The effect of climate change on marine life and mammals is a growing concern. Many of the effects of global warming
are currently unknown due to unpredictability, but many are becoming
increasingly evident today. Some effects are very direct such as loss of habitat,
temperature stress, and exposure to severe weather. Other effects are
more indirect, such as changes in host pathogen associations, changes in
body condition because of predator–prey interaction, changes in
exposure to toxins and CO 2 emissions, and increased human interactions.
Despite the large potential impacts of ocean warming on marine
mammals, the global vulnerability of marine mammals to global warming is
still poorly understood.
It has been generally assumed that the Arctic marine mammals were
the most vulnerable in the face of climate change given the substantial
observed and projected decline in Arctic sea ice
cover. However, the implementation of a trait-based approach on
assessment of the vulnerability of all marine mammals under future
global warming has suggested that the North Pacific Ocean, the Greenland Sea and the Barents Sea host the species that are most vulnerable to global warming. The North Pacific has already been identified as a hotspot for human threats for marine mammals
and now is also a hotspot of vulnerability to global warming. This
emphasizes that marine mammals in this region will face double jeopardy
from both human activities (e.g., marine traffic, pollution and offshore
oil and gas development) and global warming, with potential additive or
synergetic effect and as a result, these ecosystems face irreversible consequences for marine ecosystem functioning. Consequently the future conservation plans should therefore focus on these regions.
Potential effects
Marine mammals have evolved to live in oceans, but climate change is affecting their natural habitat. Some species may not adapt fast enough, which might lead to their extinction.
Ocean warming
The
illustration of temperature changes from 1960 to 2019 across each ocean
starting at the Southern Ocean around Antarctica (Cheng et. al., 2020)
During the last century, the global average land and sea surface temperature has increased due to an increased greenhouse effect from human activities.
From 1960 to through 2019, the average temperature for the upper 2000
meters of the oceans has increased by 0.12 degree Celsius, whereas the
ocean surface has warmed up to 1.2 degree Celsius from the
pre-industrial era.
Marine organisms usually tend to encounter relatively stable
temperatures compared with terrestrial species and thus are likely to be
more sensitive to temperature change than terrestrial organisms.
Therefore, the ocean warming will lead to increased species migration,
as endangered species look for a more suitable habitat. If sea
temperatures continue to rise, then some fauna may move to cooler water
and some range-edge species may disappear from regional waters or
experienced a reduced global range.
Change in the abundance of some species will alter the food resources
available to marine mammals, which then results in marine mammals’
biogeographic shifts. Additionally, if a species cannot successfully
migrate to a suitable environment, unless it learns to adapt to rising
ocean temperatures, it will face extinction.
Sea level rise is also important when assessing the impacts of
global warming on marine mammals, since it affects coastal environments
that marine mammals species rely.
Primary productivity
Changes in temperatures will impact the location of areas with high primary productivity. Primary producers, such as plankton,
are the main food source for marine mammals such as some whales.
Species migration will therefore be directly affected by locations of
high primary productivity. Water temperature changes also affect ocean
turbulence, which has a major impact on the dispersion of plankton and
other primary producers. Due to global warming and increased glacier melt, thermohaline circulation
patterns may be altered by increasing amounts of freshwater released
into oceans and, therefore, changing ocean salinity. Thermohaline
circulation is responsible for bringing up cold, nutrient-rich water
from the depths of the ocean, a process known as upwelling.
Ocean acidification
Change in pH since the beginning of the industrial revolution. RCP 2.6 scenario is "low CO2 emissions" . RCP 8.5 scenario is "high CO2 emissions", the path we are currently on. Source: J. P. Gattuso et al., 2015
About a quarter of the emitted CO2, about 26 million tons is absorbed by the ocean every day. Consequently, the dissolution of anthropogenic carbon dioxide (CO2)
in seawater causes a decrease in pH which is corresponding to an
increase in acidity of the oceans with consequences for marine biota.
Since the beginning of the industrial revolution, ocean acidity has
increased by 30% (the pH decreased from 8.2 to 8.1). It is projected that the ocean will experience severe acidification under RCP 8.5, high CO2 emission scenario, and less intense acidification under RCP 2.6, low CO2
emission scenario. Ocean acidification will impact marine organisms
(corals, mussels, oysters) in producing their limestone skeleton or
shell. When CO2 dissolves in seawater, it increases protons
(H+ ions) but reduces certain molecules, such as carbonate ions in which
many oysters needed to produce their limestone skeleton or shell.
The shell and the skeleton of these species may become less dense or
strong. This also may make coral reefs become more vulnerable to storm
damage, and slow down its recovery. In addition, marine organisms may
experience changes in growth, development, abundance, and survival in
response to ocean acidification
Sea ice changes
Sea ice, a defining characteristic of polar marine environment, is
changing rapidly which has impacts on marine mammals. Climate change
models predict changes to the sea ice leading to loss of the sea ice
habitat, elevations of water and air temperature, and increased
occurrence of severe weather. The loss of sea ice habitat will reduced
the abundance of seal prey for marine mammals, particularly polar bears.
Initially, polar bears may be favored by an increase in leads in the
ice that make more suitable seal habitat available but, as the ice thins
further, they will have to travel more, using energy to keep in contact
with favored habitat.
There also may be some indirect effect of sea ice changes on animal
heath due to alterations in pathogen transmission, effect on animals on
body condition caused by shift in the prey based/food web, changes in
toxicant exposure associated with increased human habitation in the
Arctic habitat.
Increase
frequency of Hypoxia Occurrence in the entire Baltic Sea calculated as
the number of profiles with recorded hypoxia relative to the total
number of profiles (Conley et. al., 2011)
Hypoxia
Hypoxia
occurs in the variety of coastal environment when the dissolved of
oxygen (DO) is depleted to a certain low level, where aquatic organisms,
especially benthic fauna, become stressed or die due to the lack of
oxygen.
