If you google “ocean acidification,” the first 3 websites
presented according to “Google’s
truth rankings” are: 1) Wikipedia, 2) NOAA’s PMEL
site featuring the graphic cartoon shown below with a dissolving pteropod shell
(a sea butterfly) as the icon of ocean acidification, and 3) the Smithsonian’s Ocean Portal site similarly featuring a
dissolving sea butterfly shell. However NOAA’s illustration incorrectly implies
shells are dissolving near the surface due to invading anthropogenic
atmospheric CO2. As will be shown, the depiction would be far more accurate if
it was turned upside down, so that the downward arrows point upwards to
illustrate shell dissolution happens when old carbon stored at depth is
upwelled to the surface. Furthermore the horizontal depiction of extreme
dissolution illustrated by their intact (green) sea butterfly shell dissolving
into an extremely shriveled shell (red), rarely if ever happens in the ocean’s
upper layers. Surface waters are supersaturated regards calcium carbonates.
Although upwelling causes some near surface dissolution, dead sea-butterfly
shells only experience such extreme dissolution when they sink to depths
containing ancient corrosive waters.
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| NOAA's Upside Down Cartoon of Sea Butterfly SHell Dissolution |
As for most organisms, pteropod populations fluctuate over
the short term. But research
finds no significant long-term trends in pteropod abundance. Nonetheless NOAA’s
Nina Bednarsek has been preparing a preliminary
report arguing sea butterflies should be listed as endangered and NOAA’s
cartoon appears to be an attempt to gain support for her claims. To warrant
endangered status, Bednarsek presents a hypothesis that increasing CO2 has
reduced critical pteropod habitat by raising the depth of calcium carbonate
saturation horizons. The threshold
above which high concentrations of carbonate ions (CO32-)
promote abiotic calcium carbonate precipitation but below which favors
dissolution, is referred to as the saturation horizon. The horizon is
quantified as 1, and higher numbers characterize supersaturated water that
favor calcification. As seen below in Fig 10 from Jiang 2016,
most of the globe’s surface oceans are supersaturated.
 |
| Global calicum carbonate supersaturation from Jiang 2016 |
Bednarsek assumes anthropogenic carbon is mostly
accumulating near the surface based on modeling results. However as detailed in
Part 2, all ocean acidification
models are deeply flawed based on an incorrect assumption that CO2 enters the
ocean and is then transported like an inert
tracer. But CO2 is not inert! When CO2 first invades sunlit surface waters,
it indeed dissolves into 3 forms of inorganic carbon (DIC) and lowers pH (DIC
is discussed in How
Gaia and Coral Reefs Regulate Ocean pH). But in contrast to those models,
DIC is rapidly assimilated into particulate organic carbon via photosynthesis,
which raises pH. Particulate
organic carbon (alive or dead) is heavy, and if not consumed and recycled, it
sinks. For millions of years, this process created and maintained a DIC/pH
gradient with high pH/low DIC near the surface and low pH/higher DIC at depth.
Gravity drives the biological pump and removes a significant
proportion of organic carbon (assimilated from both natural and anthropogenic
carbon). That carbon is transported to depths where it can be harmlessly
sequestered for hundreds to thousands of years. However NOAA’s models fail to
account for the biological pump, based on the narrow belief that carbon storage
is strictly “a chemical and physical response to rising atmospheric CO2” (Sabine
2010). In contrast to Bednarsek’s anthropogenic hypothesis, an increase in
the assimilation of CO2 and an efficient biological pump can prevent a decrease
in surface pH and calcium carbonate saturation. In fact experiments show CO2 is
often a limiting nutrient. Mesocosm
experiments found that when atmospheric CO2 was increased, primary
production by plankton community consumed 39% more DIC. When primary production
increases, more carbon is shuttled to depth.
Meet the Sea Butterflies
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| Sea Butterfly Limacina helicina |
Sea butterflies are pteropods, a kind of snail exclusively
living in the open ocean. A cubic meter of seawater may contain 50 to several
thousand individuals. Unlike their terrestrial relatives that plod along on a
slimy “foot”, pteropods transformed their foot into a pair of wings to “fly”
through ocean waters.
