25/07/2020

Major New Climate Study Rules Out Less Severe Global Warming Scenarios

Washington PostAndrew Freedman | Chris Mooney

An analysis finds the most likely range of warming from doubling carbon dioxide to be between 4.1 to 8.1 degrees Fahrenheit.

Flames ripped through trees as the Hog Fire jumped Highway 36 about five miles from Susanville, Calif., on Monday. (Josh Edelson/AFP/Getty Images). (Josh Edelson/AFP/Getty Images)

The current pace of human-caused carbon emissions is increasingly likely to trigger irreversible damage to the planet, according to a comprehensive international study released Wednesday.

Researchers studying one of the most important and vexing topics in climate science — how sensitive the Earth’s climate is to a doubling of the amount of carbon dioxide in the atmosphere — found that warming is extremely unlikely to be on the low end of estimates.

These scientists now say it is likely that if human activities — such as burning oil, gas and coal along with deforestation — push carbon dioxide to such levels, the Earth’s global average temperature will most likely increase between 4.1 to 8.1 degrees Fahrenheit (2.3 and 4.5 degrees Celsius).

The previous and long-standing estimated range of climate sensitivity, as first laid out in a 1979 report, was 2.7 to 8.1 degrees Fahrenheit (1.5 to 4.5 Celsius).

If the warming reaches the midpoint of this new range, it would be extremely damaging, said Kate Marvel, a physicist at NASA’s Goddard Institute of Space Studies and Columbia University, who called it the equivalent of a “five-alarm fire” for the planet.

The new range is narrower than previous studies, but shows at least a 95 percent chance that a doubling of carbon dioxide, which the world is on course to reach within the next five decades or so, would result in warming greater than 3.6 degrees Fahrenheit (2 degrees Celsius) relative to preindustrial temperatures.

That is the threshold beyond which scientists say the Earth will suffer dangerous effects — disruptive sea level rise, intolerable heat waves and other extreme weather and permanent damage to ecosystems.

Staying below that is still possible. If steep emissions cuts are made in the near-term, a doubling of carbon dioxide levels could be avoided. But if a doubling does occur, there would be a 6 to 18 percent chance of exceeding the upper bound defined by the study of 8.1 Fahrenheit (4.5 Celsius).

The study by 25 researchers from around the world and published in the journal Reviews of Geophysics is the result of a four-year effort sponsored by the World Climate Research Program. It includes a narrower projected sensitivity range that has a two out of three chance of occurring, of 4.7 to 7 degrees Fahrenheit (2.6 to 3.9 Celsius).

The “Holy Grail” of climate science

For decades, climate scientists have been seeking to answer the question of how much global temperatures would climb if the amount of carbon dioxide in the Earth’s atmosphere were to double.

This measure was estimated in a 1979 study from the National Research Council led by Massachusetts Institute of Technology professor Jule Charney.

The “Charney Report” concluded that the planet’s climate sensitivity was most likely within the range of 2.6 to 8.1 degrees Fahrenheit (1.5 to 4.5 Celsius).

Ever since, researchers have tried to narrow that range, contending with myriad uncertainties in how the oceans and atmosphere respond to historical changes in solar output, the planet’s orbit, past periods with higher amounts of carbon dioxide in the air as well as feedback, such as how various cloud types act to trap or reflect heat energy. In addition, scientists have wrestled with uncertainties in models that simulate past, present and future climate change.

“Constraining climate sensitivity has been something of a Holy Grail in climate science for some time,” said study co-author Zeke Hausfather, director of climate and energy at the Breakthrough Institute.

The climate sensitivity question has taken on new urgency as some of the newest computer models developed for the U.N. Intergovernmental Panel on Climate Change (IPCC) , due in a report next year, show a higher climate sensitivity than earlier models.

The new result narrows the range from what Charney and his colleagues calculated while raising the lower bound.

Multiple lines of evidence pointing in the same direction

Global average temperature departures from average from January through June 2020. (Berkeley Earth)

To produce the study, the group of researchers worked like detectives, breaking up into teams that sifted through multiple sources of evidence.

Some of the data examined include instrument records since the industrial revolution, paleoclimate records from coral reefs and ice cores that provide evidence of prehistoric temperatures, as well as satellite observations and intricate models of how the climate system works.

To reach their new, authoritative estimates, the researchers required that multiple lines of evidence point to the same general conclusion and that this be explained without being the result of a bias that influences one or more sources of evidence.

“An important part of the process was to ensure that the lines of evidence were more or less independent,” said lead author Steven Sherwood, a climate scientist at the University of New South Wales’s ARC Center of Excellence for Climate Extremes, in a news release.

