Author Archive for mmaheigan

A new approach for calculating chemical speciation in aquatic systems

Posted by mmaheigan 
· Thursday, August 22nd, 2019 

By Simon Clegg and Matthew Humphreys (UEA)

Members of a funded NERC/NSF project A Thermodynamic Chemical Speciation Model for the Oceans, Seas, and Estuaries are working to develop new tools for the calculation of chemical speciation in seawater and other natural waters. After seeking feedback from the oceanographic community via a Town Hall at the 2016 Ocean Sciences Meeting and an online survey, Matthew Humphreys and Simon Clegg at the University of East Anglia (UK) are developing a draft software package that will be able to:

  • Adjust the stability constants for the ocean carbonate system for deviations of water composition from seawater stoichiometry
  • Make similar adjustments for composition effects on pH, and on the buffer used to define the total pH scale
  • Quantify the effects of the ionic components of natural waters on equilibrium constants and pH and subsequently identify those chemical systems for which new measurements are needed in order to improve the accuracy of predictions

Calculations for Tris pH buffer in S = 35 artificial seawater, showing that the largest contribution to the total uncertainty in pHT (±0.007, calculated using a speciation model) is from the thermodynamic equilibrium constant for bisulfate (HSO4-) dissociation. This is followed by the influence of Cl- on H+ ions (HCl), and on TrisH+ ions (TrisHCl). The uncertainty contributions of the TrisH+ equilibrium constant, and Na+ interactions on SO42- are both small.

This work is part of a larger effort by members of Scientific Committee on Oceanic Research (SCOR) Working Group 145 to inform and facilitate the development of chemical speciation models that quantify uncertainties and are applicable across a broader range of natural waters.

Participants of this project and SCOR Working Group 145 (Matthew Humphries, Simon Clegg, David Turner, Andrew Dickson, Heather Benway) will attend the 2020 Ocean Sciences Meeting in San Diego and provide several opportunities to share new scientific results on chemical speciation and showcase the new speciation model. You can learn more as follows:

  • View presentations of our methods and initial results in session CT003 – Chemical Speciation and Biogeochemistry in a Changing Ocean (abstracts due Sept. 11)
  • Participate in a hands-on demonstration of our draft tools for speciation calculations at a special workshop side event (more details will be provided via the OCB, SCOR, and GEOTRACES email lists/websites)
  • Visit the SCOR exhibit booth (booth 341 in the exhibit hall) to chat and work one-on-one with the speciation model on a dedicated PC

Upwelling and solubility drive global surface dissolved inorganic carbon (DIC) distribution

Posted by mmaheigan 
· Tuesday, August 20th, 2019 

What drives the latitudinal gradient in open-ocean surface DIC concentration? Understanding the processes that drive the distribution of carbon in the surface ocean is essential to the study of the ocean carbon cycle and future predictions of ocean acidification and the ocean carbon sink.

Authors of a recent study in Biogeosciences investigated causes of the observed latitudinal trend in DIC and salinity-normalized DIC (nDIC) (Figure 1). The latitudinal trend in nDIC is not driven solely by the latitudinal gradient in temperature (through its effects on solubility), as is commonly assumed. Careful analysis using the Global Ocean Data Analysis Project version 2 (GLODAPv2) database revealed that physical supply from below (upwelling, entrainment in winter) at high latitudes is another major driver of the latitudinal pattern. The contribution of physical exchange explains an otherwise puzzling observation: Surface waters are lower in nDIC in the high-latitude North Atlantic than in other basins. This cannot be accounted for by temperature difference but rather is explained by a difference in the carbon content of deeper waters (lower in the subarctic North Atlantic than in the subarctic North Pacific or Southern Ocean) that are mixed up into the surface during winter months.

Figure caption: (Top) spatial distributions of surface ocean DIC and (bottom) salinity-normalised (nDIC). Both, most notably nDIC, increase towards the poles. Values are normalised to year 2005 to remove bias from changing levels of atmospheric CO2 in some observations before and after 2005. Data are from GLODAPv2.

These results also suggest that the upwelling/entrainment of water that is high in alkalinity generates a large and long-lasting effect on DIC, one that persists beyond the timescale of CO2 gas exchange equilibration with the . That is to say, the impact of changes in upwelling on the ocean’s carbon source-sink strength depends not only on the DIC content of the upwelled water but also on its TA content.

Authors:
Yingxu Wu (University of Southampton)
Mathis Hain (University of California, Santa Cruz)
Matthew Humphreys (University of East Anglia and University of Southampton)
Sue Hartman (National Oceanography Centre, Southampton)
Toby Tyrrell (University of Southampton)

Air-sea gas exchange estimates biased by multi-day surface trapping

Posted by mmaheigan 
· Tuesday, August 20th, 2019 

Routine measurements of air-sea gas exchange assume a homogeneous gas concentration across the upper few meters of the ocean. But is this assumption valid? A recent study in Biogeosciences revealed substantial systematic gradients of nitrous oxide (N2O) in the top few meters of the Peruvian upwelling regime. These gradients lead to a 30% overestimate of integrated N2O emissions across the entire region, with local emissions overestimated by as much as 800%.

Figure caption: Air-sea gas exchange estimates can be biased by gas concentration gradients within the upper few meters of the ocean; in particular, surface trapping over several days’ duration can generate substantial gradients.

The N2O gradients off Peru form during multi-day events of surface trapping, in which near-surface stratification dampens turbulent mixing. Until now, surface trapping was assumed to be a diurnal (driven by solar warming) process without memory, whereby only weak gradients would form during the hours of trapping and then dissipate. It is likely that multi-day surface trapping occurs in other ocean regions as well. The total impact on emission estimates of different greenhouse gases is yet to be quantified, but given the findings in the Peruvian upwelling system, could be significant globally.

Authors:
Tim Fischer, Annette Kock, Damian L. Arévalo-Martínez, Marcus Dengler, Peter Brandt, Hermann W. Bange (GEOMAR)

SSC nominations are open!

