September 2024

MACHINE LEARNING IN OCEAN REMOTE SENSING

THE AMOC EXAMINED // GULF OF MAINE COLD WAVE

METOCEAN DATA IN SUPPORT OF OFFSHORE WIND ENERGY

Oceanography

THE OFFICIAL MAGAZINE OF THE OCEANOGRAPHY SOCIETY

VOL. 37, NO. 3, SEPTEMBER 2024

September 2024 | Oceanography

GIN

cell

LSW cell

vertical

separation

horizontal separation

STMW

cell

AMOC

5 QUARTERDECK. Oceanography Ofers an Enticing Variety Pack

By E.S. Kappel

6 RIP CURRENT – NEWS IN OCEANOGRAPHY. Early Warning of a Cold Wave

in the Gulf of Maine

By N.R. Record, A.J. Pershing, and D.B. Rasher

10 COMMENTARY. Consensus Around a Common Definition of Atlantic

Overturning Will Promote Progress

By N.P. Foukal and L. Chafik

16 FEATURE ARTICLE. Is the Atlantic Overturning Circulation Approaching

a Tipping Point?

By S. Rahmstorf

30 FEATURE ARTICLE. Developments in Metocean Information in Support

of US Ofshore Wind Energy and the Ocean Sciences

By B.H. Bailey and J.M. Freedman

42 FEATURE ARTICLE. Forecasting a Summer of Extremes: Building Stakeholder

Response Capacity to Marine Heatwaves

By A.J. Hobday, C.M. Spillman, J. Allnutt, M.A. Coleman, F. Bailleul, L.K. Blamey,

S. Brodie, A. Chandrapavan, J.R. Hartog, D. Maynard, C. Mundy, É.E. Plagányi,

F. Seaborn, G.A. Smith, and J. Stuart-Smith

52 FEATURE ARTICLE. The Promise and Pitfalls of Machine Learning in Ocean

Remote Sensing

By P.C. Gray, E. Boss, J.X. Prochaska, H. Kerner, C. Begouen Demeaux,

and Y. Lehahn

64 WORKSHOP REPORT. Western Boundary Current–Subtropical Continental

Shelf Interactions

By W.B. Savidge, D.K. Savidge, F. Brandini, A.T. Greer, E.E. Hofmann,

M. Roughan, I. da Silveira, and I.M. Suthers

70 DIY OCEANOGRAPHY. Satellite Data Sharing for Scientific Inter-Group

Cooperation Using the Leaflet R Package

By C. Marchese, E. Boss, F. Falcini, D. Doxaran, C. de Vargas, G. Pfister,

and V.E. Brando

76 OCEAN EDUCATION. Developing Engineering Skills Through Project-Based

Learning: An Arduino-Based Submersible Temperature and Depth Sensor

By G. Lockridge and K.M. Dorgan

81 THE OCEANOGRAPHY CLASSROOM. Adapting a Teaching Method to Fit

Purpose and Context

By M.S. Glessmer, C. Bovill, and K. Daae

83 FROM THE TOS JEDI COMMITTEE. It Takes a Village: The Sea of Technical,

Administrative, and Other Support Colleagues Who Enable Ocean Science

By S.N. White, F.E. Muller-Karger, and E.L. Meyer-Gutbrod

85 CAREER PROFILES. Scott Loranger, Acoustician and Application

Scientist, Kongsberg Discovery • Jocelyn Runnebaum, Marine Scientist,

The Nature Conservancy

10

52

30

42

September 2024 | Oceanography

contents VOL. 37, NO. 3, SEPTEMBER 2024

Oceanography | Vol. 37, No. 3

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September 2024 | Oceanography

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September 2024 | Oceanography

One of the many joys of being the Oceanography editor is working with the community to deliver

a range of article types designed to be of broad interest to readers, from science features, to news

items, educational contributions, DIY projects, workshop reports, career profles, and more. It

is this range of article types that sets Oceanography apart from most journals publishing in the

ocean sciences sphere.