Hypoxia occurs when the coastal region enhance Phosphorus release from
sediment and increase Nitrate (N) loss. This chemical scenario supports
favorable growth for cyanobacteria which contribute to the hypoxia and
ultimately sustain eutrophication. Hypoxia degrades an ecosystem by damaging the bottom fauna habitats,
altering the food web, changing the nitrogen and phosphate cycling,
decreasing fishery catch, and enhancing the water acidification.
There were 500 areas in the world with reported coastal hypoxia in
2011, with Baltic Sea contains the largest hypoxia zone in the world. These
numbers are expected to increase due to the worsening condition of
coastal areas caused by the excessive anthropogenic nutrient loads that
stimulate intensified eutrophication. The rapidly changing climate in
particularly, global warming, also contributes to the increase of
Hypoxia occurrence that damaging marine mammals and marine/coastal
ecosystem.
Species impacted
Polar bears
A polar bear waiting in the Fall for the sea ice to form.
Polar bears are one of many Arctic marine mammals at risk of population decline due to climate change. When carbon dioxide is released into the atmosphere, a greenhouse
like effect occurs, warming the climate. For polar bears and other
Arctic marine mammals, rising temperature is the changing the sea ice
formations that they rely on to survive. In the circumpolar north, the Arctic sea ice is a dynamic ecosystem.
The levels of sea ice extent varies by season. While some areas
maintain year-round ice, others only have ice on a seasonal basis. The
amount of permanent sea ice is decreasing with global temperature
increases. Climate change is causing slower formations of sea ice,
quicker decline and thinner ice sheets. Polar bears and other Arctic
marine mammals are losing their habitat and food sources in result of
the sea ice decline.
Polar bears rely on seals as their main food source.
Although polar bears are strong swimmers, they are not successful at
catching seal underwater, therefore polar bears are ambush predators.
When they hunt seals, they wait at seal breathing hole to ambush and
haul out their prey onto the sea ice for feeding. With slower sea ice
formations, thinner ice sheets and shorter winter seasons, polar bears
are having less opportunity for optimal hunting grounds. Polar bears are
facing pressures to swim further to gain access to food. This requires
more calories spent to obtain calories to sustain their body conditions
for reproduction and survival. Researchers use body condition charts to
track polar bear population health and reproductive potential. Trends suggest 12 out of 19 sub populations of polar bears are declining or data deficient.
Polar bears also rely on sea ice to travel, mate and female polar
bears usually choose to den up on the sea ice during denning season. The sea ice is becoming less stable, forcing pregnant female polar bears to choose less optimal locations for denning. These aspects are known to result in lower reproduction rates and smaller cub years.
Dolphins
Dolphins
are marine mammals with broad geographic extent, making them
susceptible to climate change in various ways. The most common effect of
climate change on dolphins is the increasing water temperatures across
the globe. This has caused a large variety of dolphin species to
experience range shifts, in which the species move from their typical
geographic region to warmer waters.
In California, the 1982-83 El Niño warming event caused the near-bottom spawning market squid to leave southern California, which caused their predator, the pilot whale, to also leave. As the market squid returned six years later, Risso's dolphins came to feed on the squid. Bottlenose dolphins expanded their range from southern to central California, and stayed even after the warming event subsided. The Pacific white-sided dolphin has had a decline in population in the southwest Gulf of California,
the southern boundary of their distribution. In the 1980s they were
abundant with group sizes up to 200 across the entire cool season. Then,
in the 2000s, only two groups were recorded with sizes of 20 and 30,
and only across the central cool season. This decline was not related to
a decline of other marine mammals or prey, so it was concluded to have
been caused by climate change as it occurred during a period of warming.
Additionally, the Pacific white-sided dolphin had an increase in
occurrence on the west coast of Canada from 1984 to 1998.
In the Mediterranean, sea surface temperatures have increased, as well as salinity, upwelling intensity, and sea levels. Because of this, prey resources have been reduced causing a steep decline in the short-beaked common dolphin Mediterranean subpopulation, which was deemed endangered in 2003. This species now only exists in the Alboran Sea, due to its high productivity, distinct ecosystem, and differing conditions from the rest of the Mediterranean.
In northwest Europe, many dolphin species have experienced range
shifts from the region’s typically colder waters. Warm water dolphins,
like the short-beaked common dolphin and striped dolphin, have expanded north of western Britain and into the northern North Sea, even in the winter, which may displace the white-beaked and Atlantic white-sided dolphin
that are in that region. The white-beaked dolphin has shown an increase
in the southern North Sea since the 1960s because of this. The rough-toothed dolphin and Atlantic spotted dolphin may move to northwest Europe. In northwest Scotland,
white-beaked dolphins (local to the colder waters of the North
Atlantic) have decreased while common dolphins (local to warmer waters)
have increased from 1992-2003. Additionally, Fraser’s dolphin, found in tropical waters, was recorded in the UK for the first time in 1996.
River dolphins
are highly affected by climate change as high evaporation rates,
increased water temperatures, decreased precipitation, and increased acidification occur.
River dolphins typically have a higher densities when rivers have a lox
index of freshwater degradation and better water quality. Specifically looking at the Ganges river dolphin,
the high evaporation rates and increased flooding on the plains may
lead to more human river regulation, decreasing the dolphin population.
As warmer waters lead to a decrease in dolphin prey, this led to
other causes of dolphin population decrease. In the case of bottlenose
dolphins, mullet
populations decrease due to increasing water temperatures, which leads
to a decrease in the dolphins’ health and thus their population. At the Shark Bay World Heritage Area in Western Australia, the local Indo-Pacific bottlenose dolphin
population had a significant decline after a marine heatwave in 2011.