Posted by mmaheigan 
· Thursday, August 15th, 2019 

OCB is seeking nominations for new Scientific Steering Committee (SSC) members, including a new early career SSC member. To qualify for the early career slot, a nominee must have completed a PhD within the last 4 years; both postdoctoral researchers and faculty members are eligible. For the early career nominees who are currently postdocs, a letter of support from the nominee’s postdoctoral advisor is required in addition to the other information listed below.

The following SSC members are scheduled to rotate off at the end of 2019:

  • Jessica Cross (NOAA/PMEL) – Arctic biogeochemistry, ocean acidification, inorganic carbon system
  • Bethany Jenkins (URI) – marine microbial genetics and implications for biogeochemical processes in marine ecosystems
  • Uta Passow (Memorial Univ.) – biological pump, particle dynamics
  • Alyson Santoro (Univ. California, Santa Barbara) – microbes, nitrogen cycle, molecular (-omics) techniques
  • Benjamin Twining (Bigelow) – interactions between plankton and trace metals

In addition to the expertise of those members who are rotating off, we are seeking nominations of candidates

  1. who study the ocean carbon cycle on longer time scales, using paleo-proxies and models to explore past changes in the ocean carbon cycle and associated marine ecological changes; and
  2. who study the interplay between ocean physics, biogeochemistry, and marine organisms to understand key processes involved in ocean carbon uptake and cycling across a range of time and space scales.

If you wish to nominate someone, please submit your nomination to the OCB Project Office by November 15, 2019 with the following information about your nominee:

  1. Name, affiliation, and email address
  2. Expertise as it pertains to OCB
  3. Abbreviated CV (2-page limit – NSF biosketch format is ideal)
  4. A few words speaking to the nominee’s capacity to contribute to OCB leadership, science planning, and implementation

Self-nominations are welcome! OCB SSC members serve a term of 3 years. For more information on the OCB SSC, including a list of current and previous SSC members, the SSC charge and terms of reference, and links to the past year of SSC minutes, please visit the SSC page of the OCB website.

BIARRITZ workshop report

Posted by mmaheigan 
· Monday, August 12th, 2019 

This workshop took place at the National Oceanography Centre, in Southampton, UK from 22-26 July, bringing together 75 researchers from 8 countries. The aim of the BIARRITZ (Bridging International Activity and Related Research Into the Twilight Zone) project is to act as a forum for the growing number of projects investigating the functioning of the ocean’s Twilight Zone (TZ), straddling the depth range from ~100m-1000m.

The workshop was to allow projects at varying stages (from all fieldwork done to still seeking funding) to discuss common issues, to identify major gaps in the field and to identify practical ways in which they can collaborate or assist each other. The NASA EXPORTS program and the WHOI Ocean Twilight Zone project were both well-represented, as well as nine other projects funded by the UK, Australia, Spain, Germany, France and EU. The workshop benefited from encouraging attendance by early career researchers (over a third of attendees), with dedicated funding to support those from outside the big projects, to help ensure momentum in this field is maintained.

The program was designed to give the majority of time to discussion with just 16 invited talks on the four themes of Surface influences on TZ function, New techniques and technologies, Carbon pathways through the TZ, and Controls on remineralization depth. These talks can be found here. Talks were designed to provoke discussion with subsequent breakout groups covering everything from the roles of viruses to fish. Funding to attend the workshop was generously provided by OCB, with the workshop itself funded by NERC (UK) and other travel assistance from SCOR. The workshop was intended as a kick-start to develop stronger international collaborations on TZ research, but practical outcomes are already emerging spanning from new joint papers to a draft plan for sharing data across projects.

NSF EarthCube Workshop for Ocean Time Series Data

Posted by mmaheigan 
· Monday, August 12th, 2019 
EarthCube time series -slider

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Ocean time series data survey

Venue and dates

Overview

Agenda

Participants

Organizers

Relevant resources

Do you generate, use, or manage ocean time series data? Please take a few minutes to complete this survey.

In preparation for this workshop, we have developed a short survey to better understand the data challenges and needs of the ocean time series community. Your feedback will help shape future cyber-infrastructure for ocean time series.

View the survey results (as of 12 August)

Venue and Dates

Venue: C-MORE Hale Center at the University of Hawai’i Mānoa campus  (PDF map), 1950 East West Road, Honolulu

The workshop will commence first thing in the morning on Friday, September 13 and will end at lunchtime on Sunday, September 15.

We are grateful to workshop sponsor NSF EarthCube and to the C-MORE Hale Center for hosting the workshop.

NSF EarthCube Workshop for Ocean Time Series Data
September 13-15, 2019 (Univ. Hawai’i, C-MORE Hale Center)

Rationale: Data synthesis and modeling efforts across ocean time-series represents an important and necessary step forward in broadening our view of a changing ocean and improving our return on investment in ocean time-series. Despite the advances achieved over the past decade, significant barriers remain that hinder work across time-series, including issues related to data access, discoverability, and metadata reporting. Furthermore, incorporation of ocean time series data into ocean and earth system models is currently limited due to the lack of a standardized data format and user interface

Scope and Goals: To begin addressing this problem, the Ocean Carbon and Biogeochemistry (OCB) Program (us-ocb.org) is convening a small workshop with funding from NSF EarthCube in September 2019 (in conjunction with OceanObs19). The objective of the workshop is to conduct a gap analysis to identify missing data infrastructure that would increase time series data availability and use. This workshop will provide a much-needed forum for discussion of key issues and barriers surrounding data discovery, access, and interoperability.