Tis September issue of Oceanography is a great example of the variety of content our journal

delivers. Te issue kicks of with a news item by Record et al. that brings attention to deep- water

oceanographic changes in the Gulf of Maine in 2024 and their possible implications. Te news is

followed by a commentary contributed by Foukal and Chafik who argue for using a density coor-

dinate system to defne the Atlantic Meridional Overturning Circulation (AMOC) rather than the

depth space defnition, and how adopting a common defnition of the AMOC in density coordinates

will promote progress in the feld. Four feature articles covering topics of broad interest to the ocean

sciences community follow this commentary: Rahmstorf on whether the AMOC is approaching a

tipping point, Bailey and Freedman on metocean aspects of ofshore wind energy, Hobday et al.

on building stakeholder response capacity to marine heatwaves, and Gray et al. on developing intu-

ition for using machine learning methods “wisely and in a way that benefts the community.”

Te feature articles are followed by a workshop report contributed by Savidge et al. on “Western

Boundary Current– Subtropical Continental Shelf Interactions.” Next, in a DIY Oceanography arti-

cle, Marchese et al. demonstrate the practical application of the leafet R package, which was used

on an expedition to improve data sharing and visualization, aiding in selection of sampling stations.

An ocean education article by Lockridge and Dorgan describes a half-semester course where stu-

dents build, calibrate, and test an Arduino-based instrument that measures temperature and depth.

Te September issue concludes with our regular columns. Glessmer et  al. share tips in

Te Oceanography Classroom on how to adapt teaching methods to ft purpose and context, encour-

aging instructors to experiment with it. Tis month’s JEDI Committee columnists White et al. shine

a light on all the personnel behind the scenes who don’t ofen get recognized for their contribu-

tions to oceanographic research, and they challenge the community to fnd avenues to acknowl-

edge these workers. As Oceanography has done for nearly 15 years, we conclude the issue by shar-

ing two career profles, one contributed by Scott Loranger (Kongsberg Discovery), and another by

Jocelyn Runnebaum (Te Nature Conservancy).

So, grab this issue of Oceanography and enjoy reading it from cover to cover. As an open access

journal, all the individual articles are available from Oceanography’s web pages (https://tos.org/

oceanography/ issue/volume-37-issue-3). Readers can instead choose to page through the fip-

book version found on our digital kiosk (https://oceanographydigital.tos.org/). Please think about

what else you might like to see in the journal and send me—or any of the Oceanography associ-

ate editors (https://tos.org/ oceanography/ editors)—a note. Or submit your own manuscript to

Oceanography through our web portal (https://oceanography.scholasticahq.com/). We look forward

to hearing from you.

QUARTERDECK

Ellen S. Kappel, Editor

Oceanography Ofers an

Enticing Variety Pack

DOI. https://doi.org/10.5670/oceanog.2024.512

Oceanography | Vol. 37, No. 3

RIP CURRENT – NEWS IN OCEANOGRAPHY

EARLY WARNING

OF A COLD WAVE IN THE GULF OF MAINE

By Nicholas R. Record, Andrew J. Pershing, and Douglas B. Rasher

Te Gulf of Maine was one of the frst

marine ecosystems to report a major

ocean heatwave, one that lasted for more

than a year in 2012–2013 and reached

temperatures projected for the end of the

twenty-frst century (Mills et  al., 2013).

Tat heatwave drove major ecologi-

cal shifs, including historically low cod

stocks (Pershing et  al., 2015), a multi-

year unusual mortality event for the

endangered North Atlantic right whale

(Record et  al., 2019), the collapse of

northern shrimp (Richards and Hunter,

2021), the near disappearance of blue

mussels from the intertidal zone (Sorte

et al., 2017), and other efects (Reardon

et  al., 2018; Scopel et  al., 2019). While

these impacts constituted a major sur-

prise that drew a great deal of attention

(e.g., Woodard, 2020), the consequences

were documented only afer the fact,

highlighting the need to monitor rapid or

surprising oceanographic changes as they

are happening.

Subsequent research showed that the

heatwave was preceded by extremely

warm deep water entering the gulf

through the Northeast Channel a year

prior (Balch et al., 2022). Te Northeast

Channel is the only conduit for deep

water into this shallow sea, and because

of the sheer volume of water below

the thermocline, the water masses that

enter through this path have an out-

sized infuence on long-term dynamics.