Pteropods are divided into two main groups: sea butterflies
with extremely thin, coiled or cone-shaped shells, and “naked” sea angels that
evolved a way to shut off their shell-making genes completely when larvae. Sea
butterflies feed by suspending themselves in the water column and extruding a
web of mucus that passively catches sinking plankton and other organic
particles. In contrast sea angels specialized to aggressively prey on sea
butterflies. Abandoning their shell suggests whatever benefits a shell may have
provided, those benefits were not critical, but losing the shell increased
their maneuverability for the hunt. When encountering a sea butterfly, the
bizarre sea angel shoots out tentacles from its head. The tentacles dig into
the butterflies’ shells and if properly grasped, the tentacles give the angel
leverage to extract the butterfly from its shell opening. Below is a 2-minute
video below of a sea angel attacking a sea butterfly (not in English). Fish and whales also feed
on sea butterflies, gulping mouthfuls at a time. So overall the butterfly’s shell
offers precious little protection from their main predators.
While Bednarsek fears pteropods might not adapt quickly
enough to rising atmospheric CO2, pteropod behavior argues they are already
well adapted. Sea butterflies prefer to graze in highly productive regions
generated by nutrient rich but corrosive upwelled waters. Accordingly upwelled
regions are typically key reproductive habitat supporting an abundance of
juveniles. Sea butterflies are most abundant in the upper 50 meters of the
ocean, grazing on abundant phytoplankton. However depending on the species, the
population, and location, most sea butterflies migrate daily to depths of 100
meters or more (sometimes below 500 meters) where pH can drop to around 7.6 and
waters become corrosive. Similarly they will migrate to deeper more “acidic”
depths to over-winter. And although tropical waters are the most supersaturated
and the most unlikely to promote shell dissolution, pteropods are least
abundant in those tropical waters. In contrast they are very abundant in
marginally supersaturated waters around Antarctica.
All calcifying organisms have a protective organic layer
that minimizes sensitivity to any changes in seawater pH and all isolate their
calcifying chambers from ambient water conditions. Mollusks like clams, oysters
and snails have a protective outer layer of organic tissue called the
periostracum. The mollusk periostracum has allowed them to colonize the acidic
depths of ocean floors, colonize freshwater lakes and streams where pH falls to
truly acidic levels below 6.0, and to colonize the flanks of submerged
volcanoes where escaping CO2 naturally lowers the pH between 7.3 and 5.39.
Single cell foraminifera and coccolithophorids have some of
the thinnest organic layers that effectively prevent dissolution, and the
petite sea butterfly has one of the thinnest mollusk periostraca. How well it
protects the sea butterfly has created a debate between Bednarsek and other
pteropod researchers.
Bednarsek argues the sea butterfly’s thin periostracum, especially in
juveniles, offers very little to no protection from low pH water suggesting
they are very susceptible to life threatening shell dissolution. In contrast
other researchers argue shell dissolution occurs when the periostracum is
damaged. During the sea butterflies’ short life, which can be less than a year,
they are under constant attacks from predators like sea angels that can damage
their periostracum. There also exists a whole range of
shell-inhabiting/shell-digesting organisms from bacteria to sponges and worms
(aka the epibiont) that drill through a mollusk’s periostracum. Thus
researchers argue when the periostracum remains intact, “the shell appears
pristine with no sign of dissolution”, even when exposed to undersaturated
waters. Only the damaged shells showed dissolution when exposed to
undersaturated water. Based on observations, they concluded sea butterflies
“are perhaps not as vulnerable to
ocean acidification as previously claimed, at least not from direct shell dissolution.”
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| Dissolution of Sea Butterfly Shell from Bednarsek 2014 |
Furthermore to counteract shell dissolution in damaged
areas, sea butterflies rapidly repair their shells by adding more calcium
carbonate to the inside of the shell. Biogenic calcification happens at much
greater rates than dissolution, and such rapid repair mechanisms would be
expected for an animal seeking low pH upwelled waters to graze.