Participants will strategize a path forward on the development of a common framework for shipboard ocean time series data and metadata reporting, and data management resources. The overarching objective of this workshop is to move the shipboard ocean time series community toward a Findable, Accessible, Interoperable and Reusable (“FAIR”) model.
Topics of discussion will include (but are not limited to) the following ocean time series cyber-infrastructure challenges:

  • Establishing a common data model for reporting core time series variables (e.g., definitions, vocabulary, units, precision, associated errors, etc.)
  • Establishing standardized metadata reporting guidelines and required fields to facilitate data discovery and re-use
  • Improving interoperability among different databases/portals
  • Mechanisms to streamline and simplify data submission to oceanographic data management entities (e.g., automation of the time-series data acquisition/upload process)
  • Vision and framework for a dedicated time-series data interface that also includes user-friendly visualization and computation options
  • Meeting the needs of a broader range of users for data synthesis and information products emerging from ocean time-series
  • Application of unique identifiers (such as DOIs) to data sets to enable citation and crediting of data providers

Ocean Time Series Data Workshop Agenda

September 13-15, 2019
C-MORE Hale Center, Honolulu, HI

The workshop will commence first thing in the morning on Friday, September 13 and will end at lunchtime on Sunday, September 15.

Friday, September 13

8:00-9:00   Breakfast
9:00-9:30   Welcome and introductions around the room

PLENARY SESSION
Introduction/overview talks (15 min. talks with 5 mins. for Qs)
9:30   EarthCube overview (Danie Kinkade, BCO-DMO/WHOI)
9:50   FAIR data principles and initiatives (ENVRI-FAIR, GO-FAIR, Enabling FAIR data, etc.) (Justin Buck, BODC/NOC and Steve Diggs, UCSD/SIO)
10:10   Time series data challenges that hinder science (Angelicque White, UH)
10:10-10:30   Break

Insights from current data models (12 min. talks with 3 mins. for Qs)
10:30     How ocean time series efforts/frameworks are connected (Laura Lorenzoni, NASA)
10:45     Moving Towards FAIR Data Principles with ERDDAP (Kevin O’Brien, NOAA/PMEL)
11:00     The Ocean Observatories Initiative (OOI) approach to data and metadata (Wendi Ruef, Univ. Washington)
11:15     The international OceanSITES Eulerian Observing network (Johannes Karstensen, GEOMAR)
11:30     Use of controlled vocabularies: Potential applications to time series data (Justin Buck, BODC/NOC or Adam Shepherd, WHOI/BCO-DMO)
11:45     Integrated Carbon Observation System (ICOS) Ocean Thematic Centre (OTC) (Benjamin Pfeil, Univ. Bergen)
12:00    Ocean Best Practices (Johannes Karstensen, GEOMAR)
12:15    Questions and discussion
12:30-1:30    Lunch

Time series data integration and products (15 min. talks with 5 mins. for Qs)
1:30   Tools and approaches to facilitate data synthesis (Mark Schildhauer, NCEAS/UCSB)
1:50   International Group for Marine Ecological Time Series (IGMETS) overview and challenges (Laura Lorenzoni, NASA/USF)
2:10   Plans for a newly funded GLODAP-type time series data product (Björn Fiedler, GEOMAR)

2:30-5:00   Small group discussions (participants self-select, coffee will be available if needing a break)
Group 1. Establishing a common data model for reporting core time series variables (e.g., definitions, vocabulary, units, precision, associated errors, etc.) (Chair: Justin Buck)
Group 2. Mechanisms/approaches for improving interoperability among different databases/portals for time series data (Chair: Mark Schildhauer)

5:00   Adjourn for the day, dinner on your own

 

Saturday, September 14

8:00-9:00   Breakfast
9:00   Group 1-2 report outs  (15 mins. for each chair)
9:30   Group discussion
10:00-12:30   Small group discussions (participants self-select, coffee will be available if needing a break)
Group 3. Establishing standardized metadata reporting guidelines and required fields to facilitate time series data discovery and re-use (Chair: Angel White)
Group 4. Streamlining and simplifying time series data submission (Chair: Danie Kinkade)

12:30-1:30   Lunch
1:30   Group 3-4 report outs  (15 mins. for each chair)
2:00   Group discussion

2:30-5:00   Small group discussions (participants self-select, coffee will be available if needing a break)
Group 5. Application of unique identifiers (such as DOIs) to enable time series data citation and credit to be attributed to data providers (Chair: Adam Shepherd)
Group 6. Meeting the needs of a broader range of users for data synthesis and information products emerging from ocean time-series (Chair: Laura Lorenzoni)
Group 7. Designing the ultimate time-series data interface that also includes user-friendly visualization and computation options (Chair: Lance Fujieki)

5:00   Adjourn for the day
6:30-8:30   Group dinner (Tiki’s Grill and Bar, 2570 Kalakaua Ave)

 

Sunday, September 15

8:00-9:00   Breakfast
9:00   Group 5-7 report outs  (15 mins. for each chair)
9:45   Group discussion
10:15   Break

10:30   Participants assist chairs to finish compiling recommendations from small groups and discuss format/outcomes (participants self-select for one breakout topic to assist with)

11:30   Full group discussion (issues and remaining Qs, next steps, assignments, etc.) – considering the following:
Format of recommendations (best practices) – Ocean Best Practices to codify once finalized
EarthCube guidelines/requirements?
Dissemination to time series community for feedback
Opportunities for peer-reviewed publication(s)