Tis infuence is generally a refection of

the “Coupled Slope Water System” that

includes the Gulf of Maine (MERCINA

Working Group, 2001) and that is tightly

connected over long timescales to the

deep water in the Northeast Channel

(Sherwood et al., 2011). Changes in the

state of this system have coincided with

approximately decadal regime shifs in

the Gulf of Maine ecosystem (Greene

and Pershing 2007; Meyer-Gutbrod et al.,

2021). Oceanographers have suggested

the potential for early warnings of major

changes based on upstream dynamics

(Greene and Pershing, 2003; Gonçalves

Neto et al., 2021). Because of the impor-

tance of subsurface currents to this pro-

cess, focusing on surface conditions can

mask important dynamics.

Afer more than a decade of consis-

tently warming conditions, the deep

water in the Gulf of Maine has a thermo-

haline regime not detected since before

the heatwave signal appeared in 2011.

A buoy in Jordan Basin has recorded

water column temperatures and salinities

near-continuously since 2003 (Figure 1a).

Prior to 2011, mean annual tempera-

tures at 250 m depth had ranged from

approximately 7°C to 8.5°C. Since 2011,

these temperatures have ranged from

approximately 8.5°C to 10°C (Figure 1a).

Te lack of overlap between these two

regimes supports the idea that the supply

of water through the Northeast Channel

has undergone a major shif from sub-

arctic Labrador Slope Water to subtrop-

ical slope water associated with the Gulf

Stream. Te shif in salinity—a conserved

property—is consistent with a change in

source waters. Te fact that 2024 stands

out somewhat from the cluster of other

cold, fresh years suggests that the colder,

fresher Labrador source water, while sig-

nifcantly colder than it was in the past

decade, is running around 1°C warmer

ABSTRACT. Oceanographic changes are occurring more rapidly in recent decades,

with new implications for ocean ecosystems and adjacent human communities. It is

important to bring attention to these changes while they are unfolding rather than afer

they have occurred. Here we report on a rapid shif toward colder, fresher water in the

deep Gulf of Maine that, as of mid-June 2024, has persisted for at least six months.

Te shif likely represents an infux of Labrador Slope Water and resembles conditions

that predated a major warming shif that occurred in 2011–2012. Deep-water oceano-

graphic conditions in the Gulf of Maine have a strong infuence on ecosystem dynam-

ics, including the prey of critically endangered North Atlantic right whales, the sea-

sonal and disease dynamics of American lobster, and the distribution and abundance

of kelp forest communities, among others. Oceanographic surprises have an important

role in this system, and monitoring how this shif unfolds, oceanographically and eco-

logically, will give new insights into how oceanographic signals can inform our under-

standing of ecosystem responses.

September 2024 | Oceanography

than the historical Labrador source water

of the early 2000s. Tis is consistent with

warming in the upstream source region.

At a time when North Atlantic sur-

face temperatures were broadly break-

ing record warming levels during 2023

(Hobday et al., 2023), Gulf of Maine sur-

face conditions were running just a little

above average. Meanwhile, a shif toward

an input of Labrador Slope Water that

began setting up during the fall of 2023

was detectable in the subsurface waters

(Figure 1c). Conditions in 2024 have been

consistently within the temperature and

salinity ranges that characterize the pre-

2011 period—conditions that had not

been recorded since before the heatwave.

Based on long-term climate projec-

tions, we expect the water mass input

to shif at some point back toward the

previous warm and salty conditions

(Brickman et  al., 2021). However, we

do not know when or how quickly that

return will occur. Because of the large

volume of water and its separation from

the atmosphere, such deep-water condi-

tions carry a lot of thermal inertia. More

importantly, the winter and spring ocean-

ographic conditions at depth have histor-

ically had strong associations with how

the biology of the Gulf of Maine devel-

ops over the summer. Efects can con-

tinue into autumn, as vertical mixing

carries deep waters to the surface. Tus,

these conditions can serve as an early sig-

nal for potential ecological shifs in the

coming months whose possible efects are

described below.

