pkg/monod/monod_init_fixed.F

C $Header$
C $Name$

#include "CPP_OPTIONS.h"
#include "PTRACERS_OPTIONS.h"
#include "DARWIN_OPTIONS.h"

#ifdef ALLOW_PTRACERS
#ifdef ALLOW_MONOD

c===============================================================================
C===============================================================================
CStartofinterface
      SUBROUTINE MONOD_INIT_FIXED(myThid)
C     =============== Global data ==========================================
C     === Global variables ===
         implicit none
#include "SIZE.h"
#include "EEPARAMS.h"
#include "PARAMS.h"
#include "GRID.h"
#include "DYNVARS.h"
#include "GCHEM.h"
#include "DARWIN_PARAMS.h"
#include "MONOD_SIZE.h"
#include "MONOD.h"
#include "DARWIN_FLUX.h"

        INTEGER myThid
C============== Local variables ============================================
C     msgBuf    - Informational/error meesage buffer
      CHARACTER*(MAX_LEN_MBUF) msgBuf
      _RL pday
      INTEGER i,j,k,bi,bj,nz
      INTEGER tmp
      INTEGER prec
      CHARACTER*(MAX_LEN_MBUF) fn
C     /--------------------------------------------------------------\
C     |  initialise common block biochemical parameters               |
C     \--------------------------------------------------------------/

      WRITE(msgBuf,'(A)')
     &'// ======================================================='
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
     &                    SQUEEZE_RIGHT, myThid )
      WRITE(msgBuf,'(A)') '// Darwin loading parameters'
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
     &                    SQUEEZE_RIGHT, myThid )
      WRITE(msgBuf,'(A)')
     &'// ======================================================='
      CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
     &                    SQUEEZE_RIGHT, myThid )


c ANNA set fixed params for WAVEBANDS
#ifdef WAVEBANDS
        call wavebands_init_fixed(myThid)
#endif 

c c define 1 day in seconds
         pday = 86400.0 _d 0


c attenuation coefficients
c ANNA only if not wavebands
#ifndef WAVEBANDS
      k0=        4. _d -2                   !atten coefficient water(m^-1)
#ifdef GEIDER
      kc=        4. _d -2                   !atten coefficient chl ((mmol chl/m3)-1)
#else
      kc=        4. _d -2*16. _d 0*1. _d 0        !atten coefficient phy((uM m)-1)
#endif
#endif
c ANNA endif


c par parameters
      parfrac=  0.4 _d 0                    !fraction Qsw that is PAR
      parconv= 1. _d 0/0.2174 _d 0             !conversion from W/m2 to uEin/m2/s
c for chl
      chlpmax=40. _d 0                      ! mg Chl/mmolP
      chlpmin=16. _d 0                      ! mg Chl/mmolP
      istar=90. _d 0                        ! w/m2
c iron related
      alpfe=     0.04 _d 0                  !solubility of Fe dust
      scav=      0.4 _d 0/(360. _d 0*86400. _d 0) !iron chem scavenging rate (s-1)
      ligand_tot=1. _d -3                   !total ligand (uM)
      ligand_stab=2. _d 5                   !ligand stability rate ratio
      freefemax = .4 _d -3                  ! max free fe

#ifdef IRON_SED_SOURCE
c iron sediment source
      depthfesed=1000.0 _d 0       !depth above which to add sediment source
      fesedflux =1.0 _d 0 * 1.0 _d -3 / (86400.0 _d 0) !iron flux (mmol/m2/s)
      fesedflux_pcm =0.68 _d 0 * 1.0 _d -3 !iron flux (mmol/m3/s) per
c                                            mmol POC/m3/s
#endif
#ifdef PART_SCAV
      scav_rat=0.005 _d 0 /(86400.0 _d 0)
      scav_inter=0.079 _d 0
      scav_exp=0.58 _d 0
#endif

c depth for denitrification to start
      depthdenit=185.0 _d 0

c critical oxygen for O2/NO3 remineralization
      O2crit = 6.0 _d 0    !(Lipschultz et al 1990, DSR 37, 1513-1541)
c ratio of no3 to p in denitrification process
      denit_np = 120.0 _d 0