12:00   Closing remarks and adjourn
12:30   Lunch

Workshop participants

Jose Abella-Gutiérrez
jabella@cigom.org

Andrew Barna
abarna@ucsd.edu

Heather Benway
hbenway@whoi.edu

Annie Bourbonnais
abourbonnais@seoe.sc.edu

Justin Buck
juck@bodc.ac.uk

B. B. Cael
bbcael@hawaii.edu

Pat Caldwell
patrick.caldwell@noaa.gov

Fernando Carvalho Pacheco
fcarvalho.pacheco@gmail.com

Tara Clemente
tclement@hawaii.edu

Kim Currie
kim.currie@niwa.co.nz

Ed Dever
Edward.Dever@oregonstate.edu

Bjoern Fiedler
bfiedler@geomar.de

Lance Fujieki
fujieki@hawaii.edu

Ralf Goericke
rgoericke@ucsd.edu

Adriana Gonzalez Silvera
adriana.gonzalez@uabc.edu.mx

Joseph Gum
jgum@ucsd.edu

Dana Hunt
dana.hunt@duke.edu

Robert Izett
rizett@eoas.ubc.ca

Rod Johnson
Rod.Johnson@bios.edu

David Karl
dkarl@hawaii.edu

Johannes Karstensen
jkarstensen@geomar.de

Danie Kinkade
dkinkade@whoi.edu

Nico Lange
Nico.Lange@uib.no

Ricardo Letelier
letelier@coas.oregonstate.edu

Laura Lorenzoni
laura.lorenzoni@nasa.gov

Mai Maheigan
mmaheigan@whoi.edu

David Nicholson
dnicholson@whoi.edu

Kevin O'Brien
kevin.m.o'brien@noaa.gov

Ben Pfeil
benjamin.pfeil@uib.no

Al Plueddemann
aplueddemann@whoi.edu

James Potemra
jimp@hawaii.edu

Wendi Ruef
wruef@uw.edu

Mark Schildhauer
schild@nceas.ucsb.edu

Adam Shepherd
ashepherd@whoi.edu

Jim Todd
james.todd@noaa.gov

Ian Walsh
iwalsh@seabird.com

Di Wan
Di.Wan@dfo-mpo.gc.ca

Angelicque White
aewhite@hawaii.edu

Timothy Whiteaker
whiteaker@utexas.edu

Workshop organizing committee

Heather Benway, Mai Maheigan, Mary Zawoysky (Woods Hole Oceanographic Inst./OCB)

Justin Buck (National Oceanography Centre/British Oceanographic Data Centre)

Rod Johnson (Bermuda Inst. Ocean Sciences/Bermuda Atlantic Time series Study)

Danie Kinkade, Adam Shepherd (Woods Hole Oceanographic Inst./BCO-DMO)

Laura Lorenzoni (NASA, Univ. South Florida)

Mark Schildhauer (Univ. California, Santa Barbara, National Center for Ecological Analysis and Synthesis, NCEAS)

D. Sarah Stamps (Virginia Tech Univ./EarthCube liaison)

Angelicque White (Univ. Hawai'i, Hawaii Ocean Time series)

NSF liaisons

Hedy Edmonds (NSF Chemical Oceanography)

Mike Sieracki (NSF Biological Oceanography)

Relevant resources

Armstrong EM, et al (2019) An Integrated Data Analytics Platform. Front. Mar. Sci. 6:354. doi: 10.3389/fmars.2019.00354

Bailey K, et al (2019) Coastal Mooring Observing Networks and Their Data Products: Recommendations for the Next Decade. Front. Mar. Sci. 6:180. doi: 10.3389/fmars.2019.00180

Benway HM, et al (2019) Ocean Time Series Observations of Changing Marine Ecosystems: An Era of Integration, Synthesis, and Societal Applications. Front. Mar. Sci. 6:393. doi: 10.3389/fmars.2019.00393

Buck JJH, et al (2019) Ocean Data Product Integration Through Innovation-The Next Level of Data Interoperability. Front. Mar. Sci. 6:32. doi:10.3389/fmars.2019.00032

deYoung B, et al (2019) An Integrated All-Atlantic Ocean Observing System in 2030. Front. Mar. Sci. 6:428. doi: 10.3389/fmars.2019.00428

Kaiser BA, et al (2019) The Importance of Connected Ocean Monitoring Knowledge Systems and Communities. Front. Mar. Sci. 6:309. doi: 10.3389/fmars.2019.00309

Pearlman J, et al (2019) Evolving and Sustaining Ocean Best Practices and Standards for the Next Decade. Front. Mar. Sci. 6:277. doi: 10.3389/fmars.2019.00277

Snowden D, et al (2019) Data Interoperability Between Elements of the Global Ocean Observing System. Front. Mar. Sci. 6:442. doi: 10.3389/fmars.2019.00442

Steinhoff T, et al (2019) Constraining the oceanic uptake and fluxes of greenhouse gases by building an ocean network of certified stations: the ocean component of the Integrated Carbon Observation System, ICOS-Oceans. Front. Mar. Sci. 6, doi: 10.3389/fmars.2019.00544

Tanhua T, et al (2019) Ocean FAIR Data Services. Front. Mar. Sci. 6:440. doi: 10.3389/fmars.2019.00440

2020 Activity Solicitation

Posted by mmaheigan 
· Friday, August 9th, 2019 

The Ocean Carbon and Biogeochemistry (OCB) Program is soliciting proposals for OCB activities that will take place or begin during the 2020 calendar year. We seek proposals for OCB-relevant workshops and activities as follows:

  • Scoping workshops (~50-70 people) that bring together an appropriate body of expertise to foster discussions and develop forward momentum in a specific OCB-relevant research area (list of previous OCB scoping workshops)
  • Working groups (~8-12 members) to address targeted science goals/questions and develop products that benefit the broader OCB community (current OCB working groups on OCB website under Activities > Small Group Activities)
  • Synthesis activities to bring together existing data sets, model outputs, etc. to support and inform future research efforts (recent example: Coastal CARbon Synthesis, CCARS)
  • Intercomparison activities to assess and build consensus on best practices (methodological, modeling, data analysis, etc.) for advancing OCB-relevant research (recent examples: Intercomparison and Intercalibration of Ocean Metaproteomic Analyses, Ocean Carbonate System Intercomparison Forum)
  • Training activities (~30-50 participants plus instructors as needed) to build capacity in different areas of OCB research (recent examples here)

More information and proposal guidelines here.

Towards a better understanding of fish contribution to carbon flux OCB workshop summary

Posted by mmaheigan 
· Thursday, August 8th, 2019 

Summary

This workshop, held March 4-5, 2019 at Rutgers University, was attended by 14 researchers from 11 different institutions. The workshop focused on synthesizing the existing research on fish carbon flux, discussing challenges in measuring fish carbon flux, and determining approaches for estimating fish contribution to carbon flux on variable scales. Presentations interspersed with group discussions were specifically targeted toward best approaches for determining: fish biomass on regional and global scales, relative amounts of carbon forms produced from fish (i.e., release of sinking fecal pellets, excretion of particulate inorganic carbon and dissolved organic carbon, respiration of carbon dioxide), and carbon flux estimates from fish biomass (i.e., bioenergetics, size-based allometric relationships, stable isotopes).

