Biological production in two contrasted regions of the Mediterranean Sea during the oligotrophic period: An estimate based on the diel cycle of optical properties measured by BGC-Argo profiling floats
暂无分享,去创建一个
F. D’Ortenzio | V. Taillandier | H. Claustre | A. Bricaud | H. Loisel | J. Uitz | B. Gentili | Antoine Poteau | C. Schmechtig | A. Mignot | C. Roesler | Marie Barbieux | E. Leymarie | Christophe Penkerc’h
[1] F. D’Ortenzio,et al. Deep Chlorophyll Maxima in the Global Ocean: Occurrences, Drivers and Characteristics , 2021, Global biogeochemical cycles.
[2] A. Kemp,et al. The case of the diatoms and the muddled mandalas: Time to recognize diatom adaptations to stratified waters , 2018, Progress in Oceanography.
[3] Fabrizio D'Ortenzio,et al. Bio-optical characterization of subsurface chlorophyll maxima in the Mediterranean Sea from a Biogeochemical-Argo float database , 2018, Biogeosciences.
[4] Rosalia Santoleri,et al. Regional Empirical Algorithms for an Improved Identification of Phytoplankton Functional Types and Size Classes in the Mediterranean Sea Using Satellite Data , 2017, Front. Mar. Sci..
[5] Fabrizio D'Ortenzio,et al. On the vertical distribution of the chlorophyll a concentration in the Mediterranean Sea: a basin scale and seasonal approach , 2015 .
[6] Craig M. Lee,et al. A simple optical index shows spatial and temporal heterogeneity in phytoplankton community composition during the 2008 North Atlantic Bloom Experiment , 2015 .
[7] J. Cullen,et al. Subsurface chlorophyll maximum layers: enduring enigma or mystery solved? , 2015, Annual review of marine science.
[8] D. Antoine,et al. Proxies of community production derived from the diel variability of particulate attenuation and backscattering coefficients in the northwest Mediterranean Sea , 2014 .
[9] Tracy A. Villareal,et al. High diatom production and export in stratified waters – A potential negative feedback to global warming , 2013 .
[10] F. D’Ortenzio,et al. Estimates of phytoplankton class‐specific and total primary production in the Mediterranean Sea from satellite ocean color observations , 2012 .
[11] Francisco P Chavez,et al. Marine primary production in relation to climate variability and change. , 2011, Annual review of marine science.
[12] B. Quéguiner,et al. Deep silicon maxima in the stratified oligotrophic Mediterranean Sea , 2010 .
[13] Michele Scardi,et al. Challenges of modeling depth‐integrated marine primary productivity over multiple decades: A case study at BATS and HOT , 2010 .
[14] Walker O. Smith,et al. An evaluation of ocean color model estimates of marine primary productivity in coastal and pelagic regions across the globe , 2010 .
[15] Dariusz Stramski,et al. Phytoplankton class‐specific primary production in the world's oceans: Seasonal and interannual variability from satellite observations , 2010 .
[16] Xiaodong Zhang,et al. Scattering by pure seawater: effect of salinity. , 2009, Optics express.
[17] A. Quirantes,et al. Simulating the optical properties of phytoplankton cells using a two-layered spherical geometry , 2009 .
[18] F. D’Ortenzio,et al. On the trophic regimes of the Mediterranean Sea: a satellite analysis , 2008 .
[19] I. Hense,et al. Beneath the surface: Characteristics of oceanic ecosystems under weak mixing conditions – A theoretical investigation , 2007 .
[20] H. Claustre,et al. Spatial variability of phytoplankton pigment distributions in the Subtropical South Pacific Ocean: comparison between in situ and predicted data , 2007 .
[21] V. Vantrepotte,et al. Vertical variability and diel dynamics of picophytoplankton in the Strait of Sicily, Mediterranean Sea, in summer , 2007 .
[22] Hervé Claustre,et al. Gross community production and metabolic balance in the South Pacific Gyre, using a non intrusive bio-optical method , 2007 .
[23] Jean-François Berthon,et al. Investigation of the optical backscattering to scattering ratio of marine particles in relation to their biogeochemical composition in the eastern English Channel and southern North Sea , 2007 .