c
c oxidation rates for ammonium and nitrite
c i.e. Knita ...    NH4 -> NO2
c i.e. Knitb ...    NO2 -> NO3
       Knita = 1.0 _d 0/(.50 _d 0*pday)
       Knitb = 1.0 _d 0/(10.0 _d 0*pday)
c critical light level (muEin/m2/s) after which oxidation starts
       PAR0 = 10. _d 0
c
#ifndef GEIDER
c set growth days ...small or big organism?
       Smallgrow = .7 _d 0
       Biggrow   = .4 _d 0
       Smallgrowrange = 0. _d 0
       Biggrowrange = 0. _d 0
       diaz_growfac = 2. _d 0
#endif
c set mort days ...small or big organism?
       Smallmort = 10. _d 0
       Bigmort   = 10. _d 0
       Smallmortrange = 0. _d 0
       Bigmortrange = 0. _d 0
c set export fraction ...small or big organism?
       Smallexport = 0.2 _d 0
       Bigexport   = 0.5 _d 0
c set sinking rates (m/s)... small or big organism?
       SmallSink = 0.0 _d 0/pday
       BigSink =  0.5 _d 0/pday   !0.5 _d 0/pday
c set parameters for light function for phyto growth
#ifndef GEIDER
       smallksatpar =    0.12 _d 0 ! 0.8 _d 0
       smallksatparstd = 0.20 _d 0  ! 0.3 _d 0
       smallkinhib =     6.0 _d 0   ! 2.0 _d 0
       smallkinhibstd =  0.10 _d 0  ! 0.5 _d 0
       Bigksatpar =      0.12 _d 0  ! 0.35 _d 0
       Bigksatparstd =   0.06 _d 0  ! 0.1 _d 0
       Bigkinhib =       1.0 _d 0   ! 0.5 _d 0
       Bigkinhibstd =    0.05 _d 0   ! 0.1 _d 0
#endif
#ifdef  GEIDER
c for Pcm -- should be growth rates, but using old variables
c note these are in terms of days - converted to 1/s later
       Smallgrow = .7 _d 0
       Biggrow   = .4 _d 0
       Smallgrowrange = 0. _d 0
       Biggrowrange = 0. _d 0
       diaz_growfac = 2. _d 0
c
       smallchl2cmax = 0.2 _d 0      !mg Chl (mmol C)
       smallchl2cmaxrange = 0.3 _d 0  !mg Chl (mmol C)
       Bigchl2cmax = 0.5 _d 0         !mg Chl (mmol C)
       Bigchl2cmaxrange = 0.3 _d 0    !mg Chl (mmol C)

c ANNA_Q units for alpha are same as expected: mmol C (mg chla)-1 (uEin)-1 (m)2
c       smallalphachl =  1. _d -6     !mmol C (uEin/m-2)-1 (mg Chl)-1 
c       smallalphachlrange = 1. _d -6 !mmol C (uEin/m-2)-1 (mg Chl)-1
c       Bigalphachl = 6. _d -7        !mmol C (uEin/m-2)-1 (mg Chl)-1
c       Bigalphachlrange = 4. _d -7   !mmol C (uEin/m-2)-1 (mg Chl)-1
c ANNA mQyield vals are from alphachl / aphy_chl which for now is 0.02
c ANNA ranges for mQyield are same as alphachl but reduced by factor 100
       smallmQyield = 5. _d -5        !mmol C (uEin)-1
       smallmQyieldrange = 1. _d -4   !mmol C (uEin)-1
       BigmQyield = 3. _d -5          !mmol C (uEin)-1
       BigmQyieldrange = 4. _d -5     !mmol C (uEin)-1

c ANNA value of aphy_chl_ave = 0.02 - its the mean of all spectras used as input data
       aphy_chl_ave = 0.02 _d 0      !m2 (mg chla)-1 (ie. x chla gives absorption m-1)

c inhib for Prochl?
C       inhibcoef_geid_val = 1.2 _d 0 !DUMMY VAL
       inhibcoef_geid_val = 0 _d 0 !DUMMY VAL
#ifdef DYNAMIC_CHL
       acclimtimescl = 1./(60. _d 0 *60. _d 0 *24. _d 0 * 20. _d 0)
#endif
#endif
c