Participants

Workshop participants: Standing from L to R – Clive Trueman, Rod Wilson, Santiago Hernández-León, Kenneth Rose, Adrian Burd, John Dunne, Angela Martin; Sitting from L to R – Grace Saba, Deborah Steinberg, Stephanie Wilson. Other Fish Carbon working group participants that were unable to attend the meeting include: Nicola Beaumont, Joe Salisbury; Guest presenters at the workshop (not pictured): Olaf Jensen, Charles Stock

Monday, March 4, 2019

Overview of Project and Workshop Goals
Presentation by Grace Saba, Fish Carbon Work Group Lead

The ‘biological pump’, the vertical transport of biologically generated dissolved or particulate organic matter from the surface to the ocean’s interior, plays a key role in ocean biogeochemistry and food webs. Active transport of carbon via diel vertically migrating (DVM) organisms as well as passive transport via their rapidly sinking fecal pellets are major contributors to the ‘biological pump’. With more than 500 studies measuring zooplankton flux, there is a wealth of knowledge of zooplankton active and passive transport and their contributions to carbon flux. However, fish contribution to the biological pump is a complete unknown. To our knowledge, less than ten studies have estimated active transport in DVM fish and only five studies focused on direct measurements of fish passive flux. Mesopelagic DVM fishes from these few studies can contribute ~30- 40% of total carbon flux through respired and excreted carbon byproducts. Furthermore, all reports on fish fecal pellets thus far have demonstrated the formation of cohesive, durable, rapidly sinking fecal pellets. Additionally, two studies revealed that fish contribute up to 15% of total oceanic carbonate production (inorganic C) via the formation and excretion of various forms of precipitated (non-skeletal) calcium carbonate from their guts.

This information is essential to not only determine its potential for a food source for benthic organisms, but also to improve parameterization of key processes affecting the biological pump and to develop more accurate regional and global carbon models. Only then can we begin to understand interannual and seasonal/spatial variability and long-term changes of fish fecal flux, food web regulation of carbon flux, and evaluate the potential role of environmental factors and climate change on fish carbon flux. This working group is aimed at synthesizing existing knowledge of fish carbon flux, investigating the challenges associated with estimating fish contribution to the biological pump, and paving a path forward to develop approaches to begin filling some of the gaps in this much needed research. The overarching goals of the working group are to synthesize the existing research on fish carbon flux, recognize the challenges in measuring fish carbon flux and discuss approaches to resolve them, develop research priorities to fill the large gaps in understanding fish carbon flux, and identify opportunities to obtain resources needed to move this research forward. Since its inception, this working group has been meeting virtually, on average, every three months to assign tasks to complete in between calls in order to address these goals. The in-person workshop was aimed at completing some tasks and making significant progress on the more challenging aspects of some of these tasks. The specific goals for the workshop were as follows:

  • Finalize Paper 1: Synthesis, Challenges, Gaps, Research Priorities, Assign specific tasks with deadlines for completion
  • Make as much progress as possible on Paper 2: Outline emerging methods, and first attempt at estimating global and/or regional carbon contributions
    • Finalize Approaches for Fish Biomass Estimates, Passive and Active Fish Carbon Fluxes, Comparisons to Total Carbon Flux and Zooplankton Flux
    • Assign specific tasks with deadlines to complete Paper 2
  • Discuss Potential Proposals for Filling Gaps

Fish Carbon Synthesis, Challenges, Gaps, and Research Priorities
Presentation by Angela Martin followed by Group Discussion

Through web conference calls and ongoing iterations of a draft manuscript, the group has conducted a synthesis of knowledge on fish carbon flux and has developed a list of research challenges and research priorities. This is still an ongoing process, and the group is still working on incorporating thoughtful content for the manuscript. Specifically, the group is currently in the process of completing a summary of available methods for flux measurements to highlight the gaps, an approach to overcoming identified research challenges, and a prioritized list of the research needs.

Fish Biomass: Challenges and Best Approaches
Presentations by Olaf Jensen and Charles Stock followed by discussion

Dr. Olaf Jensen summarized four approaches to estimate fish biomass. These include:

  • Scaling up density estimates: Estimate an areal density from data collected from trawl or hydroacoustic surveys and multiplying by area. However, challenges exist in making these estimates. Catch efficiency from trawl surveys has uncertainty due to herding effects or escapes, and bias in scaling up hydroacoustic surveys caused by scattering other types of organisms (i.e., siphonophores) can occur.
  • Energetic approach: From primary production measurements, scale up energy movement through food chain to fish biomass using an estimated value of trophic transfer efficiency (i.e., 10%). This approach is currently used in EcoPath and EcoSym models, and has also been described previously in Ryther 1969 and Pauly and Christensen 1995. However, uncertainty in this approach occurs when making required assumptions as to what proportions of biomass of each trophic level is fish and the trophic transfer efficiency.
  • Size-based models: Using size-based relationships between trophic levels such that the slope of the size spectrum is predictable and the proportion of fish at each size in the size spectrum can be estimated (Jennings and Collingridge 2015). This approach assumes predation is size-structured, but not all predation follows this pattern.
  • Stock assessment data: Mathematical models used to estimate the size and productivity of fish or invertebrate stocks using index of abundance (i.e., trawl surveys) and how much is removed to see if the amount harvested is making an impact on the annual reproduction of stocks. However, this is limited because stock assessments are used only for specific targeted fish and, although there are some global stock assessment data bases (i.e., RAM), the tropics do not have good stock assessment data because of the operational cost. Additionally, productivity and standing stock are confounded and not equal.

