darwin2/doc/monod_equations.tex

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%MICK - STUFF TO USE HELVETICA FONTS IN TEX
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\begin{document}

% SOME MACROS
\newcommand{\etal}{{\em et al.}}
\newcommand{\ux}{{\underline{x}}}
\newcommand{\tdt}{{t}}


{\bf {\large A1. Ecosystem Model Parametrization}}

The ecosystem model equations are similar that used in Follows et al. (2007).
Most significant change is that the grazing term is now includes variable
palatibility of phytoplankton and sloppy feeding as treated in Dutkiewicz et al
(2005), and the nitrogen limitation term has been slightly modified.  For
fuller discussions we refer the reader to the Online Supplemental material of
Follows et al. (2007).

Several nutrients $N_i$ nourish many phytoplankton types $P_j$ which are grazed
by several zooplankton types $Z_k$. Mortality of and excretion from plankton,
and sloppy feeding by zooplankton contribute to a dissolved organic matter
$DOM_i$ pool and a sinking particulate organic matter pool $POM_i$.  Subscript
$i$ refers to a nutrient/element, $j$ for a specific phytoplankton type, and
$k$ for a zooplankton type.

\begin{eqnarray}
\frac{\partial N_i}{\partial t} & = & 
-\nabla \cdot (\textbf{u} N_i) +\nabla \cdot (\kappa\nabla N_i)-
\sum_j [\mu_j P_j M_{ij}]+S_{N_i}
\nonumber  \\
\frac{\partial P_j}{\partial t} & = & 
-\nabla \cdot (\textbf{u} P_j) + \nabla \cdot (\kappa\nabla P_j)+
\mu_j P_j - m_j^P P_j-\sum_k [g_{jk} Z_{k,i=1}]
-\frac{\partial(w_j^P P_j)}{\partial z}
\nonumber \\
\frac{\partial Z_{ki}}{\partial t} & = & 
- \nabla \cdot (\textbf{u} Z_{ki}) + \nabla \cdot (\kappa\nabla Z_{ki})
+Z_{ki}\sum_j [\zeta_{jk} g_{jk} M_{ij}] -m_k^Z Z_{ki}
\nonumber \\
\frac{\partial POM_i}{\partial t} & = & 
-\nabla \cdot (\textbf{u} POM_i) + \nabla \cdot (\kappa\nabla POM_i)-
r_{PO_i}POM_i-\frac{\partial(w_{POi} POM_i)}{\partial z}+S_{POM_i}
\nonumber \\
\frac{\partial DOM_i}{\partial t} & = & 
-\nabla \cdot (\textbf{u} DOM_i) + \nabla \cdot (\kappa\nabla DOM_i)- 
r_{DO_i}DOM_i + S_{DOM_i} 
\nonumber
\end{eqnarray}

where:\\
\mbox{} \hspace{.5cm} $\textbf{u}=(u,v,w),$ velocity in physical model, \\
\mbox{} \hspace{.5cm} $\kappa=$Mixing coefficients used in physical model,\\
\mbox{} \hspace{.5cm} $\mu_j=$Growth rate of phytoplankton $j$ (see below),\\
\mbox{} \hspace{.5cm} $M_{ij}=$Matrix of Redfield ratio of element $i$ to P
for phytoplankton $j$\\
\mbox{} \hspace{.5cm} $\zeta_{jk}=$ Grazing efficiency of zooplankton $k$ on phytoplankton $j$ (represents sloppy feeding), \\
\mbox{} \hspace{.5cm} $g_{jk}=$Grazing of zooplankton $k$ on phytoplankton $j$ (see below),\\
\mbox{} \hspace{.5cm} $m_j^P=$Mortality/Excretion rate for phytoplankton $j$,\\
\mbox{} \hspace{.5cm} $m_k^Z=$Mortality/Excretion rate for zooplankton $k$,\\
\mbox{} \hspace{.5cm} $w_j^P=$Sinking rate for phytoplankton $j$,\\
\mbox{} \hspace{.5cm} $w_{POi}=$Sinking rate for POM $i$,\\
\mbox{} \hspace{.5cm} $r_{DOM_i}=$Remineralization rate of DOM for element
$i$,\\
\mbox{} \hspace{.5cm} $r_{POM_i}=$Remineralization rate of POM for element
$i$,\\
\mbox{} \hspace{.5cm} $S_{N_i}=$Additional source or sink for nutrient $i$
(see below),\\
\mbox{} \hspace{.5cm} $S_{DOM_i}=$ Source of DOM $i$,
for element $i$ (see below),\\
\mbox{} \hspace{.5cm} $S_{POM_i}=$ Source of POM $i$,
for element $i$ (see below),\\