Ironically Bednarsek’s electron microscope images of
corroded sea butterfly shells, provide evidence that supports her detractors.
The shell (Figure 2 above) from Bednarsek’s
2014 paper, shows severe dissolution (labeled “b”) on the innermost whorls,
similar to her other images (not shown here) showing widespread dissolution on
juvenile shells. However despite dissolution during its juvenile stage, the
snail clearly survived and continued to grow. The subsequent growth shows very
little dissolution (labeled “a”). That suggests two possible scenarios that are
not mutually exclusive. The snail’s exposure to corrosive waters was limited to
short-term episodic upwelling during its earliest years, and was an
insignificant cost of grazing in highly productive waters. Or if corrosive
conditions continued, then the more developed periostracum protected the shell
from further dissolution. The small area of severe dissolution within the
section of unharmed shell (the patch to the right of region b) further supports
the argument that dissolution only happens where there is damage. Otherwise, if
the periostracum provided little protection, then the whole region would have
suffered dissolution not just the isolated patch. Thus life-threatening
dissolution is just conjecture, and as Bednarsek later admits,
“dissolution-driven mortality in pteropods has not been directly confirmed.”
Catastrophic Dissolution?
Long before the politics of climate wars emerged, Mark Twain
quipped, “There is something fascinating
about science. One gets such wholesale returns of conjecture out of such a
trifling investment of fact.”
Indeed the oft-cited Orr
2005 “ocean acidification” paper is an iconic example illustrating Twain’s
observation. Orr et al examined just 14 living sea butterflies (Clio pyramidata, see photograph below),
captured in the subarctic Pacific. Orr exposed them for 48 hours to
experimentally induced under-saturated water that he predicted would occur in
the future around Antarctica due to rising atmospheric CO2. All specimens
survived. However scanning electron microscopy revealed etching on their
shells.
Although it is highly unlikely such minor etching would be
of any consequence, Orr 2005 jumped to hypothesizing that pteropod species
“will not be able to adapt quickly enough to live in the undersaturated
conditions”. Orr 2005 lamented rising atmospheric CO2 would reduce pteropod
habitat and survival, leading to ecosystem collapse in polar regions. He
speculated arctic pteropods could be forced southward to warmer waters that
were more saturated. Due to the butterfly’s imagined extirpation via
dissolution, he predicted sea butterfly predators such as sea angels, fish and
whales would all suffer. Such was their wholesale catastrophic conjecture, published
in a top journal, based on etching in 14 specimens.
Observed Dissolution due to Ancient CO2 Enriched Waters
Nina Bednarsek followed with a 2012 paper
in which she too attributed shell dissolution of a sea butterfly (Limacina
helicina) to increasing anthropogenic CO2. Media outlets promoted her
conclusions in articles like Science Daily’s “First
Evidence Of Ocean Acidification Affecting Live Marine Creatures In The Southern
Ocean.” Unfortunately the term “ocean
acidification” is indiscriminately used to describe any reduction of pH even if
naturally induced by upwelling.
On her cruise through the Scotia Sea (just north of the
Antarctic peninsula), Bednarsek collected snails at depths of 200 meters from 6
different stations. Snails at five stations showed no evidence of shell
dissolution. All stations exhibited supersaturated surface waters. Her shell
dissolution was limited to just one station.
All stations experienced upwelling and Bednarsek
acknowledged, “these upwelled waters are
approximately 1000 years old”. Thousand-year old water means it had not
contacted the surface for 1000 years, and those deep waters had not absorbed
any anthropogenic CO2. The water’s corrosiveness was due to a millennium of
decomposing sunken organic matter that increasingly released CO2 and lowered
pH. Still she conjectured the observed dissolution was due to anthropogenic
CO2.
Because winds will mix supersaturated surface waters with
corrosive upwelled waters in the upper 200 meters, mixing can neutralize any
corrosive effects of upwelled waters. To attribute her observed dissolution to
anthropogenic CO2, Bednarsek argued recent invasions of anthropogenic CO2 into
the surface water had lowered its surface pH to such an extent, mixing no
longer counteracted the low pH of upwelled water. It was a reasonable
hypothesis, however there was no evidence to support it.