c set temperature function
       tempcoeff1 = 1. _d 0/3. _d 0
       tempcoeff2_small = 0.001 _d 0
       tempcoeff2_big   = 0.0003 _d 0
       tempcoeff3 = 1.04 _d 0
       tempmax = 30. _d 0      ! 32. _d 0
       temprange = 32. _d 0    ! 30. _d 0
       tempnorm = 0.3 _d 0  ! 1. _d 0
       tempdecay = 4. _d 0
c set phosphate half stauration constants .. small or big organism
       SmallPsat=0.015 _d 0
       BigPsat=0.035 _d 0
       ProcPsat=0.01 _d 0
       UniDzPsat=0.012 _d 0
       SmallPsatrange=0.02 _d 0
       BigPsatrange=0.02 _d 0
       ProcPsatrange=0.005 _d 0
       UniDzPsatrange=0.02 _d 0
c set NH4/NO2 frac, so that NH4/NO2 can be preferred nitrogen source
       ksatNH4fac=.50 _d 0
       ksatNO2fac=1.0 _d 0
c set prochl lower half-sat (used only for mutants)
       prochlPsat=.85 _d 0
c ammonia and nitrite inhibition
       sig1 = 4.6 _d 0
       sig2 = 4.6 _d 0
       sig3 = 4.6 _d 0
       ngrowfac = 1. _d 0
       ilight = 2. _d 0
c set si half sat
       val_ksatsi=1. _d 0
c set nutrient ratios for phyto
       val_R_SiP_diatom=16.0 _d 0  ! 32 for Fanny's runs
       val_R_NP=16.0 _d 0
       val_RFeP=1.0 _d -3
       val_R_NP_diaz=40.0 _d  0
       val_RFeP_diaz=30.0 _d 0 * val_RFeP
       val_R_PC=120.0 _d 0
       val_R_PICPOC=0.8 _d 0
#ifdef OLD_GRAZE
c grazing hlaf saturation
       kgrazesat = 0.1 _d 0
c set grazing rates .. small or big organism?
       GrazeFast = 1.0 _d 0/(5.0 _d 0*pday)
       GrazeSlow = 1.0 _d 0/(30.0 _d 0*pday)
c set grazing effeciency
       GrazeEffsmall=0.6 _d 0
       GrazeEffbig  =0.2 _d 0
c set grazing of diatom factor
       diatomgraz = 0.8 _d 0
       coccograz = 0.7 _d 0
       olargegraz = 0.9 _d 0
#else
c grazing hlaf saturation
c      kgrazesat = 0.1 _d 0
       kgrazesat = 0.1 _d 0
c      phygrazmin = 1 _d -5
       phygrazmin = 1 _d -10
c set grazing rates .. small or big organism?
c      GrazeFast = 1.0 _d 0/(5.0 _d 0*pday)
       GrazeFast = 1.0 _d 0/(2.0 _d 0*pday)
c      GrazeSlow = 1.0 _d 0/(30.0 _d 0*pday)
       GrazeSlow = 1.0 _d 0/(7.0 _d 0*pday)
c set grazing effeciency
       GrazeEfflow= 0.2 _d 0
       GrazeEffmod= 0.5 _d 0
       GrazeEffhi = 0.7 _d 0
c set palatibility
       palathi = 1.0 _d 0
       palatlo = 0.2 _d 0
c set palatibilty diatom factor
       diatomgraz = 0.7 _d 0
       coccograz = 0.6 _d 0
       olargegraz = 1.0 _d 0
c set faction graz to POM
       ExGrazfracbig = 0.8 _d 0
       ExGrazfracsmall = 0.8 _d 0
#endif
c set zoo mortality
       ZoomortSmall = 1.0 _d 0/(30.0 _d 0*pday)
       ZoomortBig = 1.0 _d 0/(30.0 _d 0*pday)
c set zoo exportfrac
       ZooexfacSmall = 0.2 _d 0
       ZooexfacBig = 0.7 _d 0
c minimum phyto (below which grazing and mortality doesn't happen)
c      phymin = 1 _d -10
c      phymin = 1 _d -50
       phymin = 1 _d -20
c DOM remin rates
         Kdop = 1.0 _d 0/(100.0 _d 0*pday)
         Kdon = 1.0 _d 0/(100.0 _d 0*pday)
         KdoFe = 1.0 _d 0/(100.0 _d 0*pday)
c Particulate detritus remin rates
c z* = wx_sink/Kremin_X
c for e-folding length scale, z* = 300 m
c choose Kremin_X = 1/30 day-1, wx_sink = 10 m day-1
         Kpremin_P = 1.0 _d 0/(50.0 _d 0*pday)
         Kpremin_N = Kpremin_P
         Kpremin_Fe = Kpremin_P
         Kpremin_Si = 1.0 _d 0/(300.0 _d 0*pday)
c sinking rate for particulate matter (m/s)
         wp_sink = 10.0 _d 0/pday
         wn_sink = wp_sink
         wfe_sink = wp_sink
         wsi_sink = wp_sink