\vspace{.2cm}

{\it {\bf A1.1. Phytoplankton growth:}}\\
\[
\mu_j = \mu_{max_{j}} \gamma_j^T \gamma_j^I \gamma_j^N
\]
where\\
\mbox{} \hspace{.5cm} $\mu_{max_{j}}=$ maximum growth rate of phytoplankton $j$,\\
\mbox{} \hspace{.5cm} $\gamma_j^T=$Modification of growth rate by
temperature for phytoplankton $j$,\\
\mbox{} \hspace{.5cm} $\gamma_j^I=$Modification of growth rate by light for
phytoplankton $j$,\\
\mbox{} \hspace{.5cm} $\gamma_j^N=$Modification of growth rate by nutrients
for phytoplankton $j$.\\

Temperature modification (Fig. \ref{fig-growexp1}a):\\
\[
\gamma_j^T= \frac{1}{\tau_1} (A^T e^{-B(T-T_o)^c} - \tau_2 )
\]
where coefficients $\tau_1$ and $\tau_2$ normalize the maximum
value, and $A,B,T_o$ and $C$ regulate the form of the temperature
modification function. $T$ is the local model ocean temperature.

Light modification (Fig. \ref{fig-growexp1}b):\\
\[
\gamma_j^I= \frac{1}{F_o} (1-e^{k_{par} I} ) e^{-k_{inhib} I}
\]
where $F_{o}$ is a factor controlling the maximum value, $k_{par}$ is the
PAR saturation coefficient and $k_{inhib}$ is the PAR inhibition factor.
$I$ is the local PAR, that has been attenuated through the water column
(including the effects of self-shading).

Nutrient limitation is determined by the most limiting nutrient:
\[
\gamma_j^N = \min(N_i^{lim})
\]
where typically
$N_i^{lim}=\frac{N_i}{N_i+\kappa_{N_{ij}}}$
(Fig. \ref{fig-growexp1}c) and $\kappa_{N_{ij}}$ is the half saturation constant of nutrient $i$ for phytoplankton $j$.

When we include the nitrogen as a potential limiting nutrient (EXP2) we 
modify $N_i^{lim}$ to take into account the uptake inhibition caused by ammonium:
\begin{align*}
N_N^{lim} &= \frac{NO_2}{NO_2+\kappa_{IN}} e^{-\psi NH_4}
+\frac{NH_4}{NH_4 + \kappa_{NH4}}  && \text{(nsource=1)} \\
N_N^{lim} &= \frac{NH_4}{NH_4 + \kappa_{NH4}}  && \text{(nsource=2)} \\
N_N^{lim} &= \frac{NO_3 + NO_2}{NO_3+NO_2+\kappa_{IN}} e^{-\psi NH_4}
+\frac{NH_4}{NH_4 + \kappa_{NH4}}  && \text{(nsource=3)}
\end{align*}
where $\psi$ reflects the inhibition and $\kappa_{IN}$ and $ \kappa_{NH4}$
are the half saturation constant of $IN=NO_3+NO_2$ and $NH_4$ respectively.

\vspace{.2cm}

{\it {\bf A1.2. Zooplankton grazing:}}\\
\[
 g_{jk} =g_{max_{jk}} \frac{\eta_{jk} P_j}{A_k} \frac{A_k}{A_k+\kappa^P_k}
\]
where\\
\mbox{} \hspace{.5cm} $g_{max_{jk}}=$ Maximum grazing rate of zooplankton $k$ on
phytoplankton $j$,\\
\mbox{} \hspace{.5cm} $\eta_{jk}=$ Palatibility of plankton $j$ to zooplankton $k$,\\
\mbox{} \hspace{.5cm} $A_k=$ Palatibility (for zooplankton $k$) weighted total phytoplankton concentration,\\
\mbox{} \hspace{1.1cm} $=\sum_j [\eta_{jk} P_j$] \\
\mbox{} \hspace{.5cm} $\kappa^P_k=$Half-saturation constant for grazing of zooplankton $k$,\\


\vspace{.2cm}

{\it {\bf A1.3. Inorganic nutrient Source/Sink terms:}}\\
$S_{N_i}$ depends on the specific nutrient, and includes the remineralization
of organic matter, external sources and other non-biological transformations:
\begin{eqnarray}
S_{PO4} & = & r_{DOP} DOP + r_{POP} POP \nonumber \\
S_{Si}  & = & r_{POSi} POSi \nonumber \\
S_{FeT} & = &  r_{DOFe} DOFe + r_{POFe} POFe -c_{scav} Fe' + \alpha F_{atmos} \nonumber \\
S_{NO3} & = &  \zeta_{NO3} NO_2 \nonumber \\
S_{NO2} & = &  \zeta_{NO2} NH4 - \zeta_{NO3} NO_2 \nonumber \\
S_{NH4} & = &  r_{DON} DON + r_{PON} PON - \zeta_{NO2} NH_4 \nonumber
\end{eqnarray}