NORTH ATLANTIC RIGHT WHALES. Te

primary prey of these critically endan-

gered whales, the copepod Calanus

fnmarchicus, is strongly infuenced by

the supply and conditions set up by these

same deep-water dynamics. During the

historic cold, fresh years, C. fnmarchicus

was abundant in the eastern Gulf of

Maine, and large numbers of right whales

would aggregate annually in late sum-

mer to feed. Following the heatwave, the

prey supply declined sharply and right

whales began foraging elsewhere, leading

to a complex chain of events that chal-

lenge our ability to manage this species

and the human activities that threaten

it (Davies and Brillant, 2019). Because

of the timeframe of oceanographic sup-

ply and C. fnmarchicus ontogeny, these

FIGURE 1. (a) Location of the Jordan Basin buoy (dot) and the general path of Labrador Slope Water into the Gulf of Maine superimposed on the winter

2024 sea surface temperature anomaly (January–March Optimum Interpolation Sea Surface Temperature [OISST] anomaly from the 30-year mean, °C).

(b) Annual mean temperature and salinity conditions at 250 m depth in Jordan Basin. Gray lines show the range of monthly mean values. (c) Monthly

temperature and salinity anomalies at 250 m depth in Jordan Basin. Missing values are times when no data were collected by the instrumentation.

°C

Oceanography | Vol. 37, No. 3

late summer declines were preceded by

spring shifs in deep-water conditions

(Record et  al., 2019). Tere is no guar-

antee that a return to pre-heatwave con-

ditions will resupply C. fnmarchicus to

the eastern Gulf of Maine, as the rela-

tive importance of supply versus local

dynamics is still uncertain (Pershing and

Kemberling, 2024). However, in either

case, it is a shif that we should be look-

ing out for, given the sensitive state of

this management issue. Targeted whale

or zooplankton surveys would be help-

ful, as well as coordinated communica-

tion among those with eyes on the water

for opportunistic sightings.

AMERICAN LOBSTERS. Deep-water con-

ditions in spring strongly infuence the

timing of molt and inshore migration and

rates of post-settlement survival (Goode

et  al., 2019) of the American lobster—

a species that supports a nearly billion-

dollar fshery. Changes in this phenol-

ogy can drive big swings in prices, and

because of the strong dependence on

temperature, deep waters in spring are

predictive of molt timing (Mills et  al.,

2017). Based on the predictive power of

spring bottom temperatures, a success-

ful forecasting strategy was developed,

but operational forecasts were stopped

at the request of the industry (Pershing

et  al., 2018). Deep-water temperatures

in the coastal zone have not yet cooled

to pre-heatwave conditions, but they are

getting close. Such a signifcant shif in

deep-water dynamics should be moni-

tored for its efects on stock dynamics. In

addition to ongoing buoy observations,

opportunistic water column profles

or bottom-moored thermistors would

fll gaps and give a more detailed map

of these dynamics.

KELP FORESTS. Deep-water conditions

also infuence the thermodynamics of

coastal waters where kelp forests prevail.

Such forests—which foster biodiversity,

fuel nearshore food webs, and underpin an

aquaculture industry—were widespread

at the turn of the twenty-frst century.

However, in response to unusually warm

springs and summers, forests in the

southwestern Gulf have since collapsed,

and forests in the northeast have become

less lush, with a loss of subarctic taxa

(Suskiewicz et  al., 2024). A tempo-

rary return to pre-heatwave conditions

is unlikely to foster recovery of south-

ern forests because they have shifed to a

novel, alternative stable state, but cooler

conditions may bring a banner year for

kelp recruitment in the north, given the

positive efects of “cold-priming” on kelp

reproduction and recruitment (Liesner

et al., 2020; Gauci et al., 2022). Te poten-

tial efects of cooling on kelp abundance

may take one or more years to manifest, so

continual ecosystem monitoring will be

necessary for understanding the impacts

of deep-water cooling on forest resilience.

Learning how to use oceanographic

conditions as early warnings is a multi-

decadal learning process. Ocean and cli-

mate surprises, generally defned as mis-

matches between the expectations and

the realities of changing conditions, have

the potential to drive changes in human

and natural systems (Pershing et  al.,

2019), and they have played a particu-

larly important role in the Gulf of Maine

(Record et al., 2023). If we hope to use

real-time oceanographic measurements

to prepare for future events, as some have

suggested (Link et al., 2023), we are obli-

gated to report signifcant events as they

unfold. We don’t mean to imply that this

oceanographic shif will return the Gulf of

Maine to a pre-heatwave ecosystem—that

is probably impossible in a world with

426 ppm CO2 concentrations (and ris-

ing). However, this type of oceanographic

change has had major efects in the past,

and we should be paying close attention

this summer and fall as events unfold.

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