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Department of Marine and Coastal Sciences

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1 Department of Marine and Coastal Sciences
Phytoplankton dynamics in submarine canyons in the West Antarctic Peninsula Filipa Carvalho Committee: Josh Kohut (adviser) Oscar Schofield (adviser) Maxim Gorbunov Matthew Oliver (U. Delaware) Thesis Proposal Defense Department of Marine and Coastal Sciences December 5th, 2014

2 Introduction Mean Winter Temperature is Increasing in the West Antarctic Peninsula (WAP) 86-day shorter Ice season Palmer Station Slope = 1.15°C/decade -0.2 0.2 Temperature trends (°C/ year) NASA/Goddard Space Flight Center Scientific Visualization Studio. Data provided by Larry Stock Data Source: Palmer Station Weather

3 Introduction Ice Season Duration is Decreasing in the West Antarctic Peninsula (WAP) 86-day shorter Ice season Palmer Station Slope = °C/decade -0.2 0.2 Temperature trends (°C/ year) Plus, 87% of the glaciers are in retreat NASA/Goddard Space Flight Center Scientific Visualization Studio. Data provided by Larry Stock Data Source: Palmer Station Weather

4 ACC transports the water masses responsible for warming the WAP
Introduction ACC transports the water masses responsible for warming the WAP Antarctic Circumpolar Current Weddell gyre Bellingshausen Sea Amundsen Sea ASE Ross gyre WAP: West Antarctic Peninsula ACC: Antarctic Circumpolar Current ACC based on climatological dynamic topography of Orsi et al., DSR, 1995

5 Increase of Heat content on the shelf
Introduction Increase of Heat content on the shelf due to Deep Water Intrusion

6 WAP Canyons are “Biological Hotspots”
Introduction WAP Canyons are “Biological Hotspots” Penguin Colonies at costal termini of cross-shelf canyons/troughs Predictable /elevated food availability; Enhanced production in canyon heads; Eveleth et al., In Prep. 

7 Introduction Main Questions What physical mechanisms responsible phytoplankton spring bloom initiation in the WAP canyons? Canyon dynamics affect phytoplankton dynamics? Light or nutrient availability - Which one is the main control of bloom initiation? Is Mixed Layer Depth (MLD) important? Physiological responses to canyon dynamics?

8 Thesis Structure Phytoplankton Dynamics
Introduction Thesis Structure Physical Dynamics (MLD) Bloom Initiation (Light vs. Nutrients) Physiological Responses (Fv/Fm) Chapter 1: Physical Dynamics of Palmer Deep Canyon, WAP Chapter 2: The role of light availability and nutrient delivery in controlling the spring phytoplankton bloom in canyons in the West Antarctic Peninsula Chapter 3: Physiology and Primary Production at Palmer Deep Canyon, WAP Phytoplankton Dynamics in submarine canyons in the WAP

9 Thesis Structure Phytoplankton Dynamics
Introduction Physical Dynamics Thesis Structure Physical Dynamics (MLD) Bloom Initiation (Light vs. Nutrients) Physiological Responses (Fv/Fm) Chapter 1: Physical Dynamics of Palmer Deep Canyon, WAP Chapter 2: The role of light availability and nutrient delivery in controlling the spring phytoplankton bloom in canyons in the West Antarctic Peninsula Chapter 3: Physiology and Primary Production at Palmer Deep Canyon, WAP Phytoplankton Dynamics in submarine canyons in the WAP

10 Increased Productivity Correlated with UCDW Intrusion
Introduction Physical Dynamics Increased Productivity Correlated with UCDW Intrusion Olbers & Visbeck, 2005 UCDW: Upper Circumpolar Deep Water – warmer (~ 1.8°C), low oxygen AASW: Antarctic Surface Water – colder, lower salinity

11 Water Masses at Palmer Deep Canyon
Introduction Physical Dynamics Water Masses at Palmer Deep Canyon Pure UCDW WW AASW UCDW: Upper Circumpolar Deep Water AASW: Antarctic Surface Water WW: Winter Water

12 Science Questions Location of the bloom?
Introduction Physical Dynamics Science Questions Location of the bloom? Do high productivity areas show similar physical properties of the water column as low productivity ones? Key water column physical properties lead to blooms? MLD and bathymetry relate to phytoplankton abundance? Remote forcing relate to favorable water column characteristics associated with increased productivity?

