Measured and modeled primary production in the northeast Atlantic (EUMELI JGOFS program): the impact of natural variations in photosynthetic parameters on model predictive skill
暂无分享,去创建一个
Marcel Babin | André Morel | David Antoine | D. Antoine | A. Morel | M. Babin | Y. Dandonneau | Yves Dandonneau
[1] B. Woźniak,et al. Optical absorption properties of phytoplankton in various seas , 1990 .
[2] André Morel,et al. Light and marine photosynthesis: a spectral model with geochemical and climatological implications , 1991 .
[3] Trevor Platt,et al. Remote sensing of oceanic primary production: computations using a spectral model , 1989 .
[4] André Morel,et al. Validation of a spectral light‐photosynthesis model and use of the model in conjunction with remotely sensed pigment observations , 1992 .
[5] Hugh L. MacIntyre,et al. Fluorescence assessment of the maximum quantum efficiency of photosynthesis in the western North Atlantic , 1993 .
[6] W. Richard,et al. TEMPERATURE AND PHYTOPLANKTON GROWTH IN THE SEA , 1972 .
[7] A. Bricaud,et al. Spectral absorption coefficients of living phytoplankton and nonalgal biogenous matter: A comparison between the Peru upwelling areaand the Sargasso Sea , 1990 .
[8] T. Platt,et al. The Utility of Light-Saturation Models for Estimating Marine Primary Productivity in the Field: A Comparison with Conventional "Simulated" In Situ Methods , 1985 .
[9] R. Lande,et al. Models of photoadaptation and photosynthesis by algal cells in a turbulent mixed layer , 1989 .
[10] Warren L. Butler,et al. Absorption of light by turbid materials , 1962 .
[11] A. Morel. Optical modeling of the upper ocean in relation to its biogenous matter content (case I waters) , 1988 .
[12] K. Carder,et al. Reflectance Model for Quantifying Chlorophyll- a in the Presence of Productivity Degradation Products , 1991 .
[13] Trevor Platt,et al. Mathematical formulation of the relationship between photosynthesis and light for phytoplankton , 1976 .
[14] T. Platt,et al. Oceanic Primary Production: Estimation by Remote Sensing at Local and Regional Scales , 1988, Science.
[15] K. Richardson. Comparison of 14C primary production determinations made by different laboratories , 1991 .
[16] T. Platt,et al. Basin-scale estimates of oceanic primary production by remote sensing - The North Atlantic , 1991 .
[17] A. Morel,et al. Pigment distribution and primary production in the western Mediterranean as derived and modeled from coastal zone color scanner observations , 1991 .
[18] D. Antoine,et al. Algal pigment distribution and primary production in the eastern Mediterranean as derived from coastal zone color scanner observations , 1995 .
[19] A. Morel,et al. The relation of oceanic primary production to available photosynthetic irradiance , 1976 .
[20] J. Cleveland. Regional models for phytoplankton absorption as a function of chlorophyll a concentration , 1995 .
[21] P. Falkowski,et al. Role of eddy pumping in enhancing primary production in the ocean , 1991, Nature.
[22] F. Lantoine,et al. Vertical structure of picophytoplankton at different trophic sites of the tropical northeastern Atlantic Ocean , 1996 .
[23] Y. Dandonneau,et al. A simple and rapid device for measuring planktonic primary production by in situ sampling, and 14C injection and incubation , 1992 .
[24] J. Cullen,et al. The kinetics of algal photoadaptation in the context of vertical mixing , 1988 .
[25] E. Fee. A Numerical Model for Determining Integral Primary Production and its Application to Lake Michigan , 1973 .
[26] T. Platt,et al. Absorption and photosynthetic action spectra for natural phytoplankton populations: Implications for production in the open ocean1 , 1985 .
[27] W. J. Henley. MEASUREMENT AND INTERPRETATION OF PHOTOSYNTHETIC LIGHT‐RESPONSE CURVES IN ALGAE IN THE CONTEXT OF PHOTOINHIBITION AND DIEL CHANGES , 1993 .