“You can think of it as the mathematical version of trying to determine if a rumor you hear separately from two people could have sprung from the same source; or if one of two eyewitnesses to a crime has been influenced by hearing the story of the other one,” Sherwood said.

Andrew Dessler, a climate scientist at Texas A&M University who was not involved in the study, called this “a tour de force of climate science.” He said via email that the study, “Really, really kills the skeptical argument that climate sensitivity is low.”

“It would have been great if the skeptics had been correct and climate sensitivity was, say, 1.5°C, but that’s not the world we live in.”

Knowing the climate sensitivity range could enable better decision-making

The term “climate sensitivity” might seem like an academic construct, a metric that matters more in the grand theories and computer models of scientists than it does in our everyday lives.

In fact, the study has a message that matters to us a great deal: There is basically little or no chance that we are going to get lucky and find that the warming caused by our activities turns out to be minor.

There are at least two main lines of evidence that lead to the conclusion, based on the study. The first is simply the warming that has already occurred since the industrial revolution.

Currently, with atmospheric concentrations of carbon dioxide at 415 parts per million (compared with a preindustrial level of 280 parts per million), the world is about halfway toward doubling atmospheric carbon dioxide (560 parts per million). And already, the Earth has warmed by at least 1 degree Celsius (1.8 degrees Fahrenheit) preindustrial temperatures.

The new research finds that, in light of this, there is strong evidence refuting the notion that a doubling of carbon dioxide would only cause around 2.6 degrees (1.5 Celsius) of warming.

At the same time, researchers rejected the idea that there is any factor in the climate system that will counteract the warming trend in a meaningful way.

In the past, climate change contrarians and doubters have said that clouds might be such a factor. For instance, if as the planet warms the overall size, composition or surface area of clouds increases, they could reflect more sunlight from Earth, which would cool the planet some. But the study finds that isn’t likely to happen.

“We find that a negative total cloud feedback is very unlikely,” the authors write, concluding that for this reason the climate sensitivity cannot be very low.

“The uncertainty is really asymmetric here,” Marvel said in an interview. “We can be very confident in ruling out sensitivities on the low end. So basically what we’re saying here is that there is really no evidence for any sort of natural response, any sort of big, stabilizing feedback, that in the absence of human actions, is going to save us from climate change."

But Gavin Schmidt, the study’s co-author and Marvel’s colleague at NASA Goddard, offered some optimism, noting that collective action by nations could prevent the doubling of carbon dioxide in the atmosphere.

“The primary determinant of future climate is human actions,” Marvel said.

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(AU) In A World First, Australian University Builds Own Solar Farm To Offset 100% Of Its Electricity Use

The Conversation |  
                                

Glenn Hunt

Limiting global warming to well below 2℃ this century requires carbon emissions to reach net zero by around 2050. Australian households have done much to support the transition via rooftop solar investments. Now it’s time for organisations to take a more serious role.

The University of Queensland’s efforts to reduce its electricity emissions provides one blueprint. Last week UQ opened a 64 megawatt solar farm at Warwick in the state’s southeast. It’s the first major university in the world to offset 100% of its electricity use with renewable power produced from its own assets. In fact, UQ will generate more renewable electricity than it uses.

The Warwick Solar farm shows businesses and other organisations that the renewables transition is doable, and makes economic sense.

The renewables transition makes economic sense. Glenn Hunt

A model for the future

UQ’s electricity decarbonisation journey started a decade ago when it installed a 1.2MW rooftop solar array across buildings at the St Lucia campus. At the time, it was the largest rooftop solar array in Australia.

In 2015 UQ launched the 3.3MW solar farm at Gatton – part of a world-class solar research facility open to researchers from around the world.

Building on this, last week UQ opened the Warwick solar farm, primarily funded through a A$125 million loan from the Queensland Government. The output – about 160 gigawatt-hours a year – is equal to powering about 27,000 homes or reducing coal consumption by more than 60,000 tonnes. This generation will more than offset the total amount of energy UQ’s sites use each year.

Money that would previously have been spent paying the university’s electricity bills will instead now pay off this loan, over about a decade. This shows how an organisation can redirect operating expenditure to invest in emissions reduction.

Three months ago, UQ also installed a 1.1MW Tesla battery at its St Lucia campus. As Queensland’s largest on-site battery, it saved UQ almost A$75,000 in electricity costs during the first three months of operation. It did this by buying power when it was cheap and selling it during peak demand periods, as well as helping support the grid during faults.

These projects provide a “living laboratory” for teaching and research. They also give crucial insights into how organisations can invest in renewable generation and energy storage assets today, to increase their commercial viability.