13 Datasets Glider CODAR Mooring Ship Data Weather Remote Sensing
Introduction Physical Dynamics Datasets Glider CODAR Mooring Ship Data Weather Remote Sensing

14 Buoyancy Frequency (N2)
Introduction Physical Dynamics Mixed Layer Depth (MLD). Buoyancy Frequency (N2)

15 Water Column Properties vs. MLD
Introduction Physical Dynamics Water Column Properties vs. MLD

16 Other Important Variables
Introduction Physical Dynamics Other Important Variables Tmin – Temperature minima in each profile Depth Tmin – Depth of Tmin Δσt Tmin-0 Martinson & Iannuzi, 1998; Saba et al, 2014 Stratification Location of winter Water (or remnants)

17 Palmer Deep Canyon 22 Km 10 Km Physical Dynamics Introduction
Palmer Station 22 Km 10 Km

18 Binning Data using Bathymetry & Distance to Shore
Introduction Physical Dynamics Binning Data using Bathymetry & Distance to Shore Distance to Shore Bathymetry

19 Binning Data using Bathymetry & Distance to Shore
Introduction Physical Dynamics Binning Data using Bathymetry & Distance to Shore Palmer Station Shallow Slope Deep

20 Binning Data using Bathymetry & Distance to Shore
Introduction Physical Dynamics Binning Data using Bathymetry & Distance to Shore Offshore Central Nearshore Palmer Station Shallow Slope Deep

21 Good Coverage at Head of Canyon
Introduction Physical Dynamics Good Coverage at Head of Canyon Palmer Deep Gliders + Offshore Central Nearshore Palmer Station Shallow Slope Deep

22 Good Coverage at Head of Canyon
Introduction Physical Dynamics Good Coverage at Head of Canyon Palmer Deep Gliders + (NEARSHORE REGION) Offshore Central Nearshore Palmer Station Shallow Slope Deep

23 Annual & Seasonal Variability in Tmin
Introduction Physical Dynamics Tmin increases throughout Season Season Season Annual & Seasonal Variability in Tmin Season: no change in Tmin – late ice retreat?

24 Tmin increases throughout Season
Introduction Physical Dynamics Tmin increases throughout Season Season Season Season: no change in Tmin – late ice retreat?

25 Tmin Colder on the Slope
Introduction Physical Dynamics Tmin Colder on the Slope Season Tmin peaks colder on Slope < Deep < Shallow regions Season: colder in all regions Winter water (T<- 1°C) present on the slope Season

26 Depth Tmin decreases throughout Season
Introduction Physical Dynamics Depth Tmin decreases throughout Season Season Season Season: smaller decrease in depth in Tmin - late ice retreat?

27 Different Water Masses In different parts of the Canyon
Introduction Physical Dynamics Different Water Masses In different parts of the Canyon Palmer Station

28 Adjusting the Grid Introduction Physical Dynamics Offshore Central
Nearshore Shallow Slope Deep

29 Adjusting the Grid Introduction Physical Dynamics North Offshore
Central Nearshore South Shallow Slope Deep

30 Main Points for Physical Analysis
Introduction Physical Dynamics Bloom Initiation Main Points for Physical Analysis Good coverage of the Canyon Can evaluate annual/seasonal trends Analysis with classical + local specific MLD Correlations between wind and ice retreat with MLD and Productivity

31 Thesis Structure Phytoplankton Dynamics
Introduction Physical Dynamics Bloom Initiation Thesis Structure Physical Dynamics (MLD) Bloom Initiation (Light vs. Nutrients) Physiological Responses (Fv/Fm) Chapter 1: Physical Dynamics of Palmer Deep Canyon, WAP Chapter 2: The role of light availability and nutrient delivery in controlling the spring phytoplankton bloom in canyons in the West Antarctic Peninsula Chapter 3: Physiology and Primary Production at Palmer Deep Canyon, WAP Phytoplankton Dynamics in submarine canyons in the WAP

