The GEOTRACES Arctic Program and Its Scientific Objectives

 
The GEOTRACES Arctic Program
 
Dave Kadko, University of Miami (25.80N)
Bill Landing, Florida State University (30.42N)
Greg Cutter, Old Dominion University (36.83N)
 
AOMIP-FAMOS Workshop, WHOI October 2012
 
ARCTIC GEOTRACES Program
Presentation Outline
:
 
The Science: what is GEOTRACES, why study the Arctic, what
will we measure?
Cruise plan discussion within the international framework.
Timeline: Where we’ve been, where we are, where we’re
headed!
Anticipated Benefits from Arctic GEOTRACES
 
What is GEOTRACES?
 
An international program designed to study
the marine biogeochemical cycles of trace
elements and their isotopes.
 
Its 
Mission
 is:
“To identify processes and quantify fluxes that
control the distributions of key trace elements and
isotopes (TEIs) in the ocean, and to establish the
sensitivity of these distributions to changing
environmental conditions”
 
Need to understand and quantify fluxes at ocean
interfaces and rates and mechanisms of internal
cycling processes.
 
Strategy and Overarching Scientific Goals
 
The Arctic is Unique
 
Extremely vulnerable to climate change.
Plays a major role in global climate, thermohaline circulation,
planetary heat budget, carbon transport.
Only ~ 2% of total ocean volume 
 BUT
………
10% of the global river run-off is delivered to the Arctic
Arctic shelves represent 25% of the global shelf area
30% of the world’s soil carbon stored in northern ecosystems
Warming climate should increase export of
    organic carbon to the Arctic Ocean.
 
Sea Ice: Captures and transports
 
atmospheric deposition of 
TEIs,
 
pollutants, soot.
 
This important geochemical/ecological
 
pathway will change as ice disappears!
 
Objectives for Arctic GEOTRACES:
 Fluxes and Processes at Ocean Interfaces
 
Rates and Mechanisms of Internal Cycling
 Development of Proxies for Paleoceanographic Studies
Essential Micronutrients and trace metal cycling
   Mn, Fe, Co, Ni, Cu, Zn, Cd, other TEIs, REEs, nano-nutrients
Tracers of freshwater sources
   δ
18
O, Ba, Ra isotopes, nutrients, terrestrial DOC
Tracers of particle flux
    234
Th, 
230
Th, 
231
Pa, 
210
Po, 
210
Pb
Tracers for exchange of shelf with open ocean
   Mn, Fe, Al, REE, 
228
Ra, Nd, Hf, Be, DOC (lignin)
Tracers of water mass circulation and mixing
    Pu, 
137
Cs, 
129
I, 
99
Tc, 
227
Ac,
 7
Be
• Atmospheric deposition
      210
Pb, 
7
Be, Hg, Fe, Al, anthropogenic TEIs (As, Se, Pb, Zn)
 
Why have an Arctic GEOTRACES Program Now?
 
Establish “baselines” for TEI distributions and cycling rates in
advance of anticipated rapid change in the Arctic (better late
than never!)
Improved ability to sample the ocean, process and store the
samples without contamination
Non-metallic (plastic) sampling devices – bottles and cables.
Sample storage bottles of non-contaminating plastics.
Clean acids via sub-boiling distillation for sample
preservation.
New analytical tools with low detection limits and high
precision – ASV, TIMS, ICP-MS (sector field, multi-collector)
Rates and fluxes can be derived using advanced modeling
(e.g. inverse methods).
 
 
 
Accuracy and precision for trace elements is comparable to that
for major nutrients
 
Transport pathways (currents, riverine fluxes, atmospheric
deposition) bring contaminants and natural TEIs into the Arctic
 
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and bioactive TEI cycling and to regional and global carbon
flux dynamics (how much, how fast, in what forms, where to?)
 
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(2011).
 
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reduction of MnOx(s)
on shelf followed by
offshore transport.
 
Sea Ice Impacts ocean chemistry and ecology
 
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).
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carbon flux?
 
 
 
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 Bering Strait choke point – measure TEIs in conjunction with
moored array temperature, salinity, water velocity and
transmissivity data (RUSALCA: Univ. Washington, Univ. Alaska,
Arctic and Antarctic Res. Inst., Russia---Rebecca Woodgate et
al.).
      --Fluxes of water and TEIs at this major gateway
 
 Shelf-Basin exchange  – Transport and transformations
   
      –  Boundary scavenging processes
 
 Deep basin transects:
 
--crossing fronts; Atlantic, Pacific, Transpolar Drift.
        
 
-- Sea ice: 
a platform for retaining and transporting TEIs
           -
partitioning of TEIs between different compartments
           (atmosphere, surface water, snow, ice)
 
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Timeline:
o
June 2009: Arctic GEOTRACES workshop in Delmenhorst.
o
June 2011: NSF-OPP and CO agree to co-fund US Arctic
GEOTRACES proposals.
o
January 2012 -- Ship time request for the Healy (Kadko,
Landing, Cutter, Anderson)
o
June 13-15, 2012 -- Arctic Planning workshop—formulate
science plan (continued coordination with international
partners) – NSF HQ.
o
October 15, 2012 -- Management proposal submitted (Kadko,
Landing, Cutter).
o
Summer 2013  -- Management proposal awarded (?).
o
Feb 2014  --  PI science proposals.
o
Winter 2014 -2015.  PI cruise-planning meeting.
o
Aug – Sept 2015:  Research Cruise.
o
Fall 2016 (AGU?): Post-cruise data workshop
 
What are the anticipated benefits?
 
