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PARKER SOLAR PROBE: It's been on NASA's bucket list for 60 years, and now the ambitious mission to touch the Sun is in its final phase before launch. So just how do you send a spacecraft into the Sun without it burning up?

Australia’s first biofuels pilot plant was officially opened by the Honourable Annastacia Palaszczuk MP, in Gladstone today.

Carnegie Clean Energy adds 2.6MWh battery storage system to 1.6MW solar system at CSIRO's Murchison Radio-astronomy Observatory.

Pikestone Fell, Weardale An oystercatcher, a gaudy pied clown with crimson beak and eyes, flew straight towards us, piping hysterically

In winter this part of the Weardale Way can be a morass, but the rain-leached soil drains quickly in spring. After weeks of dry, windy, weather, the mud had turned to sand and our boots were soon covered in yellow dust. In some sheltered hollows heather, at last showing a green tint of new shoots, shimmered in a heat haze.

Our route followed the wall that divides upland pasture from heather moorland. Together they provide habitats for grouse and the wading birds that return here from the coast to breed, and late May is the peak time for egg hatching.

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Leading Australian home energy management start-up, Reposit Power, has issued a recall for all Reposit meter and box Kits installed since 2015, due to potential risk of electric shock.

Endeavour says network ownership could turn 360° and revert to local councils and communities, as it seeks tender for solar and storage micro-grid.

Nauiyu community set to be powered by a 1MW solar plant during the day, relegating its diesel generators for use only at night and as back-up.

Australian Institute of Marine Science says reef’s capacity to recover under threat from climate change and pollution

Parts of the Great Barrier Reef not regularly affected by problems such as cyclones have demonstrated the reef still has the ability to regenerate, with a survey showing sharp declines in coral cover in the north but increases elsewhere.

However, the latest results from the Australian Institute of Marine Science (Aims), collected by divers visiting 243 individual reefs, do not include the losses caused by bleaching this year, or the effects of cyclone Debbie, both of which killed coral in the central section.

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America’s time as leader of the free world is over. Now we’re the villain, thwarting the global effort to save humanity.

A testing laboratory built by Queensland utility Ergon Energy to host one of Australia’s biggest residential battery storage trials has been opened in Cairns.

A ‘JKT’ triad—Japan, South Korea, and Taiwan—sets a 21st century course for clean energy.

Offshore wind farms have been blamed by conservative media in the UK for the deaths of three whales - despite not having a shred of evidence.

Deputy PM departs from official Coalition line, saying ‘to speculate on what Donald Trump might do is insanity’ and I’m going to ‘see what happens’

Barnaby Joyce has declined to say whether Australia should remain within the Paris climate accord if the United States pulls out, in a departure from the official government line that Australia will stay the course.

While Australia’s energy and employment ministers have said this week Australia will honour its Paris commitments regardless of what Donald Trump decides, the Nationals leader and deputy prime minister was more guarded on Thursday.

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Regulators issue grim warning about power of big fossil fuel generators to game energy markets, forcing up prices. They say the price surge to "unprecedented" highs in coal-dependent Queensland is being driven by market concentration and the lack of large-scale wind and solar.

Intensive farming cited as main reason for destroying natural barriers to deluge and making low lying areas more vulnerable to floods

Only a tenth of England’s extensive floodplains are now fit for purpose – 90% no longer function properly – with the shortfall putting an increasing number of homes and businesses at risk of flooding, according to a new report.

Floods are more likely due to climate change and will claim higher economic costs unless action is taken to halt the damage to floodplains and restore some of their functions, warned the authors of the 12-month study – the first to paint a comprehensive view of England’s floodplains and their capabilities.

“We have ignored our floodplains,” said George Heritage of Salford University, co-author of the study the Changing Face of Floodplains, published by Co-Op Insurance on Thursday. “The changes to them mean water [from heavy rainfall] can flow much faster downstream, and can flow at the same speed as the water in the rivers.”

This accelerated flow has led to sudden and unstoppable deluges in recent years. For instance, Storm Desmond in 2015 affected more than 6,000 homes as rivers and streams burst their banks and spread water over floodplains. As these natural floodplains had been altered by man-made features, they no longer had the ability to store water, leading to rapid flows into urban areas which led to the devastation.