All of these different approaches incorporate a modeling aspect of variable scale, and they can produce very different estimates by an order of magnitude that could be used to bound the estimates of biomass, and subsequently fish carbon contribution. Using a snapshot of biomass is valuable, but for estimating the role of fish in carbon flux, information about the flux of fish biomass over some time interval is also necessary information. Following the presentation, the group discussed potential spatial and vertical scales at which fish biomass and carbon flux could be determined and approaches that were most appropriate for global vs regional analysis.

The presentation by Dr. Charles Stock focused on the challenges of incorporating fish in biogeochemical models as well as past and ongoing efforts to do so. Energy flows decay very rapidly from phytoplankton to fish, so using net primary productivity to estimate fish biomass or abundance is not sufficient. Incorporating trophodynamics (i.e., trophic transfer efficiency) is a necessary step and there is high uncertainty in these estimations. Uncertainties in biomass estimation at each trophic level can greatly impact the biomass estimate at the highest trophic levels.

Modified from Dr. Olaf Jensen presentation “Estimating Global Fish Biomass” available on this project’s website.

Furthermore, regionally the trophodynamics vary greatly and will likely cause sharp spatial and vertical gradients in fish importance with respect to carbon flux. Newly developed models such as those that include fish size and functional type (Petrik et al. 2019) are promising for mechanistically resolving fish biomass at different trophic levels. From a discussion following the presentation, the group decided that a review of available models for estimating fish biomass should be included in the synthesis paper and should discuss strengths and weaknesses for each.

Tuesday, March 5, 2019

Getting Carbon Estimates from Fish Biomass
Presentations by Kenneth Rose and Clive Trueman

Dr. Rose described several model options to estimate carbon production from fish. These include the classical bioenergetic models (Wisconsin [Kitchell] and Dynamic Energy Budget [DEB]) and an Aquaculture model. The Wisconsin (Kitchell) model considers consumption, respiration, specific dynamic action, egestion, excretion, and egg production. Growth is typically estimated from the model.

It does not incorporate mortality and reproduction. The inclusion terms are not independent as patterns in consumption effect all other parameters in the model equation. The terms of this model relate to Cmax, or the maximum the fish can eat; however, fish are likely not always eating at their full capacity and could bias model output. There are ongoing efforts to uncouple the models and incorporate food availability to reflect more realistic conditions. The model is daily time-stepped, and all processes are temperature and size dependent. Although there are many versions of the equation, typically consumption is the only thing that is changed and the waste product is usually 0.7.

Dynamic Energy Budget: Jusup et al. 2011.

The DEB approach was developed to model energy inputs, storage, energy allocation (to growth, somatic maintenance, reproduction), and waste outputs in individual fish. The big difference between the Wisconsin (Kitchell) and a DEB model is that in a DEB, the energy allocated towards growth and reproduction can be adjusted according to fish species and size.

Aquaculture Model (AQUA): Rensel et al. 2006.
(Above) Three model examples presented by Dr. Kenneth Rose.

Models have recently been developed to determine the fate of aquaculture waste products and potential impacts on local benthic areas and downstream. The models look similar to the bioenergetic models; however, in this case the biomass (fish weight), growth rate, and food availability terms are known and the model incorporates a benthic component. DEPOMOD models the deposition and biological effects of solid wastes by tracking the waste as particles to see the fate of the waste (i.e. advection, settling, resuspension, etc.), and then incorporates a benthic component. The AQUA model incorporates different kinds of waste, and once solid waste reaches the bottom, the benthic community response is modeled.

Dr. Trueman gave two presentations focused on estimating carbon from fish – the first on using size-based macroecological models to estimate fish biomass and the second on using stable isotopes to estimate carbon from fish biomass estimates. First, the aim of size-based models is to predict biomass/abundance through an ecosystem as a function of body size and primary production. Using this model, you can estimate how energy is divided between trophic levels assuming community is size-structured. The advantages for using this method include simplification (easy to understand), ease of coupling to GCM models, and there are large data sets of body size to validate against. The key variables can be constrained a bit with relatively simple field data, and these include available primary production, temperature-dependent consumer metabolic rate, predator prey mass ratio (PPMR), and trophic transfer efficiency (TE). Typically, consumer production depends on body size and temperature. Additionally, biomass size spectrum depends on PPMR and transfer efficiency, whereby at high PPMR/constant TE and High TE/constant PPMR, there is a short food chain and a lot of energy goes through small low trophic animals. Some examples using these types of models include Jennings and Collingridge 2015 and Blanchard et al. 2008. However, as described earlier, TE and PPMR are relatively poorly constrained and cause high uncertainty in the model. But these models can be used to get approximate or range of carbon flux estimates. The models essentially track the remaining carbon after respiratory loss, and the 1-TE term in the model effectively sets available carbon for storage.

One other potential method for estimating carbon flux from fish biomass is via stable isotopes. Isotopes useful for tracking movement of carbon where this occurs across natural isotopic gradients. Isotopes can be used to determine the PPMR due to the effect of isotopes in eating vs. waste products. And then if biomass size spectrum is known, we can infer the TE or ask if the TE can link the measured PPMR. Community level analyses can also recover PPMR. Additionally, isotope analysis on fish otoliths can be used to measure metabolic rates in the field. Carbonate in the aragonite is sourced from DIC from surrounding water or from carbon respired, and the rate at which respiring dietary carbon is influenced on the isotopic ratio. Additionally, oxygen isotopes in the otolith can be used to derive temperature (thermal history) and therefore metabolic rates. This method is beneficial in estimating field metabolic rates in fish that are difficult to collect and maintain in the laboratory for traditional metabolic experiments (i.e., DVM mesopelagic fish). Combined with biomass data, isotopes could be used to quantify C flux.

Forms of Carbon
Presentations by Joe Salisbury, Rod Wilson, Grace Saba, and Santiago Hernández-León

Dr. Salisbury’s presentation was focused on whether or not the carbon removed from fishing/harvesting activities is a significant loss of carbon. The particulate organic carbon (POC) in ocean fish is brought onto land where it oxidizes relatively quickly. Similarly, consumption of fish stocks by birds is on the same order of magnitude as global fishing effort. Once consumed, they respire this POC directly into the atmosphere, potentially lowering seawater dissolved inorganic carbon and pCO2. However, bird feces released back into the water may add some of this carbon back but at a lower carbon-to-nitrogen ratio. Preliminary simplified calculations of this potential carbon loss from wild fish and aquacultured products is comparable to about ~10-15% of the coastal air-sea flux (0.2-0.4 Pg/yr vs. ~0.3-0.4 Pg/yr).

