Seasonal to Interannual Variability in Phytoplankton Biomass and Diversity on the New England Shelf Heidi M. Sosik Hui Feng In Situ Time Series for Validation.

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Seasonal to Interannual Variability in Phytoplankton Biomass and Diversity on the New England Shelf Heidi M. Sosik Hui Feng In Situ Time Series for Validation and Exploration of Remote Sensing Algorithms Woods Hole Oceanographic Institution University of New Hampshire

Project Overview Goal: Use unique time series to evaluate algorithms that extend MODIS ocean color data beyond chlorophyll to functional type or size-class- dependent phytoplankton retrievals Approach: End-to-end time series observations, with step-by-step algorithm evaluation and error analysis single cells  phytoplankton community  bulk water optical properties  sea surface optical properties (air and water)  MODIS optical properties Martha’s Vineyard Coastal Observatory Tower mounted AERONET-OC MODIS products Submersible Imaging Flow Cytometry

Talk Overview Phytoplankton Observations Single cells to communities Biomass, size- and taxon-resolved Phytoplankton Algorithms Absorption spectral shape  size structure Diagnostic pigments  size structure Next Steps

FlowCytobot Imaging FlowCytobot Observing Phytoplankton at MVCO Martha’s Vineyard Coastal Observatory (MVCO) Cabled site with power and two-way communications MicroplanktonPicoplankton Laser-based flow cytometry Fluorescence and light scattering Flow cytometry with video imaging Automated features for extended deployment (>6 months) Enumeration, identification, and cell sizing Thousands of individual cells every hour Olson et al Olson & Sosik 2007

Single Cells to Biomass FlowCytobot Picoplankton Imaging FlowCytobot Microplankton Light scattering Cell volume (  m 3 ) Sosik and Olson 2007 Moberg & Sosik 2012 Olson et al Volume from laser scattering Volume from image analysis new “distance map” approach Menden-Deuer and Lessard 2000

Individual cells  Taxa  Communities Individual cells  Size-classes  Communities Syn Single Cells to Communities

Phytoplankton Algorithms Spectral absorption shape  size structure Ciotti et al Ciotti and Bricaud 2006

FCM C-budget Phytoplankton Algorithms Spectral absorption shape  size structure Ciotti et al Ciotti and Bricaud 2006

Phytoplankton Algorithms Diagnostic pigments  size structure Vidussi et al Uitz et al Hirata et al Devred et al Fraction micro = ( P 1,w + P 2,w ) / ∑P i,w Fraction nano = ( P 3,w + P 4,w + P 5,w ) / ∑P i,w Fraction pico = ( P 6,w + P 7,w ) / ∑P i,w P 1 = fucoxanthin P 2 = peridinin … Microphytoplankton

Phytoplankton Algorithms Diagnostic pigments  size structure P 1 = fucoxanthin P 2 = peridinin … Picophytoplankton Fraction micro = ( P 1,w + P 2,w ) / ∑P i,w Fraction nano = ( P 3,w + P 4,w + P 5,w ) / ∑P i,w Fraction pico = ( P 6,w + P 7,w ) / ∑P i,w Vidussi et al Uitz et al Hirata et al Devred et al. 2011

Work in Progress and Next Steps Water-leaving radiance and aerosol property retrievals AERONET-OC vs. MODIS Inherent optical property retrievals AERONET-OC vs. in situ samples Diagnostic pigment retrievals AERONET-OC vs. in situ samples Phytoplankton carbon retrievals MODIS vs. cell-based C budgets Diagnostic pigment algorithm evaluation HPLC-CHEMTAX vs. cell-based C budgets Quantification of biases and uncertainties

Phytoplankton Algorithms Diagnostic pigments  size structure Vidussi et al Uitz et al Devred et al Hirata et al P 1 = fucoxanthin P 2 = peridinin … Nanophytoplankton Fraction micro = ( P 1,w + P 2,w ) / ∑P i,w Fraction nano = ( P 3,w + P 4,w + P 5,w ) / ∑P i,w Fraction pico = ( P 6,w + P 7,w ) / ∑P i,w

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