They include:
 
1)
Identify sources and sinks and quantify internal cycling of
essential micronutrients and other TEIs (e.g., Mn, Fe, Co,
Ni, Cu, Zn, Cd).
2)
Calibrate geochemical tracers used to reconstruct past
ocean conditions (e.g., circulation, chemistry, biological
productivity, carbon fluxes) for more reliable applications.
3)
Improve predictions of the cycling and fate of natural and
contaminant TEIs.
4)
Apply knowledge to predicting trajectory and impacts of
“change” in the Arctic.
 
 
www.geotraces.org
 
ipo@geotraces.org
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The GEOTRACES Arctic Program aims to study marine biogeochemical cycles in the Arctic region, focusing on trace elements and isotopes. Through international collaboration, the program identifies processes affecting the distribution of key elements in the ocean. The unique Arctic environment, vulnerable to climate change, plays a crucial role in global systems like climate and carbon transport. Objectives include studying ocean interfaces, internal cycling, micronutrients, freshwater sources, and atmospheric deposition. Understanding these processes is essential for climate research and ocean health.

  • GEOTRACES
  • Arctic Program
  • marine biogeochemistry
  • climate change
  • ocean research

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  1. The GEOTRACES Arctic Program Dave Kadko, University of Miami (25.80N) Bill Landing, Florida State University (30.42N) Greg Cutter, Old Dominion University (36.83N) AOMIP-FAMOS Workshop, WHOI October 2012

  2. ARCTIC GEOTRACES Program Presentation Outline: The Science: what is GEOTRACES, why study the Arctic, what will we measure? Cruise plan discussion within the international framework. Timeline: Where we ve been, where we are, where we re headed! Anticipated Benefits from Arctic GEOTRACES

  3. What is GEOTRACES? An international program designed to study the marine biogeochemical cycles of trace elements and their isotopes. Its Mission is: To identify processes and quantify fluxes that control the distributions of key trace elements and isotopes (TEIs) in the ocean, and to establish the sensitivity of these distributions to changing environmental conditions

  4. Strategy and Overarching Scientific Goals Need to understand and quantify fluxes at ocean interfaces and rates and mechanisms of internal cycling processes.

  5. The Arctic is Unique Extremely vulnerable to climate change. Plays a major role in global climate, thermohaline circulation, planetary heat budget, carbon transport. Only ~ 2% of total ocean volume BUT 10% of the global river run-off is delivered to the Arctic Arctic shelves represent 25% of the global shelf area 30% of the world s soil carbon stored in northern ecosystems Warming climate should increase export of organic carbon to the Arctic Ocean. Sea Ice: Captures and transports atmospheric deposition of TEIs, pollutants, soot. This important geochemical/ecological pathway will change as ice disappears!

  6. Objectives for Arctic GEOTRACES: Fluxes and Processes at Ocean Interfaces Rates and Mechanisms of Internal Cycling Development of Proxies for Paleoceanographic Studies Essential Micronutrients and trace metal cycling Mn, Fe, Co, Ni, Cu, Zn, Cd, other TEIs, REEs, nano-nutrients Tracers of freshwater sources 18O, Ba, Ra isotopes, nutrients, terrestrial DOC Tracers of particle flux 234Th, 230Th, 231Pa, 210Po, 210Pb Tracers for exchange of shelf with open ocean Mn, Fe, Al, REE, 228Ra, Nd, Hf, Be, DOC (lignin) Tracers of water mass circulation and mixing Pu, 137Cs, 129I, 99Tc, 227Ac, 7Be Atmospheric deposition 210Pb, 7Be, Hg, Fe, Al, anthropogenic TEIs (As, Se, Pb, Zn)

  7. Why have an Arctic GEOTRACES Program Now? Establish baselines for TEI distributions and cycling rates in advance of anticipated rapid change in the Arctic (better late than never!) Improved ability to sample the ocean, process and store the samples without contamination Non-metallic (plastic) sampling devices bottles and cables. Sample storage bottles of non-contaminating plastics. Clean acids via sub-boiling distillation for sample preservation. New analytical tools with low detection limits and high precision ASV, TIMS, ICP-MS (sector field, multi-collector) Rates and fluxes can be derived using advanced modeling (e.g. inverse methods).