#ifdef ALLOW_CARBON
         R_OP = 170 _d 0
         Kdoc = 1.0 _d 0/(100.0 _d 0*pday)
         Kpremin_C = 1.0 _d 0/(50.0 _d 0*pday)
         Kdissc =  1.0 _d 0/(300.0 _d 0*pday)
         wc_sink = wp_sink
         wpic_sink = 15.0 _d 0/pday
         permil      = 1. _d 0 / 1024.5 _d 0
         Pa2Atm      = 1.01325 _d 5
#endif

C make sure we have reserved enough space in Ptracers
      IF ( nCompZooMax .LT. 4 ) THEN
        WRITE(msgBuf,'(A,A,I3)')
     &    'MONOD_INIT_FIXED: ERROR: 4 zooplankton components, but ',
     &    'nCompZooMax = ', nCompZooMax
        CALL PRINT_ERROR( msgBuf , 1)
        STOP 'ABNORMAL END: S/R MONOD_INIT_FIXED'
      ENDIF
      DO nz = 1,nzmax
        iZooP (nz)  = iZoo +                   (nz-1)*strideTypeZoo
        iZooN (nz)  = iZoo + 1*strideCompZoo + (nz-1)*strideTypeZoo
        iZooFe(nz)  = iZoo + 2*strideCompZoo + (nz-1)*strideTypeZoo
        iZooSi(nz)  = iZoo + 3*strideCompZoo + (nz-1)*strideTypeZoo
      ENDDO
#ifdef ALLOW_CARBON
       DO nz = 1,nzmax
        iZooC (nz)  = iZoC +                   (nz-1)
      ENDDO
#endif

#ifdef DAR_DIAG_DIVER
c only look at grid point with a minimum biomass
        diver_thresh0=1 _d -12
c diver1 - if any type greater than
        diver_thresh1=1 _d -8
c diver2 - if more than this proportion of total biomass
        diver_thresh2=1 _d -3
c diver3 - fraction of biomass to count
        diver_thresh3=.999 _d 0
c diver4 - fraction of maximum species
        diver_thresh4=1 _d -5
#endif

c set up diagnostics
#ifdef ALLOW_MNC
      IF ( useMNC ) THEN
        CALL DARWIN_MNC_INIT( myThid )
#ifdef ALLOW_CARBON
        CALL DIC_MNC_INIT( myThid )
#endif
      ENDIF
#endif /* ALLOW_MNC */

COJ set up diagnostics
#ifdef ALLOW_DIAGNOSTICS
      IF ( useDIAGNOSTICS ) THEN
        CALL MONOD_DIAGNOSTICS_INIT( myThid )
#ifdef ALLOW_CARBON
        CALL DIC_DIAGNOSTICS_INIT( myThid )
#endif
      ENDIF
#endif /* ALLOW_DIAGNOSTICS */
COJ


        RETURN
        END
C============================================================================
#endif
#endif