Storm Desmond caused more than £500m in damages, and misery for families excluded from their homes sometimes for months. The UK’s flooding bills are on the rise, with scientists warning of rocketing numbers of cloudbursts and periods of sudden and intense rainfall as climate change takes effect.

Floodplains act as natural “sponges”, soaking up excess water in their vegetation, forming natural buffers that hold back or divert rushing water after rain, and providing areas where rivers can breach their banks and wetlands can be replenished.

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RepuTex says ceasing all land clearing would save between 300m and 650m tonnes of carbon dioxide emissions each year

Ending land clearing in Australia by 2030 would cut Australia’s greenhouse gas emissions by about as much as completely shifting the electricity sector to renewable energy, a new report has found.

Queensland has been clearing about 300,000ha of land a year since the Newman government weakened restrictions on land clearing there and the Palaszczuk government failed to tighten them.

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The statement backing the Paris climate agreement is seen a snub to Trump, who is mulling a pullout.

A new global study predicts coral reefs of the future will be radically different.

The world’s coral reefs are undoubtedly in deep trouble. But as we and our colleagues argue in a review published today in Nature, we shouldn’t give up hope for coral reefs, despite the pervasive doom and gloom.

Instead, we have to accept that coral reefs around the world are transforming rapidly into a newly emerging ecosystem unlike anything humans have experienced before. Realistically, we can no longer expect to conserve, maintain, preserve or restore coral reefs as they used to be.

This is a confronting message. But it also focuses attention on what we need to do to secure a realistic future for reefs, and to retain the food security and other benefits they provide to society.

The past three years have been the warmest on record, and many coral reefs throughout the tropics have suffered one or more bouts of bleaching during prolonged underwater heatwaves.

A bleached coral doesn’t necessarily die. But in 2016, two-thirds of corals on the northern Great Barrier Reef did die in just six months, as a result of unprecedented heat stress. This year the bleaching happened again, this time mainly on the middle section of the reef.

Reefs are being degraded by global pressures, not just local ones. Terry Hughes, Author provided

In both years, the southern third of the reef escaped with little or no bleaching, because it was cooler. So bleaching is patchy and it varies in severity, depending partly on where the water is hottest each summer, and on regional differences in the rate of warming. Consequently some regions, reefs, or even local sites within reefs, can escape damage even during a global heatwave.

Moderate bleaching events are also highly selective, affecting some coral species and individual colonies more than others, creating winners and losers. Coral species also differ in their capacity to reproduce, disperse as larvae, and to rebound afterwards.

This natural variability offers hope for the future, and represents different sources of resilience. Surviving corals will continue to produce billions of larvae each year, and their genetic makeup will evolve under intense natural selection.

In response to fishing, coastal development, pollution and four bouts of bleaching in 1998, 2002, 2016 and 2017, the Great Barrier Reef is already a highly altered ecosystem, and it will change even more in the coming decades. Although reefs will be different in future, they could still be perfectly functional in centuries to come – capable of sustaining ecological processes and regenerating themselves. But this will only be possible if we act quickly to curb climate change.

The Paris climate agreement provides the key framework for avoiding very dangerous levels of global warming. Its 1.5℃ and 2℃ targets refer to increases in global average land and sea temperatures, relative to pre-industrial times. For most shallow tropical oceans, where temperatures are rising more slowly than the global average, that translates to 0.5℃ of further warming by the end of this century – slightly less than the amount of warming that coral reefs have already experienced since industrialisation began.

If we can improve the management of reefs to help them run this climate gauntlet, then reefs should survive. Reefs of the future will have a different mix of species, but they should nonetheless retain their aesthetic values, and support tourism and fishing. However, this cautious optimism is entirely contingent on steering global greenhouse emissions away from their current trajectory, which could see annual bleaching of corals occurring in most tropical locations by 2050. There is no time to lose before this narrowing window of opportunity closes.

A crisis of governance

Reef governance is failing because it is largely set up to manage local threats, such as overfishing and pollution. In Australia, when the Great Barrier Reef Marine Park Authority was set up in 1976, the objective of managing threats at the scale of (almost) the entire Great Barrier Reef was revolutionary. But today, the scale of threats is global: market pressures for Australian reef fish now come from overseas; port dredging and shipping across the reef are spurred on by fossil fuel exports to Asia; a housing crisis in the United States can batter reef tourism half a world away; and record breaking marine heatwaves due to global warming can kill even the most highly protected and remote corals.