Dr. Rod Wilson suggests that fish are a major producer of new calcium carbonate, CaCO3. Fish calcium carbonate is not skeletal in origin (bone is actually calcium phosphate), but is instead produced in the gut via osmoregulation physiology. They live in a very salty environment but they have a blood osmolarity of ~330 mOsm/kg. Marine teleosts are constantly suffering or tending towards dehydration, and the only thing they can drink is seawater. Seawater ions are high in magnesium and calcium. As these ions are moving through the fish intestine, they are secreting bicarbonate which promotes calcium carbonate production. The calcium carbonate gets wrapped in a mucus coating and then excreted, along with some magnesium precipitates. Conservative estimates of fish CaCO3 production equal 40-110 million tonnes/year (0.04-0.11 Pg CaCO3-c/year = 3 to 15% of global CaCO3 production. Less conservative, but likely more realistic estimates are 3x greater (9-45% of global CaCO3 production). And in a warmer, higher CO2 future (+ 4C/1000uatm CO2), fish CaCO3 production could be >70% higher. The rate at which calcium carbonate is produced is proportional to feeding rates, whereby the mean production rate of CaCO3 in feeding fish is 10x higher than starved fish. Additionally, fecal CaCO3 content can affect the sinking rate of fecal pellets, whereby higher CaCO3 content leads to faster sinking rates. But once excreted, the fish carbonates dissolve rapidly, which can add alkalinity to seawater and as such may explain the reason why surface ocean alkalinity is higher than would be expected based solely on salinity estimates. Furthermore, DVM mesopelagic fish may drive an “alkalinity pump” through their vertical movements while excreting CaCO3.

Northern anchovy fecal pellets collected in Santa Barbara Channel sink up to 1370 m d-1 (from Saba & Steinberg 2012).

Dr. Saba described the body of work focused on fecal pellet flux measurements in zooplankton, and that lessons learned here can be applied to fish flux measurements. There has been much work focused on many different types of zooplankton, and the surface zooplankton community composition plays a big role in the types and sizes of pellets produced and how much carbon is entrained in them. For instance, gelatinous salps produce pellets that are larger and sink more rapidly compared to those produced from other zooplankton such as krill and copepods. The quality of pellets also depend on what the zooplankton were feeding on. There has been much less research focused on fish fecal pellet production and carbon flux. However, fish likely are important exporters too (i.e., northern anchovy fecal pellet sinking rates of 458 – 1370 m/d). Fish create very distinctive and well-packed fecal pellets (high in carbon and nitrogen) likely with minimal remineralization as they sink. Approaches used and challenges in measuring fecal pellet flux were also discussed. Sediment traps can directly collect sinking material in a location, but they miss most of the fish flux due to the heterogeneity of fish movements and distributions. Lab and field studies can directly measure pellet production and sinking rates, but likely fail to reflect in situ feeding conditions and may bias rate measurements. Bioenergetic and allometric modeling techniques can be used, but assumptions have to be made to constrain measurements.

Dr. Hernandez-Leon’s presentation focused on the relationship between respiration rates and electron transfer system (ETS) activity in fishes in relation to swimming activity. ETS activity is used as a proxy for respiration and is used for deep sea fish because it is experimentally difficult to measure true respiration in these fishes from laboratory experiments conducted at surface conditions. However, initial laboratory experiments need to be carried out to determine relationships between respiration and swimming speed. From acoustic approaches, the upward and downward velocities of DVM can be determined for a migration time (1-2 hours). And using an example species in the lab with swim flume techniques, the repiratory/ETS ratios can be determined at different swimming speeds.

Approach for comparisons of Fish C Flux to Total and Zooplankton Flux
Presentations by Deborah Steinberg, Santiago Hernández-León, and John Dunne followed by discussion

Dr. Debbie Steinberg presented recent research focused on zooplankton and the biological carbon pump as a basis to start thinking about comparisons with fish. She pointed to a recent review paper that reviews what we know so far regarding zooplankton and their role in the biological pump (Steinberg and Landry 2017). Recent zooplankton research suggests carcasses play an important role in carbon flux, but it is difficult to measure so there are a lot of unknowns. Active transport through vertical migration is also an important mode of bringing excreted DOC, egested POC/PIC, and respired CO2 to depths after feeding at the surface during the nighttime. The magnitude of active transport in DVM zooplankton can also be estimated because we can directly determine biomass (net tows, acoustics, etc.) and then derive carbon flux through respiration measurements (direct, ETS, Allometric/size-based algorithms of metabolism) and POC/PIC flux estimates. With respect to the fecal pellets, community size structure is very important in determining the magnitude. And recent work using long-term data sets suggests that temperature and changing zooplankton distributions and diversity play important roles in regulating carbon flux. As ocean warms, smaller tropical/subtropical species move poleward, increasing diversity. These smaller zooplankton produce pellets that have long residence times in the surface, effectively decreasing the flux of particulate C to the deep. In regions such as BATS, however, there have been observed increases in zooplankton active transport and fecal pellet production as a result of increases in biomass.

In order to make comparisons between zooplankton and fish, we need more information on fish fecal material (classify for taxa, measure production and sinking rates with respect to feeding rates and size, respectively), fish respiration rates, PIC production/dissolution rates. We will also need global carbon export models that can be used to look at relative contributions of fish and zooplankton fluxes.

From Dr. Hernández-León presentation “Zooplankton and Micronekton Active Flux” available on this project’s website (Sourced from Ariza et al. 2015).