32 Integrated Biomass Gain (Production)
Introduction Physical Dynamics Bloom Initiation Bloom Initiation when MLD shallower that critical depth (Critical Depth Hypothesis) Critical Depth when: Integrated Biomass Gain (Production) = Integrated Biomass Loss Critical Depth Sverdrup, 1953

33 Introduction Physical Dynamics Bloom Initiation Primary Production explained by shoaling of MLD due to Fresh Water and Winds Ice cover Chlorophyll a Mixed Layer Depth Fresh Water Lens Moline et al., 1996

34 Introduction Physical Dynamics Bloom Initiation Primary Production explained by shoaling of MLD due to Fresh Water and Winds Ice cover Fucoxanthin (diatoms) Mixed Layer Depth Fresh Water Lens Moline et al., 1996

35 Introduction Physical Dynamics Bloom Initiation Macronutrients are abundant before bloom initiation & never completely drawdown Nitrate Silicate Ducklow et al., 2007

36 Proposed Research The main control of the bloom initiation is the:
Introduction Physical Dynamics Bloom Initiation Proposed Research The main control of the bloom initiation is the: H1: upwelling of nutrients from the Upper Circumpolar Deep Water (UCDW); H2: shoaling of the mixed layer depth, increasing, this way, the light availability to the phytoplankton community.

37 Mesocosms Incubations
Introduction Physical Dynamics Bloom Initiation Mesocosms Incubations Stratification (light) Pure UCDW WW AASW VS. Upwelling (nutrients)

38 Mesocosms Incubations
Introduction Physical Dynamics Bloom Initiation Mesocosms Incubations Stratification (light) Surface Water Deep Water mUCDW VS. Upwelling (nutrients)

39 Setting up the Incubation Experiments
Introduction Physical Dynamics Bloom Initiation Setting up the Incubation Experiments

40 Chlorophyll Driven by Light (color)
Introduction Physical Dynamics Bloom Initiation Chlorophyll Driven by Light (color)

41 Proposed analysis Phytoplankton Biomass (Chlorophyll)
Introduction Physical Dynamics Bloom Initiation Proposed analysis Phytoplankton Biomass (Chlorophyll) Primary Production (C14 method) Pigments (HPLC) Nutrients Community Composition (HPLC, Flowcytometry)

42 Iron Seems Abundant in Shelf Regions in the WAP
Introduction Physical Dynamics Bloom Initiation Iron Seems Abundant in Shelf Regions in the WAP South America Drake Passage Gerlache Strait Antarctica Gerlache Strait Drake Passage Martin et al., 1990

43 What about Iron? Incubations in a trace metal clean environment
Introduction Physical Dynamics Bloom Initiation What about Iron? Incubations in a trace metal clean environment Iron enrichment experiments Photos courtesy of : Jess Fitzsimmons

44 Thesis Structure Phytoplankton Dynamics
Introduction Physical Dynamics Bloom Initiation Physiological Responses Thesis Structure Physical Dynamics (MLD) Bloom Initiation (Light vs. Nutrients) Physiological Responses (Fv/Fm) Chapter 1: Physical Dynamics of Palmer Deep Canyon, WAP Chapter 2: The role of light availability and nutrient delivery in controlling the spring phytoplankton bloom in canyons in the West Antarctic Peninsula Chapter 3: Physiology and Primary Production at Palmer Deep Canyon, WAP Phytoplankton Dynamics in submarine canyons in the WAP

45 Physiological Responses
Introduction Physical Dynamics Bloom Initiation Physiological Responses Photosynthesis Fluorescence

46 Physiological Responses
Introduction Physical Dynamics Bloom Initiation Physiological Responses Evaluating Environmental Stresses Using Quantum Yield of Photosynthesis Iluz & Dubinsky, 2013