where:\\
\mbox{} \hspace{.5cm} $r_{DOM_i}=$Remineralization rate of DOM for element
$i$, here P, Fe, N,\\
\mbox{} \hspace{.5cm} $r_{POM_i}=$Remineralization rate of POM for element
$i$, here P, Si, Fe, N,\\
\mbox{} \hspace{.5cm} $c_{scav}=$scavenging rate for free iron,\\
\mbox{} \hspace{.5cm} $Fe'=$free iron, modelled as in Parekh et al (2004), \\
\mbox{} \hspace{.5cm} $alpha=$solubility of iron dust in ocean water, \\
\mbox{} \hspace{.5cm} $F_{atmos}=$atmospheric deposition of iron dust on surface of model ocean,\\
\mbox{} \hspace{.5cm} $\zeta_{NO3}=\zeta_{NO3}^0(1-I/I_0)_+=$oxidation rate of NO$_2$ to NO$_3$,\\
\mbox{} \hspace{.5cm} $\zeta_{NO2}=\zeta_{NO2}^0(1-I/I_0)_+=$oxidation rate of NH$_4$ to NO$_2$ (is photoinhibited),\\
\mbox{} \hspace{.5cm} $I_0=$critical light level below which oxidation occurs,\\

The remineralization timescale $r_{DOi}$ and $r_{POi}$ parameterizes the break
down of organic matter to an inorganic form through the microbial loop.


{\it {\bf A1.3.1 Fe chemistry:}}\\
\begin{eqnarray}
Fe' & = & FeT - FeL \nonumber \\
FeL & = & L_{tot} -
  \frac{ L_{stab} (L_{tot} - FeT) - 1
        +\sqrt{(1 - L_{stab} (L_{tot} - FeT))^2 + 4 L_{stab} L_{tot}}}
     {2 L_{stab}} \nonumber
\end{eqnarray}
($Fe'$ may be constrained to be less than $Fe'_{max}$ while preserving $FeT$).

 
{\it {\bf A1.4 DOM and POM Source terms:}}\\
$S_{DOM_i}$ and $S_{POM_i}$ are the sources of dissolved and particulate
organic detritus arising from mortality, excretion and sloppy feeding of the
plantkon. We simply define that a fixed fraction $\lambda_m$ of the the
mortality/excretion term and the non-consumed grazed phytoplankton
($\lambda_g$) go into the dissolved pool and the remainder into the particulate
pool. 
\begin{eqnarray}
S_{DOM_i} & = & \sum_{j} [\lambda_{mp_{ij}} m^p_j P_j M_{ij}] 
             + \sum_{k} [\lambda_{mz_{ik}} m^z_k Z_{ik}]
             + \sum_{k} \sum_{j} [\lambda_{g_{ijk}} (1-\zeta_{jk})
                                        g_{ij} M_{ij} Z_k ]
\nonumber \\
S_{POM_i} & = & \sum_{j} [(1-\lambda_{m_{ij}}) m^p_j P_j M_{ij}]
             + \sum_{k} [(1-\lambda_{mz_{ik}}) m^z_k Z_{ik}]
             + \sum_{k} \sum_{j} [(1-\lambda_{g_{ijk}}) (1-\zeta_{jk})  
                                       g_{ij} M_{ij} Z_k ]
\nonumber
\end{eqnarray}


\newcommand{\pcm}[1]{P^C_{m#1}}
\newcommand{\pcmax}[1]{P^C_{\textrm{MAX}#1}}
\newcommand{\pcarbon}{P^C}
\newcommand{\chltoc}{\theta}
\newcommand{\chltocmax}{\theta^{\textrm{max}}}
\newcommand{\chltocmin}{\theta^{\textrm{min}}}
\newcommand{\alphachl}{\alpha^{\textrm{Chl}}}
\newcommand{\mQyield}{\mathit{mQ}^{\textrm{yield}}}
\newcommand{\RPC}{R^{PC}}
\newcommand{\phychl}{\mathit{Chl}}
\newcommand{\aphychlave}{A^{\mathrm{phy}}_{\mathrm{Chl,ave}}}

{\it {\bf A1.4 Geider light limitation model:}}\\
The phytoplankton growth rate is given by the carbon-specific photosynthesis rate
(rate of carbon synthesized per carbon present),
\[
  \mu_j = \pcarbon_j
\]
The carbon-specific photosynthesis rate
\[
  \pcarbon_j = \pcm{,j} \begin{cases}
     1 - e^{-\alphachl_j I \chltoc_j/\pcm{,j}} & \text{if }I>0.1 \\
     0                                         & \text{otherwise}
   \end{cases}
\]
depends on the carbon-specific, light-saturated photosynthesis rate
\[
  \pcm{,j}=\pcmax{j} \gamma^N_j \gamma^T_j
\]
and the Chl $a$ to carbon ratio
\[
  \chltoc_j = \left[ \frac{\chltocmax_j}
                   {1 + \chltocmax_j \alphachl_j I / (2 \pcm{,j})}
                   \right]^{\chltocmax_j}_{\chltocmin_j}
\]