Dr. Santiago Hernández-León presented work from recent cruises that compared zooplankton and micronekton active flux. There are currently very few studies (two published) with direct zooplankton and fish comparisons. Their research team employed net tows to measure biomass and abundance and ETS activity for respiration measurement of zooplankton and micronekton in the Atlantic Ocean from coast of Brazil to the Canary Islands and get a gradient from oligotrophic to eutrophic zones (MAFIA cruise). Through these methods, they determined the proportion of respiratory flux to migrant biomass. However, he noted that capture efficiency of micronekton trawls likely underestimated active flux contributions.

Particle export ratio (ratio of sinking particle flux at the base of the euphotic zone to the Net Primary Productivity from Devries and Weber 2017.

Dr. John Dunne presented past and current efforts of modeling primary production to ecosystems and particle export. His work used empirical and mechanistic models to determine particle export ratio (Dunne et al. 2005). He suggested that any of these methods are considered successful if they come out with 50% or less uncertainty particle export. Additionally, Dunne et al. 2007 conducted a synthesis of global particle export from the surface ocean and cycling through the ocean interior and on the seafloor. The particle export estimates converge quite a bit because uncertainty has to do with temperature and microbial activity. An effort by Laws et al. 2011 used simplified equations to estimate ratios and produced better estimates in the tropics. Finally, Devries and Weber 2017 combined data simulation with geochemistry and satellite estimates through an ecosystem model and came up with a cross calibrated representation to account for sinking particle flux and attenuation.

Next Steps:

Planned products resulting from this workshop and ongoing working group efforts include two peer-reviewed manuscripts focused on the synthesis of fish carbon flux research and a quantitative analysis of fish carbon flux.

Regional circulation changes and a growing atmospheric CO2 concentration drive accelerated anthropogenic carbon uptake in the South Pacific

Posted by mmaheigan 
· Tuesday, August 6th, 2019 

About one tenth of human CO2 emissions are currently being taken up by the Pacific Ocean, which makes the seawater more corrosive to the calcium carbonate shells and skeletons of the plants and animals that live there. Now, thanks to hard work by international teams of scientists from the Global Ocean Ship-based Hydrographic Investigations Program (GO-SHIP), there are decades of data, enough to test how much this anthropogenic CO2 accumulation varies throughout the Pacific Ocean and regionally on the timescales of decades.

 

Figure caption: Map of the concentration of human-emitted CO2 along the sections where data were available from more than one decade, estimated for the year 2015.

Using a new take on an old technique, along with a wide variety of repeat biogeochemical measurements, a study in Biogeochemical Cycles revealed that Pacific anthropogenic CO2 accumulation increased from the 1995-2005 decade to the 2005-2015 decade. While the magnitude of the decadal increase was consistent with increases in human CO2 emissions over this period for most of the Pacific, the rate of change was greater than expected in the South Pacific subtropical gyre. The authors suggest that recent increases in circulation in the gyre region could have delivered an unexpectedly large amount of anthropogenic CO2-laden seawater from the surface to the ocean interior. Programs like GO-SHIP will continue to be critical for tracking the fate of human CO2 emissions and associated feedbacks on climate and marine ecosystems.

 

Authors:
B. R. Carter (Univ. Washington and PMEL)
R. A. Feely, G. C. Johnson, J. L. Bullister (PMEL)
R. Wanninkhof (NOAA AOML)
S. Kouketsu, A. Murata (JAMSTEC
R. E. Sonnerup, S. Mecking (Univ. Washington)
P. C. Pardo (Univ. Tasmania)
C. L. Sabine (Univ. Hawai‘i, Mānoa)
B. M. Sloyan, B. Tilbrook (CSIRO, Australia)
K. Speer (Florida State University
L. D. Talley (Scripps Institution of Oceanography)
F. J. Millero (Univ. Miami)
S. E. Wijffels (CSIRO and WHOI)
A. M. Macdonald (WHOI)
N. Gruber (ETH Zurich)

A new era of observing the ocean carbonate system

Posted by mmaheigan 
· Tuesday, August 6th, 2019 

Amidst a backdrop of natural variability, the ocean carbonate system is undergoing a massive anthropogenic change. To capture this anthropogenic signal and differentiate it from natural variability, carbonate observations are needed across a range of spatial and temporal scales (Figure 1), many of which are not captured by traditional oceanographic platforms. A new review of autonomous carbonate observations published in Current Climate Change Reports highlights the development and deployment of pH sensors capable of in situ measurements on autonomous platforms, which represents a major step forward in observing the ocean carbonate system. These sensors have been rigorously field-tested via large-scale deployments on profiling floats in the Southern Ocean (Southern Ocean Carbon and Climate Observations and Modeling, SOCCOM), providing an unprecedented wealth of year-round data that have demonstrated the importance of wintertime outgassing of carbon dioxide in the Southern Ocean.

Figure 1: Observational capabilities and carbonate system processes as a function of time and space. Ocean processes that affect the carbonate system (solid color shapes—labeled in the legend) are depicted as a function of the temporal and spatial scales over which they must be observed to capture important variability and/or long-term change.

Most current autonomous platforms routinely measure only a single carbonate parameter, which then requires an algorithm to estimate a second parameter so that the rest of the carbonate system can be calculated. However, the ongoing development of sensors and systems to measure, rather than estimate, other carbonate parameters may greatly reduce uncertainty in constraining the full carbonate system. It is critical that the community continue to develop and adhere to best practices for calibration and data handling as existing sensors are deployed in increasing numbers and new sensors become available. Expanding autonomous carbonate measurements will increase our understanding of how anthropogenic change impacts natural variability and will provide a means to monitor carbon uptake by the ocean in real-time at high spatial and temporal resolution. This will not only help to understand the mechanisms driving changes in the ocean carbonate system, but will allow new insights in the role of mesoscale processes in regional and global biogeochemical cycles.

 

Authors:
Seth M. Bushinsky (Princeton University/University of Hawai’i Mānoa)
Yuichiro Takeshita (Monterey Bay Aquarium Research Institute)
Nancy L. Williams (Pacific Marine Environmental Laboratory – NOAA / University of South Florida)

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