UQ has made data generated by its solar and battery assets publicly available so other organisations can learn from its efforts.


Opening of UQ’s Warwick Solar Farm in 2020.

Why organisations must act

About 2,000 companies are jointly responsible for more than half the world’s emissions. In many cases, investors are now calling on companies to demonstrate how their activities are compatible with a net-zero emissions target.

Organisations generate greenhouse gas emissions in different ways. “Scope 1” emissions come from assets owned or controlled by the organisation, such as company-owned vehicles or power plants. “Scope 2” emissions come from electricity consumed, and “Scope 3” involves a wide range of indirect emissions such as staff commuting or waste disposal.

Companies can also contribute to emissions produced overseas, but these are generally not captured by standard national emissions accounts.

A 2015 study was the first to translate global climate targets to a company level. Since then, more than 900 companies have committed to climate action through the Science Based Targets initiative.

Typically, companies are not yet evaluated in terms of their performance against climate goals. However, attention from investors on climate risk and impact is increasing. It’s only a matter of time before lagging companies will face greater scrutiny from investors, governments and the broader public. All the more reason to start acting today.

Public pressure is building on companies to reduce emissions. School Strike 4 Climate Australia

Over to you

An organisation must take a holistic view of all its activities, to fully understand the emissions it creates. From this they can develop a sustainability “action plan” which includes setting science-based targets . UQ is currently finalising a ten-year Sustainability Strategy based on the UN’s Sustainable Development Goals.

Other ways organisations can reduce emissions include:
The time for talk is over. Organisations must now actively play their part in achieving global net-zero emissions. The University of Queensland shows how it can be done.

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(AU) Cyclones Can Be Predicted Four Months Ahead, Thanks To New Australasian Model

ABC NewsEvan Wasuka | Elsie Lange

Category two Cyclone Sarai was one of the storms that battered the Pacific last season. (Supplied: Japanese Meteorological Agency / Himawari-8)

Key Points
  • Cyclone modelling has traditionally been difficult due to complex interactions between the sea and atmosphere
  • A new Australia-New Zealand forecast model now synthesizes these interactions simultaneously
  • This could strengthen the Pacific's preparedness for its annual cyclone season
Cyclones have been notoriously hard to predict over decades, but a new scientific model could prove to be a circuit-breaker, particularly in the cyclone-battered Pacific.

Newcastle University, in collaboration with New Zealand's National Institute for Water and Atmospheric Research, has released a new predictive tool call Long-Range Tropical Cyclone Outlook for the Southwest Pacific (TCO-SP), which can forecast cyclones up to four months in advance.

Current modelling only produces forecasts one month in advance, while actual cyclone paths may not necessarily follow predicted paths.

Traditionally, the severity and paths of tropical cyclones have been hard to predict because of the complex interactions between the ocean and the atmosphere, but this new tool manages to capture all of these interactions simultaneously.

The above graphic shows how evolving cyclone prediction technology would have mapped Cyclone Tracy's path. (Supplied: BOM)

"We consider the most recent changes in ocean and atmospheric variability, and that enables us to refine the outlooks based on what's just happened," Andrew Magee, a specialist in climate change's effects on extreme weather events at Newcastle University, told the ABC.

Dr Magee added this could buy Pacific governments lifesaving time to prepare for the region's annual cyclone season, which runs between November and April.

There are already nine tropical cyclones predicted in the south-west Pacific for the upcoming season.

New tool could be a Pacific life-saver


Cyclone Harold devastated parts of Vanuatu earlier this year.

Earlier this year, category five Cyclone Harold tore through Vanuatu, Fiji, Tonga, and the Solomon Islands, leaving a trail of ruin and killing more than 25 people.

For ship captains like Eddie Varou from the Solomon Islands, any progress in cyclone forecasting is exciting and would benefit many in the region.

"Those islands depend entirely on fruits, so if you can predict which months cyclones can come, then these people will have three months to prepare their food, their rice, so when the cyclone hits, they are already ready," Mr Varou said.

"I hope our Government can take this on."

Cyclone Harold struck Vanuatu this year with winds of up to 285 kph. (ABC News: Dan McGarry)

Neville Koop, a meteorologist from Na Draki Weather in Fiji, said the research was a "major step" in helping authorities solve community-based issues such as disaster preparedness leading up to cyclone season.
"This provides the expert level much more information about likely scenarios for cyclone activity, both short term … over the course of days and weeks, right out to seasonal and into annual [forecasts]," Mr Koop said.
He said the technology could potentially be used to predict events "several years ahead".

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