We need to investigate how the ocean鈥檚 immense potential for atmospheric carbon dioxide removal can be harnessed to reduce the impacts of climate change.
Diane Nazaroff
0424479199
diane.nazaroff@unsw.edu.au
The upcoming sixth assessment of the Intergovernmental Panel on Climate Change warns that even prolonged warming of 1.5掳C could produce聽progressively serious, centuries-long and, in some cases, .
It states that 鈥渢he worst is yet to come, affecting our children鈥檚 and grandchildren鈥檚 lives much more than our own.鈥
In response, Australian researchers have joined efforts to investigate how the ocean鈥檚 immense potential for atmospheric carbon dioxide removal can be harnessed to reduce the impacts of climate change.
Collaborating within聽the 鈥渢hinktank鈥 , we are evaluating a range of unconventional, novel, and still experimental approaches. To achieve safe and effective large-scale solutions, the work addresses the full spectrum of technological, environmental, socio-economic, and governance issues required.
Climate extremes are breaking record upon record around the world.
Northwestern America is currently gripped in a sweltering heatwave. Last year, Australia experienced a run of extreme summer heat and drought, which culminated in the most catastrophic bushfire season on record.
厂辞尘别听聽of the continent were laid to ash. Similar combinations of heatwaves and fires are devastating other regions.
For example,聽聽were burnt in Siberia during 2020, and another聽聽along the US west coast.
The Amazon forest has changed聽from a CO2聽sink into a .
惭别补苍飞丑颈濒别,听聽extremes in the world鈥檚 oceans are causing major crises in ecosystems and fisheries, including聽decimation of coral reefs through repeated .
And all this is accompanied by an increase in the intensity of major聽, widespread聽聽events, and unprecedented聽.
This rapid increase in weather extremes is even聽greater than 聽in response to climate change.聽
聽studies convincingly link this rising trend to climate change.
Moreover,聽comparison with past natural 聽(before human impacts) clearly attributes the rapid modern climate change to human influences 鈥 most notably, to greenhouse gas emissions.
Under the聽, nation states agreed to limit global average warming to 1.5掳C and at the very most 2掳C, relative to levels before the industrial revolution.
We are at聽听补濒谤别补诲测.
To remain within the 1.5掳C warming limit,聽 of carbon (GtC)聽need to be removed from the climate system by 2100.
The range depends on which pathway of emissions reduction we will follow.
The high value applies if we globally keep emitting as we have been for the past few years.
The lower value applies if we immediately and drastically reduce global emissions.
Currently, we are following the pathway that will require carbon removal close to the high-end estimate 鈥 only bold and decisive action on emission reduction can change this.
For scale, 100 GtC is an amount of carbon equivalent to an 11m by 11m column of graphite (like an enormous artists鈥 pencil) that extends all the way from Earth to the moon.
Because removing carbon on such scales is a gargantuan challenge, it is imperative that all potential carbon-removal solutions are thoroughly assessed.
Solutions must be technically feasible and scalable, so that they can make significant inroads into the enormous quantity of carbon removal needed.
They must also be socially acceptable, economically viable and legally permissible.
There is no future for carbon-removal solutions that may be technologically perfect but are unaffordable, socially unacceptable, and/or are contrary to existing regulations.
Moreover, it is essential that governance mechanisms are developed to enable coordinated and responsible development, promote public acceptance and prevent misuse of carbon-removal solutions, such as greenwashing.聽聽聽聽聽聽 聽
Methods aimed at driving a聽聽through large-scale atmospheric CO2听removal are often called 鈥渘egative emissions technologies鈥.
Most are not high-tech solutions, but work with aspects of natural Earth processes for carbon uptake.
To be most effective, such methods need to be used alongside emissions reduction, in the same way that bailing out water from a boat is more effective when holes in the hull are fixed.
Some negative emissions technologies may sound familiar.
For example, large-scale reforestation, soil carbon enhancement by restoring depleted soils, artificially enhanced (CO2-consuming) weathering of rocks by pulverising it and adding it to farmland and coasts, or industrial CO2聽capture from the atmosphere and burying it in geological reservoirs.
Typically, these better-known methods are land-based. And some are operational on small scales already, with variable rates of success, cost, and durability.
Less familiar methods are typically focused on using the ocean to take up the CO2. Ocean-based methods have more theoretical potential than land-based methods.
The global ocean contains over 25 times more carbon than聽 combined.
In the聽recent , the global ocean contained even more carbon, so that atmospheric CO2听濒别惫别濒蝉 were reduced.聽Ocean-based negative 聽aim to use this vast capacity for CO2听诲谤补飞诲辞飞苍.
The ocean-based technologies rely on manipulating algal production rates or inorganic ocean chemistry, or on novel approaches such as sea-water splitting to release hydrogen (an attractive fuel) and using the residual fluids鈥 capacity to take up CO2.
The fundamental principles behind these approaches are well understood, but research is urgently needed to determine potential impacts on ecosystems and how to prevent these, the longevity of the CO2听uptake, and how to achieve social acceptability and suitable governance conditions.
By joining forces within CIRCA, we will uncover this information and reveal how the ocean鈥檚 massive CO2聽uptake potential can be used in an environmentally safe and acceptable manner.
We need to build this new understanding urgently.
This is because the ocean has the greatest capacity of any system on Earth to take up vast amounts of carbon, so that we will need the ocean鈥檚 help in some form or another if we are to achieve the enormous 70-280 GtC of drawdown required.
In parallel, land-based methods are vital to ensure that we have a diverse portfolio of methods to initiate as soon as they are mature enough.
Given its unique geographical attributes and critical scientific expertise, Australia can play a leading role in assessing and developing marine negative emissions methods.
Australia is the main gateway to the Southern Ocean, which is the ocean with the highest potential for carbon capture.
It also has vast quantities of resources and mature mining and transport infrastructure, which provide unparalleled availability of the materials needed in the methods.
In addition, several ocean-based negative emissions methods have potential to help efforts to ensure the survival of Earth 鈥榮 largest coral reef system.
Without readying negative emissions technologies for large-scale deployment within the next decade, we will not be able to limit warming to 1.5掳C.
For all methods 鈥 especially the less researched but major ocean-based methods 鈥 we need to urgently establish the realistic drawdown potential, environmental conditions, and socio-economic and governance requirements to ensure that we will deploy safe, effective, and acceptable solutions.
The time to act is now.
This article was originally published in聽.