47 Introduction Physical Dynamics Bloom Initiation Physiological Responses Daytime decreases Photosynthetic Efficiency (non-Photochemical quenching) Night Daytime Night Night Daytime Night Biomass Proxy (Fm) Quantum Yield of Photosynthesis (Fv/Fm)

48 Photoacclimation observed in Pigments
Introduction Physical Dynamics Bloom Initiation Physiological Responses Photoacclimation observed in Pigments Low photosynthetic pigments) Light Intensity photoprotective (non-photosynthetic) pigments High change in the chlorophyll/astaxanthin ratio In diatoms , the ratio is diadinoxanthin/diatoxanthin Dubinsky & Schofield, 2009

49 Physiological Responses
Introduction Physical Dynamics Bloom Initiation Physiological Responses Science Questions Nutrient/Light impact Physiology? Key physiological characteristics and limiting factors? Canyon dynamics drive physiological changes? Variability of Nonphotochemical Quenching (NPQ) with MLD

50 Fluorescence Induction and Relaxation Sensor (FIRe)
Introduction Physical Dynamics Bloom Initiation Physiological Responses Fluorescence Induction and Relaxation Sensor (FIRe) Iluz & Dubinsky, 2013

51 “Healthy” Phytoplankton have higher Fv/Fm
Introduction Physical Dynamics Bloom Initiation Physiological Responses “Healthy” Phytoplankton have higher Fv/Fm Increasing Fv/Fm

52 FIRe Glider Data Correction - Fm
Introduction Physical Dynamics Bloom Initiation Physiological Responses FIRe Glider Data Correction - Fm Before correction After correction Fm - proxy for phytoplankton biomass (relative units) Need in situ water collection and chl measurements through fluorometric method

53 Evaluating Total Nonphotochemical Quenching (NPQ)
Introduction Physical Dynamics Bloom Initiation Physiological Responses Evaluating Total Nonphotochemical Quenching (NPQ)

54 Looking at NPQ due to Photoinhibition
Introduction Physical Dynamics Bloom Initiation Physiological Responses Looking at NPQ due to Photoinhibition Initial Sample Dark bottle Dim light bottle ~1h

55 Looking at NPQ due to Photoinhibition
Introduction Physical Dynamics Bloom Initiation Physiological Responses Looking at NPQ due to Photoinhibition Initial Sample Dark bottle Dim light bottle ~1h

56 FIRe in an Upwelling Event: Light is the Main Driver of the Bloom
Introduction Physical Dynamics Bloom Initiation Physiological Responses FIRe in an Upwelling Event: Light is the Main Driver of the Bloom Upwelling Photosynthetic Efficiency (Fv/Fm) fairly constant & high Points=observations (no interpolations)

57 FIRe in an Upwelling Event: Light is the Main Driver of the Bloom
Introduction Physical Dynamics Bloom Initiation Physiological Responses FIRe in an Upwelling Event: Light is the Main Driver of the Bloom Fv/Fm inversely mirrors PAR data Upwelling Points=observations (no interpolations)

58 FIRe in an Upwelling Event: Light is the Main Driver of the Bloom
Introduction Physical Dynamics Bloom Initiation Physiological Responses FIRe in an Upwelling Event: Light is the Main Driver of the Bloom Upwelling Fm decreases – Due to mixing? Deepening of the MLD? Points=observations (no interpolations)

59 Fraction of Chronically damaged Reaction Centers
Introduction Physical Dynamics Bloom Initiation Physiological Responses Fraction of Chronically damaged Reaction Centers Able to recover overnight Not able to recover overnight Gorbunov et at., 2001

60 Evaluating NPQ using Diel Cycles
Introduction Physical Dynamics Bloom Initiation Physiological Responses Evaluating NPQ using Diel Cycles “dark adapted” and in relaxed state Photoinhibited Runcie & Riddle, 2011

61 Physiological Responses
Introduction Physical Dynamics Primary Production Physiological Responses Final Remarks Primary Productivity in Submarine Canyons Phytoplankton Dynamics Physics Physiology

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