1	jahn	1.1	C $Header$
2			C $Name$
3
4			#include "CPP_OPTIONS.h"
5			#include "PTRACERS_OPTIONS.h"
6			#include "DARWIN_OPTIONS.h"
7
8			#ifdef ALLOW_PTRACERS
9			#ifdef ALLOW_MONOD
10
11			c===============================================================================
12			C===============================================================================
13			CStartofinterface
14			SUBROUTINE MONOD_INIT_FIXED(myThid)
15			C =============== Global data ==========================================
16			C === Global variables ===
17			implicit none
18			#include "SIZE.h"
19			#include "EEPARAMS.h"
20			#include "PARAMS.h"
21			#include "GRID.h"
22			#include "DYNVARS.h"
23			#include "GCHEM.h"
24			#include "DARWIN_PARAMS.h"
25			#include "MONOD_SIZE.h"
26			#include "MONOD.h"
27			#include "DARWIN_FLUX.h"
28
29			INTEGER myThid
30			C============== Local variables ============================================
31			C msgBuf - Informational/error meesage buffer
32			CHARACTER*(MAX_LEN_MBUF) msgBuf
33			_RL pday
34			INTEGER i,j,k,bi,bj,nz
35			INTEGER tmp
36			INTEGER prec
37			CHARACTER*(MAX_LEN_MBUF) fn
38			C /--------------------------------------------------------------\
39			C \| initialise common block biochemical parameters \|
40			C \--------------------------------------------------------------/
41
42			WRITE(msgBuf,'(A)')
43			&'// ======================================================='
44			CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
45			& SQUEEZE_RIGHT, myThid )
46			WRITE(msgBuf,'(A)') '// Darwin loading parameters'
47			CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
48			& SQUEEZE_RIGHT, myThid )
49			WRITE(msgBuf,'(A)')
50			&'// ======================================================='
51			CALL PRINT_MESSAGE( msgBuf, standardMessageUnit,
52			& SQUEEZE_RIGHT, myThid )
53
54
55			c ANNA set fixed params for WAVEBANDS
56			#ifdef WAVEBANDS
57			call wavebands_init_fixed(myThid)
58			#endif
59
60			c c define 1 day in seconds
61			pday = 86400.0 _d 0
62
63
64			c attenuation coefficients
65			c ANNA only if not wavebands
66			#ifndef WAVEBANDS
67			k0= 4. _d -2 !atten coefficient water(m^-1)
68			#ifdef GEIDER
69			kc= 4. _d -2 !atten coefficient chl ((mmol chl/m3)-1)
70			#else
71			kc= 4. _d -216. _d 01. _d 0 !atten coefficient phy((uM m)-1)
72			#endif
73			#endif
74			c ANNA endif
75
76
77			c par parameters
78			parfrac= 0.4 _d 0 !fraction Qsw that is PAR
79			parconv= 1. _d 0/0.2174 _d 0 !conversion from W/m2 to uEin/m2/s
80			c for chl
81			chlpmax=40. _d 0 ! mg Chl/mmolP
82			chlpmin=16. _d 0 ! mg Chl/mmolP
83			istar=90. _d 0 ! w/m2
84			c iron related
85			alpfe= 0.04 _d 0 !solubility of Fe dust
86			scav= 0.4 _d 0/(360. _d 0*86400. _d 0) !iron chem scavenging rate (s-1)
87			ligand_tot=1. _d -3 !total ligand (uM)
88			ligand_stab=2. _d 5 !ligand stability rate ratio
89			freefemax = .4 _d -3 ! max free fe
90
91			#ifdef IRON_SED_SOURCE
92			c iron sediment source
93			depthfesed=1000.0 _d 0 !depth above which to add sediment source
