as well as the variations with |
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9 | C altitude and latitude of the maximum ozone concentrations and the total |
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10 | C column ozone concentration of Keating and Young (1986). The analytic |
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11 | C formula have been established by J-F Royer (CRNM, Meteo France), who |
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12 | C also provided us the code. |
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13 | C |
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14 | C A. J. Krueger and R. A. Minzner, A Mid-Latitude Ozone Model for the |
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15 | C 1976 U.S. Standard Atmosphere, J. Geophys. Res., 81, 4477, (1976). |
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16 | C |
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17 | C Keating, G. M. and D. F. Young, 1985: Interim reference models for the |
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18 | C middle atmosphere, Handbook for MAP, vol. 16, 205-229. |
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19 | C |
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20 | |
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21 | #include "dimensions.h" |
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22 | #include "dimphy.h" |
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23 | #include "clesphys.h" |
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24 | #include "YOMCST.h" |
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25 | REAL rlat(klon), paprs(klon,klev+1) |
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26 | REAL o3(klon,klev) ! ozone concentration in kg/kg |
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27 | REAL tozon, rjour, pi, pl |
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28 | INTEGER i, k |
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29 | C---------------------------------------------------------- |
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30 | REAL field(klon,klev+1) |
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31 | REAL ps |
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32 | PARAMETER (ps=101325.0) |
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33 | REAL an, unit, zo3q3 |
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34 | SAVE an, unit, zo3q3 |
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35 | REAL mu,gms, zslat, zsint, zcost, z, ppm, qpm, a |
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36 | REAL asec, bsec, aprim, zo3a3 |
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37 | C---------------------------------------------------------- |
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38 | c data an /365.25/ (meteo) |
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39 | DATA an /360.00/ |
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40 | DATA unit /2.1415e-05/ |
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41 | DATA zo3q3 /4.0e-08/ |
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42 | |
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43 | pi = 4.0 * ATAN(1.0) |
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44 | DO k = 1, klev |
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45 | DO i = 1, klon |
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46 | zslat = SIN(pi/180.*rlat(i)) |
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47 | zsint = SIN(2.*pi*(rjour+15.)/an) |
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48 | zcost = COS(2.*pi*(rjour+15.)/an) |
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49 | z = 0.0531+zsint*(-0.001595+0.009443*zslat) + |
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50 | . zcost*(-0.001344-0.00346*zslat) + |
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51 | . zslat**2*(.056222+zslat**2*(-.037609 |
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52 | . +.012248*zsint+.00521*zcost+.008890*zslat)) |
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53 | zo3a3 = zo3q3/ps/2. |
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54 | z = z-zo3q3*ps |
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55 | gms = z |
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56 | mu = ABS(sin(pi/180.*rlat(i))) |
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57 | ppm = 800.-(500.*zslat+150.*zcost)*zslat |
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58 | qpm = 1.74e-5-(7.5e-6*zslat+1.7e-6*zcost)*zslat |
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59 | bsec = 2650.+5000.*zslat**2 |
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60 | a = 4.0*(bsec)**(3./2.)*(ppm)**(3./2.)*(1.0+(bsec/ps)**(3./2.)) |
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61 | a = a/(bsec**(3./2.)+ppm**(3./2.))**2 |
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62 | aprim = (2.666666*qpm*ppm-a*gms)/(1.0-a) |
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63 | aprim = amax1(0.,aprim) |
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64 | asec = (gms-aprim)*(1.0+(bsec/ps)**(3./2.)) |
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65 | asec = AMAX1(0.0,asec) |
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66 | aprim = gms-asec/(1.+(bsec/ps)**(3./2.)) |
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67 | pl = paprs(i,k) |
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68 | tozon = aprim/(1.+3.*(ppm/pl)**2)+asec/(1.+(bsec/pl)**(3./2.)) |
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69 | . + zo3a3*pl*pl |
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70 | tozon = tozon / 9.81 ! en kg/m**2 |
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71 | tozon = tozon / unit ! en kg/m**2 > u dobson (10e-5 m) |
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72 | tozon = tozon / 1000. ! en cm |
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73 | field(i,k) = tozon |
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74 | ENDDO |
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75 | ENDDO |
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76 | c |
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77 | DO i = 1, klon |
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78 | field(i,klev+1) = 0.0 |
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79 | ENDDO |
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80 | DO k = 1, klev |
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81 | DO i = 1, klon |
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82 | o3(i,k) = field(i,k) - field(i,k+1) |
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83 | IF (.not. bug_ozone) then |
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84 | c convert o3 into kg/kg |
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85 | o3(i,k)=MAX(o3(i,k),1.0e-12)*RG/46.6968 |
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86 | . /(paprs(i,k)-paprs(i,k+1)) |
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87 | ENDIF |
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88 | ENDDO |
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89 | ENDDO |
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90 | c |
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91 | RETURN |
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92 | END |
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