This heatwave caused a decrease in prey, which led to a decline in
dolphin reproductive rates as female dolphins could not get enough
nutrients to sustain a calf.
The resultant decrease in fish population due to warming waters has
also influenced humans to see dolphins as fishing competitors or even
bait. Humans use dusky dolphins as bait or are killed off because they consume the same fish humans eat and sell for profit. In the central Brazilian Amazon alone, approximately 600 pink river dolphins are killed each year to be used as bait. Another side effect of increasing water temperatures is the increase in toxic algae blooms, which has caused a mass die-off of bottlenose dolphins.
The Sabatier reaction or Sabatier process produces methane and water from a reaction of hydrogen with carbon dioxide at elevated temperatures (optimally 300–400 °C) and pressures (perhaps 30 bar) in the presence of a nickelcatalyst. It was discovered by the French chemists Paul Sabatier and Jean-Baptiste Senderens in 1897. Optionally, ruthenium on alumina (aluminium oxide) makes a more efficient catalyst. It is described by the following exothermic reaction.
∆H = −165.0 kJ/mol
There is disagreement on whether the CO2 methanation occurs by first associatively adsorbing an adatom
hydrogen and forming oxygen intermediates before hydrogenation or
dissociating and forming a carbonyl before being hydrogenated.
∆H = −206 kJ/mol
CO methanation is believed to occur through a dissociative mechanism
where the carbon oxygen bond is broken before hydrogenation with an
associative mechanism only being observed at high H2 concentrations.
Methanation reaction over different carried metal catalysts including Ni, Ru and Rh has been widely investigated for the production of CH4 from syngas and other power to gas initiatives. Nickel is the most widely used catalyst due to its high selectivity and low cost.
Applications
Creation of synthetic natural gas
Methanation is an important step in the creation of synthetic or substitute natural gas (SNG).
Coal or wood undergo gasification which creates a producer gas that
must undergo methaneation in order to produce a usable gas that just
needs to undergo a final purification step.
The first commercial synthetic gas plant opened in 1984 and is the Great Plains Synfuel plant in Beulah, North Dakota.
It is still operational and produces 1500 MW worth of SNG using coal as
the carbon source. In the years since its opening, other commercial
facilities have been opened using other carbon sources such as wood
chips.
In France, the AFUL Chantrerie, located in Nantes, started in
November 2017 the demonstrator MINERVE. This methanation unit of 14 Nm3 /
day was carried out by Top Industrie, with the support of Leaf. This
installation is used to feed a CNG station and to inject methane into
the natural gas boiler.
It has been seen in a renewable-energy-dominated energy system to
use the excess electricity generated by wind, solar photovoltaic,
hydro, marine current, etc. to make hydrogen via water electrolysis and
the subsequent application of the Sabatier reaction to make methane
In contrast to a direct usage of hydrogen for transport or energy storage applications, the methane can be injected into the existing gas network, which in many countries has one to two years of storage capacity.
The methane can then be used on demand to generate electricity (and
heat—combined heat and power) overcoming low points of renewable energy
production. The process is electrolysis of water by electricity to
create hydrogen (which can partly be used directly in fuel cells) and
the addition of carbon dioxide CO2 (Sabatier process) to create methane. The CO2 can be extracted from the air or fossil fuel waste gases by the amine process, amongst many others. It is a low-CO2 system, and has similar efficiencies of today's energy system.
A 6 MW power-to-gas plant went into production in Germany in 2013, and powered a fleet of 1500 Audi A3s.
Ammonia synthesis
In ammonia production CO and CO2 are considered poisons to most commonly used catalysts.
Methanation catalysts are added after several hydrogen producing steps
to prevent carbon oxide buildup in the ammonia synthesis loop as methane
does not have similar adverse effects on ammonia synthesis rates.
International Space Station life support
Oxygen generators on board the International Space Station produce oxygen from water using electrolysis;
the hydrogen produced was previously discarded into space. As
astronauts consume oxygen, carbon dioxide is produced, which must then
be removed from the air and discarded as well. This approach required
copious amounts of water to be regularly transported to the space
station for oxygen generation in addition to that used for human
consumption, hygiene, and other uses—a luxury that will not be available
to future long-duration missions beyond low Earth orbit.
NASA
is using the Sabatier reaction to recover water from exhaled carbon
dioxide and the hydrogen previously discarded from electrolysis on the
International Space Station and possibly for future missions.
The other resulting chemical, methane, is released into space. As half
of the input hydrogen becomes wasted as methane, additional hydrogen is
supplied from Earth to make up the difference. However, this creates a
nearly-closed cycle between water, oxygen, and carbon dioxide which only
requires a relatively modest amount of imported hydrogen to maintain.
Ignoring other results of respiration, this cycle looks like:
The loop could be further closed if the waste methane was separated into its component parts by pyrolysis, the high efficiency (up to 95% conversion) of which can be achieved at 1200 °C:
The released hydrogen would then be recycled back into the Sabatier reactor, leaving an easily removed deposit of pyrolytic graphite.
The reactor would be little more than a steel pipe, and could be
periodically serviced by an astronaut where the deposit is chiselled
out.
Alternatively, the loop could be partially closed (75% of H2 from CH4 recovered) by incomplete pyrolysis of the waste methane while keeping the carbon locked up in gaseous form as acetylene:
The Bosch reaction is also being investigated by NASA for this purpose and is:
The Bosch reaction would present a completely closed hydrogen and
oxygen cycle which only produces atomic carbon as waste. However,
difficulties maintaining its temperature of up to 600 °C and properly
handling carbon deposits mean significantly more research will be
required before a Bosch reactor could become a reality. One problem is
that the production of elemental carbon tends to foul the catalyst's
surface (coking), which is detrimental to the reaction's efficiency.