The chlorophyll concentration is
\[
  \phychl_j=P_j \RPC_j \chltoc_j
\]

The light limitation factor can be diagnosed
\[
  \gamma^I_j=\pcarbon_j/\pcm{,j}
\]

\[
  \alphachl_j = \mQyield_j \aphychlave
\]

Parameters:\\
\begin{tabular}{@{\qquad}r@{}l}
 $\pcmax{j}    ={}$& Maximum C-spec.\ photosynthesis rate at reference temperature of phytoplankton $j$\\
 $\chltocmax_j ={}$& Maximum Chl a to C ratio if phytoplankton $j$\\
 $\RPC_j       ={}$& Carbon to phosphorus (!) ratio of phytoplankton $j$\\
 $\alphachl_j  ={}$& Chl a-specific initial slope of the photosynthesis-light curve\\
 $\mQyield_j   ={}$& slope of the photosynthesis-light curve per absorption\\
 $\aphychlave  ={}$& absorption ($m^{-1}$) per mg Chl a
\end{tabular}


\newcommand{\Ptot}{P_{\mathrm{tot}}}

{\it {\bf A2 Diagnostics:}}\\
Total phytoplankton biomass:
\[
  \Ptot = \sum_j P_j
\]

\begin{tabular}{llll}
 name & definition && units \\
\hline
 \texttt{PhyTot  } & $\Ptot$                                                        && $\mu\mathrm{M\,P}$ \\
 \texttt{PhyGrp1 } & Total biomass of small phytoplankton with $\texttt{nsrc}=1$    && $\mu\mathrm{M\,P}$ \\
 \texttt{PhyGrp2 } & Total biomass of small phytoplankton with $\texttt{nsrc}=2$    && $\mu\mathrm{M\,P}$ \\
 \texttt{PhyGrp3 } & Total biomass of small phytoplankton with $\texttt{nsrc}=3$    && $\mu\mathrm{M\,P}$ \\
 \texttt{PhyGrp4 } & Total biomass of large non-diatoms                             && $\mu\mathrm{M\,P}$ \\
 \texttt{PhyGrp5 } & Total biomass of diatoms                                       && $\mu\mathrm{M\,P}$ \\
 \texttt{PP      } & Primary production                                             && $\mu\mathrm{M\,P}\, \mathrm{s}^{-1}$ \\
 \texttt{Nfix    } & Nitrogen fixation                                              && $\mu\mathrm{M\,N}\, \mathrm{s}^{-1}$ \\
 \texttt{PAR     } & Photosynthetically active radiation                            && $\mu\mathrm{Ein}\, \mathrm{m}^{-2}\,\mathrm{s}^{-1}$ \\
 \texttt{Rstar01 } & $R^*_{\mathrm{PO4}}$ of Phytoplankton species \#1, \dots       && $\mu\mathrm{M\,P}$ \\
 \texttt{Diver1  } & Number of species with $P_j > 10^{-8}\,\mu\mathrm{M\,P}$       & where $\Ptot>10^{-12}$ \\
 \texttt{Diver2  } & Number of species with $P_j > 0.1\%\,  \Ptot$                  & where $\Ptot>10^{-12}$ \\
 \texttt{Diver3  } & Number of species that constitute 99.9\% of $\Ptot$            & where $\Ptot>10^{-12}$ \\
 \texttt{Diver4  } & Number of species with $P_j > 10^{-5} \cdot \max\limits_j P_j$ & where $\Ptot>10^{-12}$ \\
\end{tabular}