[28] P. Falkowski,et al. Nitrogen- and irradiance-dependent variations of the maximum quantum yield of carbon fixation in eutrophic, mesotrophic and oligotrophic marine systems , 1996 .
[29] B. Côté,et al. Utility of the light-saturation curve as an operational model for quantifying the effects of environmental conditions on phytoplankton photosynthesis , 1984 .
[30] T. Platt,et al. Turbulent motions may control phytoplankton photosynthesis in the upper ocean , 1984, Nature.
[31] H. Claustre,et al. Variability in the chlorophyll‐specific absorption coefficients of natural phytoplankton: Analysis and parameterization , 1995 .
[32] T. Platt,et al. An estimate of global primary production in the ocean from satellite radiometer data , 1995 .
[33] Jean-Michel André,et al. Spatial/temporal variability of algal biomass and potential productivity in the Mauritanian upwelling zone, as estimated from CZCS data , 1987 .
[34] Paul G. Falkowski,et al. Primary Productivity and Biogeochemical Cycles in the Sea , 1992 .
[35] A. Keller. Modeling the effects of temperature, light, and nutrients on primary productivity: An empirical and a mechanistic approach compared , 1989 .
[36] A. Morel,et al. An incubator designed for extensive and sensitive measurements of phytoplankton photosynthetic parameters , 1994 .
[37] Curtiss O. Davis,et al. Photosynthetic characteristics and estimated growth rates indicate grazing is the proximate control of primary production in the equatorial Pacific , 1992 .
[38] Patrick Raimbault,et al. Feasibility of using an automated colorimetric procedure for the determination of seawater nitrate in the 0 to 100 nM range: Examples from field and culture , 1990 .
[39] J. Talling,et al. THE PHYTOPLANKTON POPULATION AS A COMPOUND PHOTOSYNTHETIC SYSTEM , 1957 .
[40] A. Morel,et al. Surface pigments, algal biomass profiles, and potential production of the euphotic layer: Relationships reinvestigated in view of remote‐sensing applications , 1989 .
[41] H. Sosik,et al. Light absorption by phytoplankton, photosynthetic pigments and detritus in the California Current System , 1995 .
[42] H. Claustre,et al. Specific phytoplankton biomasses and their relation to primary production in the tropical North Atlantic , 1995 .
[43] T. Platt,et al. Ocean primary production and available light: further algorithms for remote sensing , 1988 .
[44] D. Antoine,et al. Oceanic primary production: 2. Estimation at global scale from satellite (Coastal Zone Color Scanner) chlorophyll , 1996 .
[45] T. Platt,et al. Photosynthetic action, absorption, and quantum yield spectra for a natural population of Oscillatoria in the North Atlantic , 1988 .
[46] M. Lewis,et al. Satellite Ocean Color Observations of Global Biogeochemical Cycles , 1992 .
[47] H. Gordon,et al. Remote Assessment of Ocean Color for Interpretation of Satellite Visible Imagery: A Review , 1983 .
[48] D. Antoine,et al. Oceanic primary production: 1. Adaptation of a spectral light‐photosynthesis model in view of application to satellite chlorophyll observations , 1996 .
[49] A. Weidemann,et al. The maximum quantum yield of phylopiankton photosynthesis in situ , 1984 .
[50] Motoaki Kishino,et al. Estimation of the spectral absorption coefficients of phytoplankton in the sea , 1985 .
[51] Susan Walsh,et al. Ocean color: Availability of the global data set , 1989 .
[52] Motoaki Kishino,et al. Light Utilization Efficiency and Quantum Yield of Phytoplankton in a Thermally Stratified Seai , 1986 .
[53] J. Szyper,et al. Temporal and spatial variability of phytoplankton in a subtropical ecosystem1,2 , 1984 .