Increasingly, coral reef researchers are turning to the social sciences, not just biology, in search of solutions. We need better governance that addresses both local and larger-scale threats to coral reef degradation, rather than band-aid measures such as culling starfish that eat corals.

In many tropical countries, the root causes of reef degradation include poverty, increasing market pressures from globalisation, and of course the extra impacts of global warming. Yet these global issues desperately need more attention at just the time when some governments are reducing foreign aid, failing to address global climate change, and in the case of Australia and the US, trying to resuscitate the dying fossil fuel industry with subsidies for economically unviable projects.

Effective reef governance will not only require increased cooperation among nations to tackle global issues, as in the case of the Paris climate deal, but will also require policy coordination at the national level to ensure that domestic action matches and supports these larger-scale goals.

Quite simply, we can’t expect to have thriving coral reefs in the future as well as new coal mines – policies to promote both are incompatible.

Terry Hughes receives competitive research funding from The Australian Research Council.

Joshua Cinner receives competitive research funding from the Australian Research Council and currently holds a fellowship from the Pew Charitable Trust

A wide range of industrial processes have released greenhouse gases into the atmosphere. Paulo Resende/Shutterstock.com

The most comprehensive collection of atmospheric greenhouse gas measurements, published today, confirms the relentless rise in some of the most important greenhouse gases.

The data show that today’s aggregate warming effect of carbon dioxide (CO₂), methane (CH₄) and nitrous oxide (N₂O) is higher than at any time over the past 800,000 years, according to ice core records.

Building on half a century of atmospheric measurements by the international research community, we compiled and analysed the data as part of a group of international scientists, led by Malte Meinshausen from the University of Melbourne in collaboration with CSIRO.

Together, the data provide the most compelling evidence of the unprecedented perturbation of Earth’s atmosphere. They clearly show that the growth of greenhouse gases began with the onset of the industrial era around 1750, took a sharp turn upwards in the 1950s, and still continues today.

Research has demonstrated that this observed growth in greenhouse gases is caused by human activities, leading to warming of the climate – and in fact more than the observed warming, because part of the effect is currently masked by atmospheric pollution (aerosols).

The new collection of records comes from measurements of current and archived air samples, air trapped in bubbles in ice cores, and firn (compacted snow). The data cover the past 2,000 years without gaps, and are the result of a compilation of measurements analysed by dozens of laboratories around the world, including CSIRO, the Bureau of Meteorology’s Cape Grim Station, NOAA, AGAGE and the Scripps Institution of Oceanography, among others.

These data include 43 different greenhouse gases released into the atmosphere from dozens of human activities and industrial processes. While CO₂, CH₄ and N₂O are on the rise, some other greenhouse gases such as dichlorodifluoromethane (CFC-12) are slowly starting to decline as a result of policies to ban their use.

Author provided The greenhouse gases

Most of us know that CO₂, CH₄ and N₂O are among the principal causes of human-induced climate change. They are found in the atmosphere in the absence of human activity, but the increases in their concentrations are due to human activities such as burning fossil fuels, deforestation and agriculture (livestock, rice paddies, and the use of nitrogen-based fertilisers). They are all from biological or fossil fuel sources.

But there is much more when it comes to greenhouse gases. Our analysis features a further 40 greenhouse gases (among hundreds that exist), many of them emitted in very small quantities. Although many might play a small role, dichlorodifluoromethane (CFC-12) and trichlorofluoromethane (CFC-11) are the third and fifth most important greenhouse gases respectively, in terms of their overall contributions to global warming.

Most of these gases are emitted exclusively by humans, the so-called synthetic greenhouse gases, and have been used variously as aerosol spray propellants, refrigerants, fire-extinguishing agents, and in the production of semiconductors, among other industrial applications.