\end{document} 
1	jahn	1.1	\documentclass[11pt,letterpaper,english]{article}
2			\usepackage[T1]{fontenc}
3			\usepackage[latin1]{inputenc}
4			\setlength\parskip{\medskipamount}
5			\setlength\parindent{0pt}
6			\usepackage{amsmath}
7			%\usepackage{graphicx}
8			\usepackage{amssymb}
9			\usepackage{babel}
10			%use epsfig package for figs
11			\usepackage{epsfig}
12			\makeatother
13
14
15			%MICK - STUFF TO USE HELVETICA FONTS IN TEX
16			%%\usepackage[scaled=0.92]{helvet}
17			\usepackage{helvet}
18			\usepackage[sf]{titlesec}
19			\renewcommand\familydefault{\sfdefault}
20
21			%use lgrind to include code listing
22			%\usepackage{lgrind}
23
24			%other formatting stuff
25			\oddsidemargin 0pt
26			\flushbottom
27			\parskip 10pt
28			\parindent 0pt
29			\textwidth 465pt
30			\topmargin 10pt
31			\textheight 610pt
32			\renewcommand{\baselinestretch}{1.0}
33
34
35			\begin{document}
36
37			% SOME MACROS
38			\newcommand{\etal}{{\em et al.}}
39			\newcommand{\ux}{{\underline{x}}}
40			\newcommand{\tdt}{{t}}
41
42
43			{\bf {\large A1. Ecosystem Model Parametrization}}
44
45			The ecosystem model equations are similar that used in Follows et al. (2007).
46			Most significant change is that the grazing term is now includes variable
47			palatibility of phytoplankton and sloppy feeding as treated in Dutkiewicz et al
48			(2005), and the nitrogen limitation term has been slightly modified. For
49			fuller discussions we refer the reader to the Online Supplemental material of
50			Follows et al. (2007).
51
52			Several nutrients $N_i$ nourish many phytoplankton types $P_j$ which are grazed
53			by several zooplankton types $Z_k$. Mortality of and excretion from plankton,
54			and sloppy feeding by zooplankton contribute to a dissolved organic matter
55			$DOM_i$ pool and a sinking particulate organic matter pool $POM_i$. Subscript
56			$i$ refers to a nutrient/element, $j$ for a specific phytoplankton type, and
57			$k$ for a zooplankton type.
58
59			\begin{eqnarray}
60			\frac{\partial N_i}{\partial t} & = &
61			-\nabla \cdot (\textbf{u} N_i) +\nabla \cdot (\kappa\nabla N_i)-
62			\sum_j [\mu_j P_j M_{ij}]+S_{N_i}
63			\nonumber \\
64			\frac{\partial P_j}{\partial t} & = &
65			-\nabla \cdot (\textbf{u} P_j) + \nabla \cdot (\kappa\nabla P_j)+
66			\mu_j P_j - m_j^P P_j-\sum_k [g_{jk} Z_{k,i=1}]
67			-\frac{\partial(w_j^P P_j)}{\partial z}
68			\nonumber \\
69			\frac{\partial Z_{ki}}{\partial t} & = &
70			- \nabla \cdot (\textbf{u} Z_{ki}) + \nabla \cdot (\kappa\nabla Z_{ki})
71			+Z_{ki}\sum_j [\zeta_{jk} g_{jk} M_{ij}] -m_k^Z Z_{ki}
72			\nonumber \\
73			\frac{\partial POM_i}{\partial t} & = &
74			-\nabla \cdot (\textbf{u} POM_i) + \nabla \cdot (\kappa\nabla POM_i)-
75			r_{PO_i}POM_i-\frac{\partial(w_{POi} POM_i)}{\partial z}+S_{POM_i}
76			\nonumber \\
77			\frac{\partial DOM_i}{\partial t} & = &
78			-\nabla \cdot (\textbf{u} DOM_i) + \nabla \cdot (\kappa\nabla DOM_i)-
79			r_{DO_i}DOM_i + S_{DOM_i}
80			\nonumber
81			\end{eqnarray}
82
83			where:\\
84			\mbox{} \hspace{.5cm} $\textbf{u}=(u,v,w),$ velocity in physical model, \\
85			\mbox{} \hspace{.5cm} $\kappa=$Mixing coefficients used in physical model,\\
86			\mbox{} \hspace{.5cm} $\mu_j=$Growth rate of phytoplankton $j$ (see below),\\
87			\mbox{} \hspace{.5cm} $M_{ij}=$Matrix of Redfield ratio of element $i$ to P
88			for phytoplankton $j$\\
89			\mbox{} \hspace{.5cm} $\zeta_{jk}=$ Grazing efficiency of zooplankton $k$ on phytoplankton $j$ (represents sloppy feeding), \\
90			\mbox{} \hspace{.5cm} $g_{jk}=$Grazing of zooplankton $k$ on phytoplankton $j$ (see below),\\