Manufacturing propellant on Mars
The Sabatier reaction has been proposed as a key step in reducing the cost of human mission to Mars (Mars Direct, SpaceX Starship) through in-situ resource utilization. Hydrogen is combined with CO2 from the atmosphere, with methane then stored as fuel and the water side product electrolyzed
yielding oxygen to be liquefied and stored as oxidizer and hydrogen to
be recycled back into the reactor. The original hydrogen could be
transported from Earth or separated from Martian sources of water.
Importing hydrogen
Importing a small amount of hydrogen avoids searching for water and just uses CO2 from the atmosphere.
"A variation of the basic Sabatier methanation reaction may be
used via a mixed catalyst bed and a reverse water gas shift in a single
reactor to produce methane from the raw materials available on Mars,
utilising carbon dioxide in the Martian atmosphere. A 2011 prototype
test operation that harvested CO2 from a simulated Martian atmosphere and reacted it with H2,
produced methane rocket propellant at a rate of 1 kg/day, operating
autonomously for 5 consecutive days, maintaining a nearly 100%
conversion rate. An optimised system of this design massing 50 kg "is
projected to produce 1 kg/day of O2:CH4 propellant
... with a methane purity of 98+% while consuming ~17 kWh per day of
electrical power (at a continuous power of 700 W). Overall unit
conversion rate expected from the optimised system is one tonne of propellant per 17 MWh energy input."
Stoichiometry issue with importing hydrogen
The stoichiometric ratio of oxidiser and fuel is 2:1, for an oxygen:methane engine:
However, one pass through the Sabatier reactor produces a ratio of only 1:1. More oxygen may be produced by running the water-gas shift reaction (WGSR) in reverse (RWGS), effectively extracting oxygen from the atmosphere by reducing carbon dioxide to carbon monoxide.
Another option is to make more methane than needed and pyrolyze
the excess of it into carbon and hydrogen (see above section), where the
hydrogen is recycled back into the reactor to produce further methane
and water. In an automated system, the carbon deposit may be removed by
blasting with hot Martian CO2, oxidizing the carbon into carbon monoxide (via the Boudouard reaction), which is vented.
A fourth solution to the stoichiometry
problem would be to combine the Sabatier reaction with the reverse
water-gas shift (RWGS) reaction in a single reactor as follows:
This reaction is slightly exothermic, and when the water is electrolyzed, an oxygen to methane ratio of 2:1 is obtained.
Regardless of which method of oxygen fixation is utilized, the overall process can be summarized by the following equation:
Looking at molecular masses, we have produced 16 grams of methane and
64 grams of oxygen using 4 grams of hydrogen (which would have to be
imported from Earth, unless Martian water was electrolysed), for a mass
gain of 20:1; and the methane and oxygen are in the right stoichiometric
ratio to be burned in a rocket engine. This kind of in-situ resource utilization would result in massive weight and cost savings to any proposed manned Mars or sample-return missions.
Global
mean land-ocean temperature change from 1880–2011, relative to the
1951–1980 mean. The black line is the annual mean and the red line is
the 5-year running mean. The green bars show uncertainty estimates. Source: NASA GISS
Animated map exhibiting the world's oceanic waters. A continuous body of water encircling Earth, the World Ocean
is divided into a number of principal areas with relatively free
interchange among them. Five oceanic divisions are usually reckoned: Pacific, Atlantic, Indian, Arctic, and Southern; the last two listed are sometimes consolidated into the first three.
Energy (heat) added to various parts of the climate system due to global warming.
Coasts
There are a number of factors affecting rising sea levels, including the thermal expansion of seawater, the melting of glaciers and ice sheets on land, and possibly human changes to groundwater storage.
The consensus of many studies of coastal tide gauge records is that during the past century sea level has risen
worldwide at an average rate of 1–2 mm/yr reflecting a net flux of heat
into the surface of the land and oceans. Corresponding studies based on
satellite altimetry shows that this rate has increased to closer to 3 mm/yr during the more completely monitored past 20 years. A recent review of the literature
suggests that 30% of the sea level rise since 1993 is due to thermal
expansion and 55% due to continental ice melt, both resulting from
warming global temperatures. In another study, results estimate the heat content of the ocean
in the upper 700 meters has increased significantly from 1955–2010. It
has to be reminded that in this context the usage of the word heat
is extremely improper, as heat cannot be stored in a body but only
exchanged between bodies. Observations of the changes in "heat content"
of the ocean are important for providing realistic estimates of how the
ocean is changing with global warming. An even more recent study of the
contributions to global sea level due to melting of the two large ice
sheets based on satellite measurements of gravity fluctuations suggests
that the melting of these alone are causing global sea level to about
1 mm/yr. In a recent modeling study,
scientists used an earth system model to study several variables of the
ocean, one of which was the "heat content" of the oceans over the past
several hundred years. The earth system model incorporated the
atmosphere, land surface processes, and other earth components to make
it more realistic and similar to observations. Results of their model
simulation showed that since 1500, the ocean "heat content" of the upper
500 m has increased.
The connection between sea level rise and ocean thermal expansion follows from Charles's law
(also known as the law of volumes) put simply states that the volume of
a given mass is proportional to its temperature. This contribution to
sea level is monitored by oceanographers using a succession of
temperature measuring profiling instruments, which is then compiled at
national data centers such as the United States National Oceanographic Data Center. The International Panel on Climate Change
(IPCC) Fifth Assessment Report estimates that the upper ocean (surface
to 750 m deep) has warmed by 0.09 to 0.13 degrees C per decade over the
past 40 years. Other processes important in influencing global sea level include changes to groundwater storage including dams and reservoirs.