  8. Accuracy and precision for trace elements is comparable to that for major nutrients Zn (nmol kg-1) Al (nmol kg-1) 0 2 4 6 8 10 0 10 20 30 40 0 0 500 1000 1000 Carousel - Osmonics TITAN - 2010 Carousel - Nuclepore 1500 Depth (m) Depth (m) 2000 2000 2500 3000 3000 3500 4000 UAF Vane Carousel Average 4000

  9. Transport pathways (currents, riverine fluxes, atmospheric deposition) bring contaminants and natural TEIs into the Arctic

  10. Sampling: o Water column (dissolved TEIs, nutrients, hydrography) o Suspended particles o Sea ice + dirty ice ; melt ponds, ice-edge, under ice sampling; ice algae o Aerosols o Precipitation o Surface sediments

  11. SHELF PROCESSES Physical, biogeochemical, and biological fluxes interact; impact on Arctic ecosystems (e.g. heat, fresh water, nutrients, carbon, TEI tracers) Biologically-mediated redox processes are critical to carbon and bioactive TEI cycling and to regional and global carbon flux dynamics (how much, how fast, in what forms, where to?) Macdonald and Gobeil (2011). Nearly quantitative reduction of MnOx(s) on shelf followed by offshore transport.

  12. Sea Ice Impacts ocean chemistry and ecology o Sea-ice receives and transports atmospherically deposited material (e.g. Hg, Pb, As, Se, Cd, Zn, soot, natural aerosols). o Strongly influences gas exchange (e.g. CO2). o Ice-algae: cycle nutrients and bio-active TEIs; serve as a food source for Arctic food webs.

  13. also ....... What about sediment-laden (dirty) Sea Ice >100,000 km2 of sediment-laden sea ice (5-8 x 106 t particulate export) Enhanced rafting due to changing sea- ice regime? Source of TEIs to Arctic interior Impact on ice primary production and carbon flux? Multiple rafting with sediment layers in lower sections Changes in sea-ice coverage/timing will affect the distribution and partitioning of TEIs within the ocean and the nature of important ocean processes: gas-exchange biological productivity sedimentation, removal of contaminants

  14. There are even hydrothermal vents! The ultra-slow spreading Gakkel Ridge. POLARSTERN, 2007 IPY (Rob Middag; Hein de Baar) How do these fluxes impact the Arctic? How will we model these tracer fields?

  15. Planning for an international Arctic GEOTRACES initiative is logistically complex. Four nations (Sweden, Canada, Germany and the U.S.) have active GEOTRACES programs that will pursue the use of a national icebreaker. In addition, GEOTRACES scientists from other nations (e.g., The Netherlands, U.K., France and Spain) are interested in participating. The desired objective is to mount a 4-ship operation in 2015 (US, Canada, Germany, Sweden) to support the collaborative research of investigators from all nations. USCG HEALY and Canadian Coast Guard Cutter LOUIS S. ST. LAURENT working together (2010). GEOTRACES Arctic workshop in Moscow Nov. 26-30, 2012

  16. NOAA/RUSALCA K K US McK McK L L AR T D AR T Y Y Sw O O Russia CA UK

  17. GOALS US Arctic GEOTRACES Bering Strait choke point measure TEIs in conjunction with moored array temperature, salinity, water velocity and transmissivity data (RUSALCA: Univ. Washington, Univ. Alaska, Arctic and Antarctic Res. Inst., Russia---Rebecca Woodgate et al.). --Fluxes of water and TEIs at this major gateway Shelf-Basin exchange Transport and transformations Boundary scavenging processes Deep basin transects: --crossing fronts; Atlantic, Pacific, Transpolar Drift. -- Sea ice: a platform for retaining and transporting TEIs -partitioning of TEIs between different compartments (atmosphere, surface water, snow, ice)

  18. Figure 2. Anticipated track for the US Arctic GEOTRACES cruise in 2015. The outbound, northward leg would be extended if the German expedition does not occur. The number of stations along the deep-basin transects will be adjusted as needed to account for sea and iceconditions.

  19. Timeline: o June 2009: Arctic GEOTRACES workshop in Delmenhorst. o June 2011: NSF-OPP and CO agree to co-fund US Arctic GEOTRACES proposals. o January 2012 -- Ship time request for the Healy (Kadko, Landing, Cutter, Anderson) o June 13-15, 2012 -- Arctic Planning workshop formulate science plan (continued coordination with international partners) NSF HQ. o October 15, 2012 -- Management proposal submitted (Kadko, Landing, Cutter). o Summer 2013 -- Management proposal awarded (?). o Feb 2014 -- PI science proposals. o Winter 2014 -2015. PI cruise-planning meeting. o Aug Sept 2015: Research Cruise. o Fall 2016 (AGU?): Post-cruise data workshop

  20. What are the anticipated benefits? They include: 1) Identify sources and sinks and quantify internal cycling of essential micronutrients and other TEIs (e.g., Mn, Fe, Co, Ni, Cu, Zn, Cd). 2) Calibrate geochemical tracers used to reconstruct past ocean conditions (e.g., circulation, chemistry, biological productivity, carbon fluxes) for more reliable applications. 3) Improve predictions of the cycling and fate of natural and contaminant TEIs. 4) Apply knowledge to predicting trajectory and impacts of change in the Arctic.

  21. www.geotraces.org ipo@geotraces.org

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