91			\mbox{} \hspace{.5cm} $m_j^P=$Mortality/Excretion rate for phytoplankton $j$,\\
92			\mbox{} \hspace{.5cm} $m_k^Z=$Mortality/Excretion rate for zooplankton $k$,\\
93			\mbox{} \hspace{.5cm} $w_j^P=$Sinking rate for phytoplankton $j$,\\
94			\mbox{} \hspace{.5cm} $w_{POi}=$Sinking rate for POM $i$,\\
95			\mbox{} \hspace{.5cm} $r_{DOM_i}=$Remineralization rate of DOM for element
96			$i$,\\
97			\mbox{} \hspace{.5cm} $r_{POM_i}=$Remineralization rate of POM for element
98			$i$,\\
99			\mbox{} \hspace{.5cm} $S_{N_i}=$Additional source or sink for nutrient $i$
100			(see below),\\
101			\mbox{} \hspace{.5cm} $S_{DOM_i}=$ Source of DOM $i$,
102			for element $i$ (see below),\\
103			\mbox{} \hspace{.5cm} $S_{POM_i}=$ Source of POM $i$,
104			for element $i$ (see below),\\
105
106
107
108			\vspace{.2cm}
109
110			{\it {\bf A1.1. Phytoplankton growth:}}\\
111			\[
112			\mu_j = \mu_{max_{j}} \gamma_j^T \gamma_j^I \gamma_j^N
113			\]
114			where\\
115			\mbox{} \hspace{.5cm} $\mu_{max_{j}}=$ maximum growth rate of phytoplankton $j$,\\
116			\mbox{} \hspace{.5cm} $\gamma_j^T=$Modification of growth rate by
117			temperature for phytoplankton $j$,\\
118			\mbox{} \hspace{.5cm} $\gamma_j^I=$Modification of growth rate by light for
119			phytoplankton $j$,\\
120			\mbox{} \hspace{.5cm} $\gamma_j^N=$Modification of growth rate by nutrients
121			for phytoplankton $j$.\\
122
123			Temperature modification (Fig. \ref{fig-growexp1}a):\\
124			\[
125			\gamma_j^T= \frac{1}{\tau_1} (A^T e^{-B(T-T_o)^c} - \tau_2 )
126			\]
127			where coefficients $\tau_1$ and $\tau_2$ normalize the maximum
128			value, and $A,B,T_o$ and $C$ regulate the form of the temperature
129			modification function. $T$ is the local model ocean temperature.
130
131			Light modification (Fig. \ref{fig-growexp1}b):\\
132			\[
133			\gamma_j^I= \frac{1}{F_o} (1-e^{k_{par} I} ) e^{-k_{inhib} I}
134			\]
135			where $F_{o}$ is a factor controlling the maximum value, $k_{par}$ is the
136			PAR saturation coefficient and $k_{inhib}$ is the PAR inhibition factor.
137			$I$ is the local PAR, that has been attenuated through the water column
138			(including the effects of self-shading).
139
140			Nutrient limitation is determined by the most limiting nutrient:
141			\[
142			\gamma_j^N = \min(N_i^{lim})
143			\]
144			where typically
145			$N_i^{lim}=\frac{N_i}{N_i+\kappa_{N_{ij}}}$
146			(Fig. \ref{fig-growexp1}c) and $\kappa_{N_{ij}}$ is the half saturation constant of nutrient $i$ for phytoplankton $j$.
147
148			When we include the nitrogen as a potential limiting nutrient (EXP2) we
149			modify $N_i^{lim}$ to take into account the uptake inhibition caused by ammonium:
150			\begin{align*}
151			N_N^{lim} &= \frac{NO_2}{NO_2+\kappa_{IN}} e^{-\psi NH_4}
152			+\frac{NH_4}{NH_4 + \kappa_{NH4}} && \text{(nsource=1)} \\
153			N_N^{lim} &= \frac{NH_4}{NH_4 + \kappa_{NH4}} && \text{(nsource=2)} \\
154			N_N^{lim} &= \frac{NO_3 + NO_2}{NO_3+NO_2+\kappa_{IN}} e^{-\psi NH_4}
155			+\frac{NH_4}{NH_4 + \kappa_{NH4}} && \text{(nsource=3)}
156			\end{align*}
157			where $\psi$ reflects the inhibition and $\kappa_{IN}$ and $ \kappa_{NH4}$
158			are the half saturation constant of $IN=NO_3+NO_2$ and $NH_4$ respectively.
159
160			\vspace{.2cm}
161
162			{\it {\bf A1.2. Zooplankton grazing:}}\\
163			\[
164			g_{jk} =g_{max_{jk}} \frac{\eta_{jk} P_j}{A_k} \frac{A_k}{A_k+\kappa^P_k}
165			\]
166			where\\
167			\mbox{} \hspace{.5cm} $g_{max_{jk}}=$ Maximum grazing rate of zooplankton $k$ on
168			phytoplankton $j$,\\
169			\mbox{} \hspace{.5cm} $\eta_{jk}=$ Palatibility of plankton $j$ to zooplankton $k$,\\