Global warming also has an enormous impact with respect to
melting glaciers and ice sheets. Higher global temperatures melt
glaciers such as the one in Greenland,
which flow into the oceans, adding to the amount of seawater. A large
rise (on the order of several feet) in global sea levels poses many
threats. According to the U.S.Environmental Protection Agency (EPA), “such a rise would inundate coastal wetlands and lowlands, erodebeaches, increase the risk of flooding, and increase the salinity of estuaries, aquifers, and wetlands.”
The seasonal cycles are closely linked with the seasonal changes in sea
ice and sea surface temperatures. The timing and amplitude of the
seasonal cycle has been altered by global warming.
Superimposed on the global rise in sea level, is strong regional
and decadal variability which may cause sea level along a particular
coastline to decline with time (for example along the Canadian eastern
seaboard), or to rise faster than the global average. Regions that have
shown a rapid rise in sea level during the past two decades include the
western tropical Pacific and the United States northeastern seaboard.
These regional variations in sea level are the result of many factors,
such as local sedimentation rates, geomorphology, post-glacial rebound, and coastal erosion. Large storm events, such as Hurricane Sandy in the eastern Atlantic, can dramatically alter coastlines and affect sea level rise as well.
Coastal regions would be most affected by rising sea levels. The
increase in sea level along the coasts of continents, especially North America are much more significant than the global average. According to 2007 estimates by the International Panel on Climate Change (IPCC), “global average sea level will rise between 0.6 and 2 feet (0.18 to 0.59 meters) in the next century. Along the U.S. Mid-Atlantic
and Gulf Coasts, however, sea level rose in the last century 5 to 6
inches more than the global average. This is due to the subsiding of
coastal lands.
The sea level along the U.S. Pacific coast has also increased more than
the global average but less than along the Atlantic coast. This can be
explained by the varying continental margins along both coasts; the
Atlantic type continental margin is characterized by a wide, gently
sloping continental shelf, while the Pacific type continental margin
incorporates a narrow shelf and slope descending into a deep trench.
Since low-sloping coastal regions should retreat faster than
higher-sloping regions, the Atlantic coast is more vulnerable to sea
level rise than the Pacific coast.
Society
The rise in sea level along coastal regions carries implications for a wide range of habitats
and inhabitants. Firstly, rising sea levels will have a serious impact
on beaches— a place which humans love to visit recreationally and a
prime location for real estate. It is ideal to live on the coast, due to
a more moderate climate
and pleasant scenery, but beachfront property is at risk from eroding
land and rising sea levels. Since the threat posed by rising sea levels
has become more prominent, property owners and local government have
taken measures to prepare for the worst. For example, “Maine has enacted
a policy declaring that shorefront buildings will have to be moved to
enable beaches and wetlands to migrate inland to higher ground.” Additionally, many coastal states add sand to their beaches to offset shore erosion,
and many property owners have elevated their structures in low-lying
areas. As a result of the erosion and ruin of properties by large storms
on coastal lands, governments have looked into buying land and having
residents relocate further inland.
The seas now absorb much of human-generated carbon dioxide, which then
affects temperature change. The oceans store 93 percent of that energy which helps keep the planet livable by moderating temperatures.
Another important coastal habitat that is threatened by sea level
rise is wetlands, which “occur along the margins of estuaries and other
shore areas that are protected from the open ocean and include swamps,
tidal flats, coastal marshes and bayous.”
Wetlands are extremely vulnerable to rising sea levels, since they are
within several feet of sea level. The threat posed to wetlands is
serious, due to the fact that they are highly productive ecosystems,
and they have an enormous impact on the economy of surrounding areas.
Wetlands in the U.S. are rapidly disappearing due to an increase in
housing, industry, and agriculture, and rising sea levels contribute to
this dangerous trend. As a result of rising sea levels, the outer
boundaries of wetlands tend to erode, forming new wetlands more inland.
According to the EPA, “the amount of newly created wetlands, however,
could be much smaller than the lost area of wetlands— especially in
developed areas protected with bulkheads, dikes, and other structures
that keep new wetlands from forming inland.”
When estimating a sea level rise within the next century of 50 cm (20
inches), the U.S. would lose 38% to 61% of its existing coastal
wetlands.
A rise in sea level will have a negative impact not only on
coastal property and economy but on our supply of fresh water. According
to the EPA, “Rising sea level increases the salinity of both surface
water and ground water through salt water intrusion.” Coastal estuaries and aquifers, therefore, are at a high risk of becoming too saline
from rising sea levels. With respect to estuaries, an increase in
salinity would threaten aquatic animals and plants that cannot tolerate
high levels of salinity. Aquifers often serve as a primary water supply
to surrounding areas, such as Florida's Biscayne aquifer, which receives
freshwater from the Everglades and then supplies water to the Florida
Keys. Rising sea levels would submerge low-lying areas of the
Everglades, and salinity would greatly increase in portions of the
aquifer.
The considerable rise in sea level and the decreasing amounts of
freshwater along the Atlantic and Gulf coasts would make those areas
rather uninhabitable. Many economists predict that global warming will
be one of the main economic threats to the West Coast, specifically in
California. "Low-lying coastal areas, such as along the Gulf Coast, are
particularly vulnerable to sea-level rise and stronger storms—and those
risks are reflected in rising insurance rates and premiums. In Florida,
for example, the average price of a homeowners’ policy increased by 77
percent between 2001 and 2006."