Synthetic greenhouse gases include chlorofluorocarbons (CFCs), hydrochlorofluorocarbons (HCFCs), hydrofluorocarbons (HFCs), most perfluorocarbons (PFCs), sulfur hexafluoride (SF₆), and others. Several, most famously CFCs, also deplete the ozone layer and are regulated under the Montreal Protocol. Others, such as HFCs, were actually first produced in large quantities to replace the ozone-depleting substances, but unfortunately turned out to be potent greenhouse gases too.

Importantly, all 43 greenhouse gases offer opportunities to tackle climate change, either by reducing their emissions or, in the case of synthetic gases, finding non-greenhouse alternatives.

Not all greenhouse gases are the same

How much a greenhouse gas contributes to warming depends on three factors. The first is how much gas is emitted. Second is how much a kilogram of that gas will warm the planet once it’s in the atmosphere. And third is how long the gas will remain in the atmosphere.

CO₂ is the most important greenhouse gas in warming the planet, despite being the weakest greenhouse gas per unit of mass. Its contribution to warming comes from the sheer scale of emissions (40 billion tonnes emitted each year), and the fact that a large part effectively hangs around in the atmosphere for hundreds or thousands of years after emission. The resulting concentration makes CO₂ responsible for about 65% of all warming due to greenhouse gas emissions from human activities.

This makes CO₂ the most important factor in determining future global warming. Unless we can cut CO₂ emissions to zero by the second half of this century, primarily by finding alternatives to fossil fuels, the world will continue to warm beyond the 2℃ target of the Paris Agreement, not to mention the aspirational 1.5℃ goal.

Provided by University of Melbourne http://climate-energy-college.org/more-climate-spirals.

Methane (CH₄) is the next most important greenhouse gas, with current concentration contributing about 15% of overall human-induced warming.

Most synthetic greenhouse gases have very high global warming potentials. The one with the highest current emissions is the refrigerant HFC-134a, which is 1,300 times more potent than CO₂ (per mass unit emitted). Other synthetic greenhouse gases have even more extraordinary warming potentials, with CF₄ (used in the semiconductor industry) and SF₆ (from industrial electricity transformers) being 6,500 and 23,400 times more potent than CO₂, respectively.

CFC-12, a former refrigerant, is both a potent ozone-depleting substance and a powerful greenhouse gas. Although its emissions and atmospheric concentrations are now declining thanks to global compliance with the Montreal Protocol, it is still the third most important greenhouse gas and responsible for 6-7% of all warming since the beginning of the industrial era.

What are these GHG data good for?

Our new compilation of greenhouse gas data is the most complete and robust picture to date showing the main drivers of climate change, and how we humans are altering the Earth’s atmosphere. Global temperature is now about 1℃ warmer on average than pre-industrial temperatures.

The new database also serves as an accurate measure of greenhouse gas concentrations resulting from past human and natural emissions, which will in turn help to improve the performance of climate models. Building trust and confidence in climate projections starts by testing and running models with real data during historical periods. The new climate projections will feed in the next major report from the Intergovernmental Panel on Climate Change, due to be released in 2021.

Continued greenhouse gas monitoring, including significant contributions by Australia, is crucial to understand how the planet reacts to human interference, and to better plan for adaptation to a changing climate. Global and regional greenhouse data can help nations to track the long-term global targets under the Paris agreement, and to inform actions needed to stabilise the climate.

Pep Canadell receives funding from the National Environmental Science Programme - Earth Systems and Climate Change Hub.

Cathy Trudinger receives funding from the National Environmental Science Programme - Earth Systems and Climate Change Hub

David Etheridge's research has received funding from the Australian Climate Change Science Program (a partnership between the Department of the Environment, the Bureau of Meteorology and CSIRO), from the University of Copenhagen, from the CO2CRC and from the Gas Industry Social and Environmental Research Alliance.

Malte Meinshausen works for the University of Melbourne. He receives funding from the Australian Research Council.

Paul Fraser is a CSIRO post-retirement Fellow and in the recent past as a CSIRO officer has received funding from Bureau of Meteorology, NASA/MIT, Department of Environment and Energy, Refrigerant Reclaim Australia; future funding is likely from CSIRO, NASA/MIT and Refrigerant Reclaim Australia

Paul Krummel is employed by CSIRO and receives funding from MIT, NASA, Australian Bureau of Meteorology, Department of the Environment and Energy, and Refrigerant Reclaim Australia.