At the one and only station where snails had experienced
dissolution, surface waters were far more supersaturated than at any other
station. In contrast to Bednarsek’s narrative, that station’s supersaturated
waters should have had the most neutralizing effect. Her anthropogenic
attribution was simply not consistent with observations. More parsimoniously
either that one station experienced greater upwelling, or there was less wind
mixing to deepen the neutralizing effect. It is puzzling why peer-review or the
editors at Nature allowed her unsupported anthropogenic conclusion to be
published.
In 2014, NOAA
News promoted another paper
by Bednarsek about dissolving sea butterfly shells with the headlines, “NOAA-Led Researchers Discover Ocean Acidity
Is Dissolving Shells Of Tiny Snails Off The U.S. West Coast.” NOAA’s press release explicitly stated
the term “ocean acidification” described the process of ocean water becoming
corrosive as a result of absorbing nearly a third of the carbon dioxide
released into the atmosphere from human sources.” In contrast, her observed
shell dissolution only happened where upwelling was the greatest, along Oregon
and northern California. Along
southern California where upwelling was minimal, Bednarsek found no
dissolution. If acidification was due to atmospheric CO2, we would expect a
more uniform pattern of dissolution. But again Bednarsek set forth a scenario
to blame anthropogenic CO2, arguing upwelled waters had been directly
“acidified” by anthropogenic CO2.
She speculated the upwelled waters had been near the surface
50 years ago, during which time it equilibrated with the 1960s atmosphere.
Those waters then sank to depths of 80 to 200 meters, and were now upwelled to
the surface. However the problem with this scenario is the source of upwelled
waters along the California Oregon coast can be traced back to the California
Undercurrent. The California Undercurrent originates in equatorial regions
primarily at depths 100 to 200 meters and flows poleward beneath the
equatorward flowing California Current. The undercurrent is supplied with low
pH, low oxygen, and high inorganic carbon waters from the eastern tropical
Pacific. Due to the accumulation of ancient carbon, the eastern tropical
Pacific contains some of the oldest waters on earth and more than any other
region on earth ventilates tremendous amounts of CO2 from the ocean into the
air.
Studies
of the changing characteristics of the California Undercurrent conclude all its
“changes are consistent with an increasing influence of Pacific equatorial
waters” over the past decades. During a negative Pacific Decadal
Oscillation (PDO) or a La Nina, research
shows the California Undercurrent acquires increased amounts of those ancient
waters and upwelling is stronger. Although those studies did not consider
possible anthropogenic contributions, the trends in lower oxygen and lower pH
were explained by natural increased mixing of older water masses. That mixing
trend could represent decadal variability or the centuries long increasing
upwelling trend documented under the Peru Current (detailed in Part 2).
The same corrosive upwelling associated with Bednarsek’s
sea butterfly dissolution was also responsible for the corrosive waters that
oyster fisherman unwittingly pumped into larval-rearing tanks in 2008-9. (To
make matters worse, oyster fishermen pumped water in the early morning when
nighttime respiration further acidified the water). And consistent with
multidecadal variability, during the previous negative PDO from 1940 to the
late 70s, corrosive upwelled waters had similarly reduced survival of larval
oysters in those bays. Clearly natural oscillations episodically upwell more
nutrient-rich, oxygen-poor corrosive waters. And because oceans contain the
greatest concentration of inorganic carbon by far, the question remains has
anthropogenic CO2 significantly exacerbated the corrosiveness of natural
upwelling? In contrast, NOAA’s Richard Feely believes anthropogenic CO2 is the
primary factor. Thus he answers that question with an upside down perspective, stating
upwelling “exacerbates [anthropogenic] ocean acidification”. And as detailed in
part 2, NOAA's models have an upside down representation of carbon
distribution.
The sea butterfly joins the parade of icons like polar
bears, penguins,
pika,
mangroves
and Parmesan’s
butterflies where the effects of natural climate variability or direct
human interference are obscured and falsely promoted as catastrophic climate
change.