Global issue
Since
rising sea levels present a pressing problem not only to coastal
communities but to the whole global population as well, much scientific
research has been performed to analyze the causes and consequences of a
rise in sea level. The U.S. Geological Survey
has conducted such research, addressing coastal vulnerability to sea
level rise and incorporating six physical variables to analyze the
changes in sea level: geomorphology; coastal slope (percent); rate of
relative sea level rise (mm/yr); shoreline erosion and acceleration
rates (m/yr); mean tidal range (m); and mean wave height (m).
The research was conducted on the various coasts of the U.S., and the
results are very useful for future reference. Along the Pacific coast,
the most vulnerable areas are low-lying beaches, and “their
susceptibility is primarily a function of geomorphology and coastal
slope.”
With regard to research performed along the Atlantic coast, the most
vulnerable areas to sea level rise were found to be along the
Mid-Atlantic coast (Maryland to North Carolina) and Northern Florida,
since these are “typically high-energy coastlines where the regional
coastal slope is low and where the major landform type is a barrier
island.”
For the Gulf coast, the most vulnerable areas are along the
Louisiana-Texas coast. According to the results, “the
highest-vulnerability areas are typically lower-lying beach and marsh
areas; their susceptibility is primarily a function of geomorphology,
coastal slope and rate of relative sea-level rise.”
Many humanitarians and environmentalists believe that political
policy needs to have a bigger role in carbon dioxide reduction. Humans
have a substantial influence on the rise of sea level because we emit
increasing levels of carbon dioxide
into the atmosphere through automobile use and industry. A higher
amount of carbon dioxide in the atmosphere leads to higher global
temperatures, which then results in thermal expansion of seawater and
melting of glaciers and ice sheets.
Ocean currents
The currents
in the world's oceans are a result of varying temperatures associated
with the changing latitudes of our planet. As the atmosphere is warmed
nearest the equator,
the hot air at the surface of our planet is heated, causing it to rise
and draw in cooler air to take its place, creating what is known as circulation cells. This ultimately causes the air to be significantly colder near the poles than at the equator.
Wind patterns associated with these circulation cells drive surface currents
which push the surface water to the higher latitudes where the air is
colder. This cools the water down enough to where it is capable of
dissolving more gasses and minerals, causing it to become very dense in
relation to lower latitude waters, which in turn causes it to sink to
the bottom of the ocean, forming what is known as North Atlantic Deep Water (NADW) in the north and Antarctic Bottom Water (AABW) in the south.
Driven by this sinking and the upwelling that occurs in lower
latitudes, as well as the driving force of the winds on surface water,
the ocean currents act to circulate water throughout the entire sea.
When global warming is added into the equation, changes occur,
especially in the regions where deep water is formed. With the warming
of the oceans and subsequent melting of glaciers and the polar ice caps,
more and more fresh water is released into the high latitude regions
where deep water is formed. This extra water that gets thrown into the
chemical mix dilutes the contents of the water arriving from lower
latitudes, reducing the density of the surface water. Consequently, the
water sinks more slowly than it normally would.
It is important to note that ocean currents provide the necessary nutrients for life to sustain itself in the lower latitudes. Should the currents slow down, fewer nutrients would be brought to sustain ocean life resulting in a crumbling of the food chain and irreparable damage to the marine ecosystem. Slower currents would also mean less carbon fixation.
Naturally, the ocean is the largest sink within which carbon is stored.
When waters become saturated with carbon, excess carbon has nowhere to
go, because the currents are not bringing up enough fresh water to fix
the excess. This causes a rise in atmospheric carbon which in turn causes positive feedback that can lead to a runaway greenhouse effect.
Ocean acidification
The oceans cover approximately 71 percent of the Earth's surface and support a diverse range of ecosystems, which are home to over 50 percent of all the species on the planet. Oceans regulate climate and weather as well as providing nutrition for a vast variety of species, humans included. Covering such an extensive part of the planet has allowed the oceans to absorb a large portion of the carbon dioxide (CO 2) from the atmosphere. This process is part of the carbon cycle in which the fluxes of carbon dioxide (CO 2) in Earth's atmosphere, biosphere and lithosphere are described. Humans have drastically added to the amount of carbon dioxide (CO 2) in the atmosphere through the burning of fossil fuels and the process of deforestation. Oceans work as a sink absorbing excess anthropogeniccarbon dioxide (CO 2). As the oceans absorb anthropogeniccarbon dioxide (CO 2) it breaks down into carbonic acid, a mild acid, this neutralizes the normally alkaline ocean water. As a result, the pH in the oceans is declining (ocean acidification).
In the research surrounding global climate change we are only just
beginning to realize that our oceans can sequester a finite amount of CO 2
before we start seeing impacts on marine life that could lead to
devastating losses. Acidification of our oceans has the potential to
drastically alter life as we know it - from extreme weather patterns and food scarcity to a loss of millions of species from the planet.
The rate at which ocean acidification will occur may be
influenced by the rate of surface ocean warming, because the chemical
equilibria that govern seawater pH are temperature-dependent. Greater seawater warming could lead to a smaller change in pH for a given increase in CO2.
Another effect of global warming on the carbon cycle is ocean acidification.
The ocean and the atmosphere constantly act to maintain a state of
equilibrium, so a rise in atmospheric carbon naturally leads to a rise
in oceanic carbon. When carbon dioxide is dissolved in water it forms
hydrogen and bicarbonate ions, which in turn breaks down to hydrogen and
carbonate ions.
All these extra hydrogen ions increase the acidity of the ocean and
make survival harder for planktonic organisms that depend on calcium
carbonate to form their shells. A decrease in the base of the food chain
will, once again, be destructive to the ecosystems to which they
belong. With fewer of these photosynthetic organisms present at the
surface of the ocean, less carbon dioxide will be converted to oxygen,
thereby allowing the greenhouse gasses to go unchecked.
