Readme for the data files to reproduce plots for Enhanced sensitivity of oceanic CO2 uptake to dust deposition by iron-light colimitation Levin Nickelsen Biogeochemical Modeling, GEOMAR Helmholtz-Centre of Ocean Research Kiel, Kiel, Germany Andreas Oschlies Biogeochemical Modeling, GEOMAR Helmholtz-Centre of Ocean Research Kiel, Kiel, Germany Geophysical Research Letters, 2014 -------------------------------------------------------------- List of variables in the files -------------------------------------------------------------- Figure 2 fig2.mat (matlab file) dpco2ironexii IRONEXII observed DPCO2 tdpco2ironexii IRONEXII observed time vector modeltimeironexII IRONEXII simulated time vector spco2maxi2 IRONEXII simulated maximum DPCO2 optimized spco2mini2 IRONEXII simulated minimum DPCO2 optimized spco2maxctli2ctl IRONEXII simulated maximum DPCO2 original spco2minctli2ctl IRONEXII simulated minimum DPCO2 original dpco2soiree SOIREE observed DPCO2 tdpco2soiree SOIREE observed time vector modeltimeSOIREE SOIREE simulated time vector spco2maxtnd SOIREE simulated time vector spco2mintnd SOIREE simulated minimum DPCO2 optimized spco2maxctl SOIREE simulated maximum DPCO2 original spco2minctl SOIREE simulated minimum DPCO2 original -------------------------------------------------------------- Figure 3 fig3_atmco2_ctl.mat control Atmospheric pCO2 Control fig3_atmco2_dc_ill.mat Atmospheric pCO2 for dust deposition as estimated for a climate with double CO2 concentration with iron-light colimitation fig3_atmco2_dc_noill.mat Atmospheric pCO2 for dust deposition as estimated for a climate with double CO2 concentration without iron-light colimitation fig3_atmco2_lgm_ill.mat Atmospheric pCO2 for dust deposition as estimated for last glacial maximum with iron-light colimitation fig3_atmco2_lgm_noill.mat Atmospheric pCO2 for dust deposition as estimated for last glacial maximum without iron-light colimitation fig3_exp_ctl.mat control Export production at 100 m Control fig3_exp_dc_ill.mat Export production at 100 m for dust deposition as estimated for a climate with double CO2 concentration with iron-light colimitation fig3_exp_dc_noill.mat Export production at 100 m for dust deposition as estimated for a climate with double CO2 concentration without iron-light colimitation fig3_exp_lgm_ill.mat Export production at 100 m for dust deposition as estimated for last glacial maximum with iron-light colimitation fig3_exp_lgm_noill.mat Export production at 100 m for dust deposition as estimated for last glacial maximum without iron-light colimitation -------------------------------------------------------------- Figure 4 SBP241EXPDC Export production at 100 m for dust deposition as estimated for a climate with double CO2 concentration with iron-light colimitation SBP242EXPDCZM Export production at 100 m for dust deposition as estimated for a climate with double CO2 concentration with iron-light colimitation (zonal mean) SBP243EXPLGM Export production at 100 m for dust deposition as estimated for last glacial maximum with iron-light colimitation SBP244EXPLGMZM Export production at 100 m for dust deposition as estimated for last glacial maximum with iron-light colimitation (zonal mean) SBP245PO4DC Surface phosphate concentration for dust deposition as estimated for a climate with double CO2 concentration with iron-light colimitation SBP246PO4DCZM Surface phosphate concentration for dust deposition as estimated for a climate with double CO2 concentration with iron-light colimitation (zonal mean) SBP247PO4LGM Surface phosphate concentration for dust deposition as estimated for last glacial maximum with iron-light colimitation SBP248PO4LGMZM Surface phosphate concentration for dust deposition as estimated for last glacial maximum with iron-light colimitation (zonal mean)