170			\mbox{} \hspace{.5cm} $A_k=$ Palatibility (for zooplankton $k$) weighted total phytoplankton concentration,\\
171			\mbox{} \hspace{1.1cm} $=\sum_j [\eta_{jk} P_j$] \\
172			\mbox{} \hspace{.5cm} $\kappa^P_k=$Half-saturation constant for grazing of zooplankton $k$,\\
173
174
175			\vspace{.2cm}
176
177			{\it {\bf A1.3. Inorganic nutrient Source/Sink terms:}}\\
178			$S_{N_i}$ depends on the specific nutrient, and includes the remineralization
179			of organic matter, external sources and other non-biological transformations:
180			\begin{eqnarray}
181			S_{PO4} & = & r_{DOP} DOP + r_{POP} POP \nonumber \\
182			S_{Si} & = & r_{POSi} POSi \nonumber \\
183			S_{FeT} & = & r_{DOFe} DOFe + r_{POFe} POFe -c_{scav} Fe' + \alpha F_{atmos} \nonumber \\
184			S_{NO3} & = & \zeta_{NO3} NO_2 \nonumber \\
185			S_{NO2} & = & \zeta_{NO2} NH4 - \zeta_{NO3} NO_2 \nonumber \\
186			S_{NH4} & = & r_{DON} DON + r_{PON} PON - \zeta_{NO2} NH_4 \nonumber
187			\end{eqnarray}
188
189			where:\\
190			\mbox{} \hspace{.5cm} $r_{DOM_i}=$Remineralization rate of DOM for element
191			$i$, here P, Fe, N,\\
192			\mbox{} \hspace{.5cm} $r_{POM_i}=$Remineralization rate of POM for element
193			$i$, here P, Si, Fe, N,\\
194			\mbox{} \hspace{.5cm} $c_{scav}=$scavenging rate for free iron,\\
195			\mbox{} \hspace{.5cm} $Fe'=$free iron, modelled as in Parekh et al (2004), \\
196			\mbox{} \hspace{.5cm} $alpha=$solubility of iron dust in ocean water, \\
197			\mbox{} \hspace{.5cm} $F_{atmos}=$atmospheric deposition of iron dust on surface of model ocean,\\
198			\mbox{} \hspace{.5cm} $\zeta_{NO3}=\zeta_{NO3}^0(1-I/I_0)_+=$oxidation rate of NO$_2$ to NO$_3$,\\
199			\mbox{} \hspace{.5cm} $\zeta_{NO2}=\zeta_{NO2}^0(1-I/I_0)_+=$oxidation rate of NH$_4$ to NO$_2$ (is photoinhibited),\\
200			\mbox{} \hspace{.5cm} $I_0=$critical light level below which oxidation occurs,\\
201
202			The remineralization timescale $r_{DOi}$ and $r_{POi}$ parameterizes the break
203			down of organic matter to an inorganic form through the microbial loop.
204
205
206			{\it {\bf A1.3.1 Fe chemistry:}}\\
207			\begin{eqnarray}
208			Fe' & = & FeT - FeL \nonumber \\
209			FeL & = & L_{tot} -
210			\frac{ L_{stab} (L_{tot} - FeT) - 1
211			+\sqrt{(1 - L_{stab} (L_{tot} - FeT))^2 + 4 L_{stab} L_{tot}}}
212			{2 L_{stab}} \nonumber
213			\end{eqnarray}
214			($Fe'$ may be constrained to be less than $Fe'_{max}$ while preserving $FeT$).
215
216
217			{\it {\bf A1.4 DOM and POM Source terms:}}\\
218			$S_{DOM_i}$ and $S_{POM_i}$ are the sources of dissolved and particulate
219			organic detritus arising from mortality, excretion and sloppy feeding of the
220			plantkon. We simply define that a fixed fraction $\lambda_m$ of the the
221			mortality/excretion term and the non-consumed grazed phytoplankton
222			($\lambda_g$) go into the dissolved pool and the remainder into the particulate
223			pool.
224			\begin{eqnarray}
225			S_{DOM_i} & = & \sum_{j} [\lambda_{mp_{ij}} m^p_j P_j M_{ij}]
226			+ \sum_{k} [\lambda_{mz_{ik}} m^z_k Z_{ik}]
227			+ \sum_{k} \sum_{j} [\lambda_{g_{ijk}} (1-\zeta_{jk})
228			g_{ij} M_{ij} Z_k ]
229			\nonumber \\
230			S_{POM_i} & = & \sum_{j} [(1-\lambda_{m_{ij}}) m^p_j P_j M_{ij}]
231			+ \sum_{k} [(1-\lambda_{mz_{ik}}) m^z_k Z_{ik}]
232			+ \sum_{k} \sum_{j} [(1-\lambda_{g_{ijk}}) (1-\zeta_{jk})
233			g_{ij} M_{ij} Z_k ]
234			\nonumber
235			\end{eqnarray}
236
237
238			\newcommand{\pcm}[1]{P^C_{m#1}}
239			\newcommand{\pcmax}[1]{P^C_{\textrm{MAX}#1}}
240			\newcommand{\pcarbon}{P^C}
241			\newcommand{\chltoc}{\theta}
242			\newcommand{\chltocmax}{\theta^{\textrm{max}}}