94			fesedflux =1.0 _d 0 * 1.0 _d -3 / (86400.0 _d 0) !iron flux (mmol/m2/s)
95			fesedflux_pcm =0.68 _d 0 * 1.0 _d -3 !iron flux (mmol/m3/s) per
96			c mmol POC/m3/s
97			#endif
98			#ifdef PART_SCAV
99			scav_rat=0.005 _d 0 /(86400.0 _d 0)
100			scav_inter=0.079 _d 0
101			scav_exp=0.58 _d 0
102			#endif
103
104			c depth for denitrification to start
105			depthdenit=185.0 _d 0
106
107			c critical oxygen for O2/NO3 remineralization
108			O2crit = 6.0 _d 0 !(Lipschultz et al 1990, DSR 37, 1513-1541)
109			c ratio of no3 to p in denitrification process
110			denit_np = 120.0 _d 0
111
112			c
113			c oxidation rates for ammonium and nitrite
114			c i.e. Knita ... NH4 -> NO2
115			c i.e. Knitb ... NO2 -> NO3
116			Knita = 1.0 _d 0/(.50 _d 0*pday)
117			Knitb = 1.0 _d 0/(10.0 _d 0*pday)
118			c critical light level (muEin/m2/s) after which oxidation starts
119			PAR0 = 10. _d 0
120			c
121			#ifndef GEIDER
122			c set growth days ...small or big organism?
123			Smallgrow = .7 _d 0
124			Biggrow = .4 _d 0
125			Smallgrowrange = 0. _d 0
126			Biggrowrange = 0. _d 0
127			diaz_growfac = 2. _d 0
128			#endif
129			c set mort days ...small or big organism?
130			Smallmort = 10. _d 0
131			Bigmort = 10. _d 0
132			Smallmortrange = 0. _d 0
133			Bigmortrange = 0. _d 0
134			c set export fraction ...small or big organism?
135			Smallexport = 0.2 _d 0
136			Bigexport = 0.5 _d 0
137			c set sinking rates (m/s)... small or big organism?
138			SmallSink = 0.0 _d 0/pday
139			BigSink = 0.5 _d 0/pday !0.5 _d 0/pday
140			c set parameters for light function for phyto growth
141			#ifndef GEIDER
142			smallksatpar = 0.12 _d 0 ! 0.8 _d 0
143			smallksatparstd = 0.20 _d 0 ! 0.3 _d 0
144			smallkinhib = 6.0 _d 0 ! 2.0 _d 0
145			smallkinhibstd = 0.10 _d 0 ! 0.5 _d 0
146			Bigksatpar = 0.12 _d 0 ! 0.35 _d 0
147			Bigksatparstd = 0.06 _d 0 ! 0.1 _d 0
148			Bigkinhib = 1.0 _d 0 ! 0.5 _d 0
149			Bigkinhibstd = 0.05 _d 0 ! 0.1 _d 0
150			#endif
151			#ifdef GEIDER
152			c for Pcm -- should be growth rates, but using old variables
153			c note these are in terms of days - converted to 1/s later
154			Smallgrow = .7 _d 0
155			Biggrow = .4 _d 0
156			Smallgrowrange = 0. _d 0
157			Biggrowrange = 0. _d 0
158			diaz_growfac = 2. _d 0
159			c
160			smallchl2cmax = 0.2 _d 0 !mg Chl (mmol C)
161			smallchl2cmaxrange = 0.3 _d 0 !mg Chl (mmol C)
162			Bigchl2cmax = 0.5 _d 0 !mg Chl (mmol C)
163			Bigchl2cmaxrange = 0.3 _d 0 !mg Chl (mmol C)
164
165			c ANNA_Q units for alpha are same as expected: mmol C (mg chla)-1 (uEin)-1 (m)2
166			c smallalphachl = 1. _d -6 !mmol C (uEin/m-2)-1 (mg Chl)-1
167			c smallalphachlrange = 1. _d -6 !mmol C (uEin/m-2)-1 (mg Chl)-1
168			c Bigalphachl = 6. _d -7 !mmol C (uEin/m-2)-1 (mg Chl)-1
169			c Bigalphachlrange = 4. _d -7 !mmol C (uEin/m-2)-1 (mg Chl)-1
170			c ANNA mQyield vals are from alphachl / aphy_chl which for now is 0.02
171			c ANNA ranges for mQyield are same as alphachl but reduced by factor 100
172			smallmQyield = 5. _d -5 !mmol C (uEin)-1
173			smallmQyieldrange = 1. _d -4 !mmol C (uEin)-1
174			BigmQyield = 3. _d -5 !mmol C (uEin)-1