Steps are being taken to combat the potentially devastating
effects of ocean acidification, and scientists worldwide are coming
together to solve the problem that is known as “global warming’s evil
twin”.
Between 1750 and 2000, surface-ocean pH has decreased by about 0.1, from about 8.2 to about 8.1. Surface-ocean pH has probably not been below 8.1 during the past 2 million years. Projections suggest that surface-ocean pH could decrease by an additional 0.3–0.4 units by 2100. Ocean acidification could threaten coral reefs, fisheries, protected species, and other natural resources of value to society.
Effects of acidification
The
effects of ocean acidification can already be seen and have been
happening since the start of the industrial revolution, with pH levels
of the ocean dropping by 0.1 since the pre-industrial revolution times. An effect called coral bleaching can be seen on the Great Barrier Reef
in Australia, where ocean acidification's effects are already taking
place. Coral bleaching is when unicellular organisms that help make up
the coral begin to die off and leave the coral giving it a white
appearance.
These unicellular organisms are important for the coral to feed and get
the proper nutrition that is necessary to survive, leaving the coral
weak and malnourished. This results in weaker coral that can die more
easily and offer less protection to the organisms that depend on coral
for shelter and protection. Increased acidity can also dissolve an
organism's shell, threatening entire groups of shellfish and zooplankton
and in turn, presenting a threat to the food chain and ecosystem.
Without strong shells, surviving and growing becomes more of a challenge for marine life
that depend on calcified shells. The populations of these animals
becomes smaller and individual members of the species turn weaker. The
fish that rely on these smaller shell constructing animals for food now
have a decreased supply, and animals that need coral reefs for shelter
now have less protection. The effects of ocean acidification decrease
population sizes of marine life and may cause an economic disruption if
enough fish die off, which can seriously harm the global economy as the
fishing industry makes a lot of money worldwide.
Ocean acidification can also have affects on marine fish larvae.
It internally affects their olfactory systems, which is a crucial part
of their development, especially in the beginning stage of their life.
Orange clownfish larvae mostly live on oceanic reefs that are surrounded
by vegetative islands.
With the use of their sense of smell, larvae are known to be able to
detect the differences between reefs surrounded by vegetative islands
and reefs not surrounded by vegetative islands.
Clownfish larvae need to be able to distinguish between these two
destinations to have the ability to locate an area that is satisfactory
for their growth. Another use for marine fish olfactory systems is to
help in determining the difference between their parents and other adult
fish in order to avoid inbreeding.
At James Cook University's experimental aquarium facility,
clownfish were sustained in non-manipulated seawater that obtained a pH
of 8.15 ± 0.07 which is similar to our current ocean's pH. To test for
effects of different pH levels, seawater was manipulated to three
different pH levels, including the non-manipulated pH. The two opposing
pH levels correspond with climate change models that predict future
atmospheric CO2 levels.
In the year 2100 the model predicts that we could potentially acquire
CO2 levels at 1,000 ppm, which correlates with the pH of 7.8 ± 0.05.
Continuing even further into the next century, we could have CO2 levels
at 1,700 ppm, which correlates with a pH of 7.6 ± 0.05.
Results of this experiment show that when larvae is exposed to a
pH of 7.8 ± 0.05 their reaction to environmental cues differs
drastically to larvae's reaction to cues in a non-manipulated pH. Not
only did if effect their reaction to environmental cues but their
reaction to parental cues was also skewed compared to the larvae reared
in a non-manipulated pH of 8.15 ± 0.07. At the pH of 7.6 ± 0.05 larvae
had no reaction to any type of cue. These results display the negative
outcomes that could possibly be the future for marine fish larvae.
Oxygen depletion
Ocean deoxygenation is projected to increase hypoxia
by 10%, and triple suboxic waters (oxygen concentrations 98% less than
the mean surface concentrations), for each 1 °C of upper ocean warming.
Research indicates that increasing ocean temperatures are taking a toll on the marine ecosystem. A study on phytoplankton changes in the Indian Ocean indicates a decline of up to 20% in marine phytoplankton during the past six decades.
During the summer, the western Indian Ocean is home to one of the
largest concentrations of marine phytoplankton blooms in the world when
compared to other oceans in the tropics. Increased warming in the Indian
Ocean enhances ocean stratification, which prevents nutrient mixing in
the euphotic zone where there is ample light available for
photosynthesis. Thus, primary production is constrained and the region's
entire food web is disrupted. If rapid warming continues, experts
predict that the Indian Ocean will transform into an ecological desert
and will no longer be productive.
The same study also addresses the abrupt decline of tuna catch rates in
the Indian Ocean during the past half century. This decrease is mostly
due to increased industrial fisheries, with ocean warming adding further
stress to the fish species. These rates show a 50-90% decrease over 5
decades.
A study that describes climate-driven trends in contemporary ocean productivity looked at global-ocean net primary production (NPP) changes detected from satellite measurements of ocean color from 1997 to 2006.
These measurements can be used to quantify ocean productivity on a
global scale and relate changes to environmental factors. They found an
initial increase in NPP from 1997 to 1999 followed by a continuous
decrease in productivity after 1999. These trends are propelled by the
expansive stratified low-latitude oceans and are closely linked to
climate variability. This relationship between the physical environment
and ocean biology effects the availability of nutrients for
phytoplankton growth since these factors influence variations in
upper-ocean temperature and stratification.
The downward trends of ocean productivity after 1999 observed in this
study can give insight into how climate change can affect marine life in
the future.
Effects of Marine Life Danger in Society.
As stated before, marine life has been decreasing in percentage
as the time goes on due to the increase in ocean pollution being the
main component plastic that is eaten by marine animals.