[24] Michael J. Behrenfeld,et al. Beam attenuation and chlorophyll concentration as alternative optical indices of phytoplankton biomass , 2006 .
[25] P. Quay,et al. In vitro and in situ gross primary and net community production in the North Pacific Subtropical Gyre using labeled and natural abundance isotopes of dissolved O2 , 2005 .
[26] Dariusz Stramski,et al. The role of seawater constituents in light backscattering in the ocean , 2004 .
[27] E. Boss,et al. The beam attenuation to chlorophyll ratio: an optical index of phytoplankton physiology in the surface ocean? , 2003 .
[28] J. Ronald V. Zaneveld,et al. The effect of bottom substrate on inherent optical properties: Evidence of biogeochemical processes , 2003 .
[29] Marcel Babin,et al. Diel variations in Prochlorococcus optical properties , 2002 .
[30] R. Anadón,et al. Large-scale variability of planktonic net community metabolism in the Atlantic Ocean: importance of temporal changes in oligotrophic subtropical waters , 2002 .
[31] A. Bricaud,et al. Modeling the inherent optical properties of the ocean based on the detailed composition of the planktonic community. , 2001, Applied optics.
[32] R. Anadón,et al. Seasonal compensation of microbial production and respiration in a temperate sea , 1999 .
[33] J. Cloern. The relative importance of light and nutrient limitation of phytoplankton growth: a simple index of coastal ecosystem sensitivity to nutrient enrichment , 1999, Aquatic Ecology.
[34] D. Vaulot,et al. Diel variability of photosynthetic picoplankton in the equatorial Pacific , 1999 .
[35] C. Duarte,et al. The CO2 balance of unproductive aquatic ecosystems , 1998, Science.
[36] John J. Cullen,et al. Biological processes and optical measurements near the sea surface: Some issues relevant to remote sensing , 1995 .
[37] Scott C. Doney,et al. Photochemistry, mixing and diurnal cycles in the upper ocean , 1995 .
[38] G. Magazzù,et al. Primary production, biomass and abundance of phototrophic picoplankton in the Mediterranean Sea: a review , 1995 .
[39] John Marra,et al. Primary production, water column changes, and the demise of a Phaeocystis bloom at the Marine Light-Mixed Layers site (59°N, 21°W) in the northeast Atlantic Ocean , 1995 .
[40] T Platt,et al. Effect of the particle-size distribution on the backscattering ratio in seawater. , 1994, Applied optics.
[41] Hervé Claustre,et al. The trophic status of various oceanic provinces as revealed by phytoplankton pigment signatures , 1994 .
[42] Dariusz Stramski,et al. Diel variations in the optical properties of a marine diatom , 1993 .
[43] T. Dickey,et al. Variability of bio‐optical properties of the upper ocean associated with diel cycles in phytoplankton population , 1992 .
[44] D. Purdie,et al. In vitro and in situ derived rates of gross production, net community production and respiration of oxygen in the oligotrophic subtropical gyre of the North Pacific Ocean , 1991 .
[45] Charles S. Yentsch,et al. A bridge between ocean optics and microbial ecology , 1989 .
[46] John J. Cullen,et al. The deep chlorophyll maximum comparing vertical profiles of chlorophyll a , 1982 .
[47] Catherine Schmechtig,et al. Processing Bio-Argo particle backscattering at the DAC level , 2018 .
[48] Catherine Schmechtig,et al. Processing bio-Argo chlorophyll-A concentration at the DAC level , 2015 .
[49] E. Boss,et al. In Situ Measurement of the Inherent Optical Properties (IOPs) and Potential for Harmful Algal Bloom Detection and Coastal Ecosystem Observations , 2012 .
[50] Michael S. Twardowski,et al. Particulate backscattering ratio at LEO 15 and its use to study particle composition and distribution , 2004 .
[51] Paul G. Falkowski,et al. Primary Productivity and Biogeochemical Cycles in the Sea , 1992 .
[52] Dale A. Kiefer,et al. Light scattering by microorganisms in the open ocean , 1991 .
[53] L. Prieur,et al. Absorption by dissolved organic matter of the sea (yellow substance) in the UV and visible domains1 , 1981 .