175			BigmQyieldrange = 4. _d -5 !mmol C (uEin)-1
176
177			c ANNA value of aphy_chl_ave = 0.02 - its the mean of all spectras used as input data
178			aphy_chl_ave = 0.02 _d 0 !m2 (mg chla)-1 (ie. x chla gives absorption m-1)
179
180			c inhib for Prochl?
181			C inhibcoef_geid_val = 1.2 _d 0 !DUMMY VAL
182			inhibcoef_geid_val = 0 _d 0 !DUMMY VAL
183			#ifdef DYNAMIC_CHL
184			acclimtimescl = 1./(60. _d 0 60. _d 0 24. _d 0 * 20. _d 0)
185			#endif
186			#endif
187			c
188
189			c set temperature function
190			tempcoeff1 = 1. _d 0/3. _d 0
191			tempcoeff2_small = 0.001 _d 0
192			tempcoeff2_big = 0.0003 _d 0
193			tempcoeff3 = 1.04 _d 0
194			tempmax = 30. _d 0 ! 32. _d 0
195			temprange = 32. _d 0 ! 30. _d 0
196			tempnorm = 0.3 _d 0 ! 1. _d 0
197			tempdecay = 4. _d 0
198			c set phosphate half stauration constants .. small or big organism
199			SmallPsat=0.015 _d 0
200			BigPsat=0.035 _d 0
201			ProcPsat=0.01 _d 0
202			UniDzPsat=0.012 _d 0
203			SmallPsatrange=0.02 _d 0
204			BigPsatrange=0.02 _d 0
205			ProcPsatrange=0.005 _d 0
206			UniDzPsatrange=0.02 _d 0
207			c set NH4/NO2 frac, so that NH4/NO2 can be preferred nitrogen source
208			ksatNH4fac=.50 _d 0
209			ksatNO2fac=1.0 _d 0
210			c set prochl lower half-sat (used only for mutants)
211			prochlPsat=.85 _d 0
212			c ammonia and nitrite inhibition
213			sig1 = 4.6 _d 0
214			sig2 = 4.6 _d 0
215			sig3 = 4.6 _d 0
216			ngrowfac = 1. _d 0
217			ilight = 2. _d 0
218			c set si half sat
219			val_ksatsi=1. _d 0
220			c set nutrient ratios for phyto
221			val_R_SiP_diatom=16.0 _d 0 ! 32 for Fanny's runs
222			val_R_NP=16.0 _d 0
223			val_RFeP=1.0 _d -3
224			val_R_NP_diaz=40.0 _d 0
225			val_RFeP_diaz=30.0 _d 0 * val_RFeP
226			val_R_PC=120.0 _d 0
227			val_R_PICPOC=0.8 _d 0
228			#ifdef OLD_GRAZE
229			c grazing hlaf saturation
230			kgrazesat = 0.1 _d 0
231			c set grazing rates .. small or big organism?
232			GrazeFast = 1.0 _d 0/(5.0 _d 0*pday)
233			GrazeSlow = 1.0 _d 0/(30.0 _d 0*pday)
234			c set grazing effeciency
235			GrazeEffsmall=0.6 _d 0
236			GrazeEffbig =0.2 _d 0
237			c set grazing of diatom factor
238			diatomgraz = 0.8 _d 0
239			coccograz = 0.7 _d 0
240			olargegraz = 0.9 _d 0
241			#else
242			c grazing hlaf saturation
243			c kgrazesat = 0.1 _d 0
244			kgrazesat = 0.1 _d 0
245			c phygrazmin = 1 _d -5
246			phygrazmin = 1 _d -10
247			c set grazing rates .. small or big organism?
248			c GrazeFast = 1.0 _d 0/(5.0 _d 0*pday)
249			GrazeFast = 1.0 _d 0/(2.0 _d 0*pday)
250			c GrazeSlow = 1.0 _d 0/(30.0 _d 0*pday)
251			GrazeSlow = 1.0 _d 0/(7.0 _d 0*pday)
252			c set grazing effeciency
253			GrazeEfflow= 0.2 _d 0
254			GrazeEffmod= 0.5 _d 0
255			GrazeEffhi = 0.7 _d 0
256			c set palatibility
257			palathi = 1.0 _d 0
258			palatlo = 0.2 _d 0
259			c set palatibilty diatom factor
260			diatomgraz = 0.7 _d 0
261			coccograz = 0.6 _d 0
262			olargegraz = 1.0 _d 0
263			c set faction graz to POM
264			ExGrazfracbig = 0.8 _d 0
265			ExGrazfracsmall = 0.8 _d 0
266			#endif
267			c set zoo mortality