243			\newcommand{\chltocmin}{\theta^{\textrm{min}}}
244			\newcommand{\alphachl}{\alpha^{\textrm{Chl}}}
245			\newcommand{\mQyield}{\mathit{mQ}^{\textrm{yield}}}
246			\newcommand{\RPC}{R^{PC}}
247			\newcommand{\phychl}{\mathit{Chl}}
248			\newcommand{\aphychlave}{A^{\mathrm{phy}}_{\mathrm{Chl,ave}}}
249
250			{\it {\bf A1.4 Geider light limitation model:}}\\
251			The phytoplankton growth rate is given by the carbon-specific photosynthesis rate
252			(rate of carbon synthesized per carbon present),
253			\[
254			\mu_j = \pcarbon_j
255			\]
256			The carbon-specific photosynthesis rate
257			\[
258			\pcarbon_j = \pcm{,j} \begin{cases}
259			1 - e^{-\alphachl_j I \chltoc_j/\pcm{,j}} & \text{if }I>0.1 \\
260			0 & \text{otherwise}
261			\end{cases}
262			\]
263			depends on the carbon-specific, light-saturated photosynthesis rate
264			\[
265			\pcm{,j}=\pcmax{j} \gamma^N_j \gamma^T_j
266			\]
267			and the Chl $a$ to carbon ratio
268			\[
269			\chltoc_j = \left[ \frac{\chltocmax_j}
270			{1 + \chltocmax_j \alphachl_j I / (2 \pcm{,j})}
271			\right]^{\chltocmax_j}_{\chltocmin_j}
272			\]
273
274			The chlorophyll concentration is
275			\[
276			\phychl_j=P_j \RPC_j \chltoc_j
277			\]
278
279			The light limitation factor can be diagnosed
280			\[
281			\gamma^I_j=\pcarbon_j/\pcm{,j}
282			\]
283
284			\[
285			\alphachl_j = \mQyield_j \aphychlave
286			\]
287
288			Parameters:\\
289			\begin{tabular}{@{\qquad}r@{}l}
290			$\pcmax{j} ={}$& Maximum C-spec.\ photosynthesis rate at reference temperature of phytoplankton $j$\\
291			$\chltocmax_j ={}$& Maximum Chl a to C ratio if phytoplankton $j$\\
292			$\RPC_j ={}$& Carbon to phosphorus (!) ratio of phytoplankton $j$\\
293			$\alphachl_j ={}$& Chl a-specific initial slope of the photosynthesis-light curve\\
294			$\mQyield_j ={}$& slope of the photosynthesis-light curve per absorption\\
295			$\aphychlave ={}$& absorption ($m^{-1}$) per mg Chl a
296			\end{tabular}
297
298
299
300			\newcommand{\Ptot}{P_{\mathrm{tot}}}
301
302			{\it {\bf A2 Diagnostics:}}\\
303			Total phytoplankton biomass:
304			\[
305			\Ptot = \sum_j P_j
306			\]
307
308			\begin{tabular}{llll}
309			name & definition && units \\
310			\hline
311			\texttt{PhyTot } & $\Ptot$ && $\mu\mathrm{M\,P}$ \\
312			\texttt{PhyGrp1 } & Total biomass of small phytoplankton with $\texttt{nsrc}=1$ && $\mu\mathrm{M\,P}$ \\
313			\texttt{PhyGrp2 } & Total biomass of small phytoplankton with $\texttt{nsrc}=2$ && $\mu\mathrm{M\,P}$ \\
314			\texttt{PhyGrp3 } & Total biomass of small phytoplankton with $\texttt{nsrc}=3$ && $\mu\mathrm{M\,P}$ \\
315			\texttt{PhyGrp4 } & Total biomass of large non-diatoms && $\mu\mathrm{M\,P}$ \\
316			\texttt{PhyGrp5 } & Total biomass of diatoms && $\mu\mathrm{M\,P}$ \\
317			\texttt{PP } & Primary production && $\mu\mathrm{M\,P}\, \mathrm{s}^{-1}$ \\
318			\texttt{Nfix } & Nitrogen fixation && $\mu\mathrm{M\,N}\, \mathrm{s}^{-1}$ \\
319			\texttt{PAR } & Photosynthetically active radiation && $\mu\mathrm{Ein}\, \mathrm{m}^{-2}\,\mathrm{s}^{-1}$ \\
320			\texttt{Rstar01 } & $R^*_{\mathrm{PO4}}$ of Phytoplankton species \#1, \dots && $\mu\mathrm{M\,P}$ \\
321			\texttt{Diver1 } & Number of species with $P_j > 10^{-8}\,\mu\mathrm{M\,P}$ & where $\Ptot>10^{-12}$ \\
322			\texttt{Diver2 } & Number of species with $P_j > 0.1\%\, \Ptot$ & where $\Ptot>10^{-12}$ \\
323			\texttt{Diver3 } & Number of species that constitute 99.9\% of $\Ptot$ & where $\Ptot>10^{-12}$ \\
324			\texttt{Diver4 } & Number of species with $P_j > 10^{-5} \cdot \max\limits_j P_j$ & where $\Ptot>10^{-12}$ \\
325			\end{tabular}
326
327
328			\end{document}