Along with marine life, humans are also being affected by ocean
pollution. One of the biggest animal protein industries, as it is the
seafood industry, is affected since marine life has been decreasing and
it is predicted that if they continue using the harmful techniques that
are being used, by 2048 there is the possibility of an ocean without
fish. The seafood industry has a big impact in the world’s food industry, proving food for approximately 3 billion people.
One of the many famous and trending diets that are out there are the
pescatarian diet, in which vegetarian diets followers add fish or other
types of seafood in order to obtain the nutrients from the fish.
If it comes to the point in which the seafood industry keep growing, as
more people are joining this type of food trends and eating more fish
(more demand means more production),
and using techniques that deteriorate the marine life beyond catching
the animals we will end up at the point of no return: where the marine
life is extinct and we as humans will not be able to consume such as
good source of protein in order to meet the required necessities. The
ocean pollution does not mean that only marine life is being damaged,
but also that we as humans will deprive ourselves from a great privilege
as it is seafood and marine life.
Weather
Global warming also affects weather patterns as they pertain to cyclones.
Scientists have found that although there have been fewer cyclones than
in the past, the intensity of each cyclone has increased.
A simplified definition of what global warming means for the planet is
that colder regions would get warmer and warmer regions would get much
warmer.
However, there is also speculation that the complete opposite could be
true. A warmer earth could serve to moderate temperatures worldwide.
There is still much that is not understood about the earth's climate,
because it is very difficult to make climate models. As such, predicting
the effects that global warming might have on our planet is still an
inexact science.
Global warming is also causing the amount of hazards on the ocean to
increase. It has increased the amount of fog at sea level, making it
harder for ships to navigate without crashing into other boats or other
objects in the ocean. The warmness and dampness of the ground is causing
the fog to come closer to the surface level of the ocean. As the rain
falls it makes the ground wet, then the warm air rises leaving a layer
of cold air that turns into fog causing an unsafe ocean for travel and
for working conditions on the ocean.
It is also causing the ocean to create more floods due to the fact that
it is warming up and the glaciers from the ice age are now melting
causing the sea levels to rise, which causes the ocean to take over part
of the land and beaches.
Glaciers are melting at an alarming rate which is causing the ocean to
rise faster than predicted. Inside of this ice there are traces of
bubbles that are filled with CO2 that are then released into the atmosphere when they melt causing the greenhouse effect to grow at an even faster rate.
Regional weather patterns across the globe are also changing due to tropical ocean warming. The Indo-Pacific warm pool
has been warming rapidly and expanding during the recent decades,
largely in response to increased carbon emissions from fossil fuel
burning. The warm pool expanded to almost double its size, from an area of 22 million km2 during 1900–1980, to an area of 40 million km2 during 1981–2018. This expansion of the warm pool has altered global rainfall patterns, by changing the life cycle of the Madden Julian Oscillation (MJO), which is the most dominant mode of weather fluctuation originating in the tropics.
Seafloor
It is known that climate affects the ocean and the ocean affects the climate. Due to climate change, as the ocean gets warmer this too has an effect on the seafloor.
Because of greenhouse gases such as carbon dioxide, this warming will
have an effect on the bicarbonate buffer of the ocean. The bicarbonate
buffer is the concentration of bicarbonate ions that keeps the ocean's
acidity balanced within a pH range of 7.5–8.4.
Addition of carbon dioxide to the ocean water makes the oceans more
acidic. Increased ocean acidity is not good for the planktonic organisms
that depend on calcium to form their shells. Calcium dissolves with
very weak acids and any increase in the ocean's acidity will be
destructive for the calcareous organisms. Increased ocean acidity will
lead to decreased Calcite Compensation Depth (CCD), causing calcite to dissolve in shallower waters. This will then have a great effect on the calcareous ooze in the ocean, because the sediment itself would begin to dissolve.
Predictions
Calculations prepared in or before 2001 from a range of climate models
under the SRES A2 emissions scenario, which assumes no action is taken
to reduce emissions and regionally divided economic development.
The geographic distribution of surface warming during the 21st century calculated by the HadCM3
climate model if a business as usual scenario is assumed for economic
growth and greenhouse gas emissions. In this figure, the globally
averaged warming corresponds to 3.0 °C (5.4 °F).
A temperature rise of 1.5°C above preindustrial levels is projected
to make existence impossible for 10% of fishes in their typical
geographical range. A temperature rise of 5°C above this level is
projected to make existence impossible for 60% of fishes in their
geographical range. The main reason is Oxygen depletion
as one of the consequences of the rise in temperature. Further, the
change in temperature and decrease in oxygen is expected to occur too
quickly for effective adaptation of affected species. Fishes can migrate
to cooler places, but there are not always appropriate spawning sites.
If ocean temperatures rise it will have an effect right beneath
the ocean floor and it will allow the addition of another greenhouse
gas, methane gas. Methane gas has been found under methane hydrate,
frozen methane and water, beneath the ocean floor. With the ocean
warming, this methane hydrate will begin to melt and release methane
gas, contributing to global warming.
However, recent research has found that CO2 uptake outpaces methane
release in these areas of the ocean causing overall decreases in global
warming.
Increase of water temperature will also have a devastating effect on
different oceanic ecosystems like coral reefs. The direct effect is the
coral bleaching of these reefs, which live within a narrow temperature
margin, so a small increase in temperature would have a drastic effects
in these environments. When corals bleach it is because the coral loses
60–90% of their zooxanthellae due to various stressors, ocean
temperature being one of them. If the bleaching is prolonged, the coral
host would die.
Although uncertain, another effect of climate change may be the growth, toxicity, and distribution of harmful algal blooms.
These algal blooms have serious effects on not only marine ecosystems,
killing sea animals and fish with their toxins, but also for humans as
well. Some of these blooms deplete the oxygen around them to levels low enough to kill fish.