268			ZoomortSmall = 1.0 _d 0/(30.0 _d 0*pday)
269			ZoomortBig = 1.0 _d 0/(30.0 _d 0*pday)
270			c set zoo exportfrac
271			ZooexfacSmall = 0.2 _d 0
272			ZooexfacBig = 0.7 _d 0
273			c minimum phyto (below which grazing and mortality doesn't happen)
274			c phymin = 1 _d -10
275			c phymin = 1 _d -50
276			phymin = 1 _d -20
277			c DOM remin rates
278			Kdop = 1.0 _d 0/(100.0 _d 0*pday)
279			Kdon = 1.0 _d 0/(100.0 _d 0*pday)
280			KdoFe = 1.0 _d 0/(100.0 _d 0*pday)
281			c Particulate detritus remin rates
282			c z* = wx_sink/Kremin_X
283			c for e-folding length scale, z* = 300 m
284			c choose Kremin_X = 1/30 day-1, wx_sink = 10 m day-1
285			Kpremin_P = 1.0 _d 0/(50.0 _d 0*pday)
286			Kpremin_N = Kpremin_P
287			Kpremin_Fe = Kpremin_P
288			Kpremin_Si = 1.0 _d 0/(300.0 _d 0*pday)
289			c sinking rate for particulate matter (m/s)
290			wp_sink = 10.0 _d 0/pday
291			wn_sink = wp_sink
292			wfe_sink = wp_sink
293			wsi_sink = wp_sink
294
295			#ifdef ALLOW_CARBON
296			R_OP = 170 _d 0
297			Kdoc = 1.0 _d 0/(100.0 _d 0*pday)
298			Kpremin_C = 1.0 _d 0/(50.0 _d 0*pday)
299			Kdissc = 1.0 _d 0/(300.0 _d 0*pday)
300			wc_sink = wp_sink
301			wpic_sink = 15.0 _d 0/pday
302			permil = 1. _d 0 / 1024.5 _d 0
303			Pa2Atm = 1.01325 _d 5
304			#endif
305
306			C make sure we have reserved enough space in Ptracers
307			IF ( nCompZooMax .LT. 4 ) THEN
308			WRITE(msgBuf,'(A,A,I3)')
309			& 'MONOD_INIT_FIXED: ERROR: 4 zooplankton components, but ',
310			& 'nCompZooMax = ', nCompZooMax
311			CALL PRINT_ERROR( msgBuf , 1)
312			STOP 'ABNORMAL END: S/R MONOD_INIT_FIXED'
313			ENDIF
314			DO nz = 1,nzmax
315			iZooP (nz) = iZoo + (nz-1)*strideTypeZoo
316			iZooN (nz) = iZoo + 1strideCompZoo + (nz-1)strideTypeZoo
317			iZooFe(nz) = iZoo + 2strideCompZoo + (nz-1)strideTypeZoo
318			iZooSi(nz) = iZoo + 3strideCompZoo + (nz-1)strideTypeZoo
319			ENDDO
320			#ifdef ALLOW_CARBON
321			DO nz = 1,nzmax
322			iZooC (nz) = iZoC + (nz-1)
323			ENDDO
324			#endif
325
326			#ifdef DAR_DIAG_DIVER
327			c only look at grid point with a minimum biomass
328			diver_thresh0=1 _d -12
329			c diver1 - if any type greater than
330			diver_thresh1=1 _d -8
331			c diver2 - if more than this proportion of total biomass
332			diver_thresh2=1 _d -3
333			c diver3 - fraction of biomass to count
334			diver_thresh3=.999 _d 0
335			c diver4 - fraction of maximum species
336			diver_thresh4=1 _d -5
337			#endif
338
339			c set up diagnostics
340			#ifdef ALLOW_MNC
341			IF ( useMNC ) THEN
342			CALL DARWIN_MNC_INIT( myThid )
343			#ifdef ALLOW_CARBON
344			CALL DIC_MNC_INIT( myThid )
345			#endif
346			ENDIF
347			#endif /* ALLOW_MNC */
348
349			COJ set up diagnostics
350			#ifdef ALLOW_DIAGNOSTICS
351			IF ( useDIAGNOSTICS ) THEN
352			CALL MONOD_DIAGNOSTICS_INIT( myThid )
353			#ifdef ALLOW_CARBON
354			CALL DIC_DIAGNOSTICS_INIT( myThid )
355			#endif
356			ENDIF
357			#endif /* ALLOW_DIAGNOSTICS */
358			COJ
359
360
361
362			RETURN
363			END
364			C============================================================================
365			#endif
366			#endif
367