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Of hungry badgers and hidden worms
Old Warden, Bedfordshire In this parched landscape it was clear the hedgerow fruit had not ripened a moment too soon for the badgers
It took only a few dry weeks for the fields on the plateau above the village to forget that it had ever rained. The clay soil was beginning to crack, the footpath had turned to a sun-baked dirt track and there was no yield underfoot. Every bump and stone was hard and uncompromisingly contoured, jabbing at an instep, stubbing a toe.
The worms had become dustbowl refugees in this parched landscape, sinking deep underground. Far below my feet, they would be aestivating, bunched up in knots, coated in their own mucus in a hibernation-like suspension of active life, waiting for moisture to come again.
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154 Australian scientists demand climate policy that matches the science
Climate scientists write another letter warning of unfolding crisis for Turnbull to ignore
More than 150 leading climate scientists at universities and government agencies ask for cuts to coal exports, saying: ‘There is no Planet B’
I’m guessing that Malcolm Turnbull gets a fair few letters on any given day. You wonder how he has the time to read them all.
How do you prioritise the ones worth your attention, and the ones that you can toss in the round-shaped filing cabinet under your desk?
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Climate warming 'started about 180 years ago'
Seeking ET
The Industrial Revolution kick-started global warming much earlier than we realised
In the early days of the Industrial Revolution, no one would have thought that their burning of fossil fuels would have an almost immediate effect on the climate. But our new study, published today in Nature, reveals that warming in some regions actually began as early as the 1830s.
That is much earlier than previously thought, so our discovery redefines our understanding of when human activity began to influence our climate.
Determining when global warming began, and how quickly the planet has warmed since then, is essential for understanding how much we have altered the climate in different parts of the world. Our study helps to answer the question of whether our climate is already operating outside thresholds that are considered safe for human society and functional ecosystems.
Our findings show that warming did not develop at the same time across the planet. The tropical oceans and the Arctic were the first regions to begin warming, in the 1830s. Europe, North America and Asia followed roughly two decades later.
Surprisingly, the results show that the southern hemisphere began warming much later, with Australasia and South America starting to warm from the early 20th century. This continental-scale time lag is still evident today: while some parts of Antarctica have begun to warm, a clear warming signal over the entire continent is still not detectable.
The warming in most regions reversed what would otherwise have been a cooling trend related to high volcanic activity during the preceding centuries.
Global warming got underway much earlier in the north.By pinpointing the date when human-induced climate change started, we can then begin to work out when the warming trend broke through the boundaries of the climate’s natural fluctuations, because it takes some decades for the global warming signal to “emerge” above the natural climate variability.
According to our evidence, in all regions except for Antarctica, we are now well and truly operating in a greenhouse-influenced world. We know this because the only climate models that can reproduce the results seen in our records of past climate are those models that factor in the effect of the carbon dioxide released into the atmosphere by humans.
These remarkable findings were pieced together from the most unusual of sources – not thermometers or satellites, but rather from natural climate archives. These include coral skeletons, ice cores, tree rings, cave deposits and ocean and lake sediment layers, all of which record the climate as they grow or accumulate.
These archives provide long records that extend back 500 years – well before the Industrial Revolution – and provide a critical baseline for the planet’s past climate, one that is impossible to obtain otherwise.
But why is there no clear warming fingerprint yet seen across Antarctica? The answer most likely lies in the vast Southern Ocean, which isolates the frozen continent from the warming happening elsewhere.
The westerly winds that circulate through the Southern Ocean around Antarctica keep warm air masses from lower latitudes at bay. Ozone depletion and rising greenhouse gas concentrations during the 20th century have also caused this wind barrier to get stronger.
The Southern Ocean currents that flow around Antarctica also tend to move warmer surface waters away from the continent, to be replaced with cold deeper water that hasn’t yet been affected by surface greenhouse warming. This process could potentially delay Antarctica’s warming by centuries.
Ocean insulationThe delay in warming observed in the rest of the southern hemisphere is something we do not yet fully understand. It could simply be because fewer records are available from the southern hemisphere, meaning that we still don’t have a full picture of what is happening.
Alternatively, like Antarctica, the southern hemisphere’s oceans could be holding back warming – partly through winds and currents, but perhaps also because of “thermal inertia”, whereby the ocean can absorb far more heat energy than the atmosphere or the land before its temperature markedly increases. Bear in mind that the southern half of the globe has much more ocean than the north.
Essentially, then, the coolness of the southern hemisphere’s vast oceans could be “insulating” Australasia and South America from the impact of global warming. The question is, for how long?
If our evidence of delayed warming in the southern hemisphere holds true, it could mean we are in in for more climate surprises as global warming begins to overcome the thermal inertia of our surrounding oceans. Could the recent record warming of Australian waters, and the subsequent damage to the Great Barrier Reef, be an early sign that this is already occurring?
Recent research suggest that the mass bleaching event of the reef was made 175 times more likely by climate change. Following the recent severity of such extremes, a better understanding of how anthropogenic greenhouse warming is already impacting the southern hemisphere is critical.
What to do about itLeading scientists from around the world met in Geneva last week to discuss the goal of limiting average global warming to 1.5℃ – the more ambitious of the two targets enshrined in the Paris climate agreement.
Last year, global temperatures crossed the 1℃ threshold, and 2016 is on track to be 1.2-1.3℃ above our climate baseline.
But here’s the kicker. That baseline is relative to 1850–1900, when most of our thermometer-based temperature records began. What our study shows is that for many parts of the world that estimate isn’t good enough, because global warming was already under way, so the real baseline would be lower.
The small increases in greenhouse gases during the 19th century had a small effect on Earth’s temperatures, but with the longer perspective we get from our natural climate records we see that big changes occurred. These fractions of a degree of extra warming might seem insignificant at first, but as we nudge ever closer to the 1.5℃ guardrail (and potentially beyond), the past tells us that small changes matter.
Helen McGregor will be online to answer your questions from 2pm AEST today. Post a query in the comments below.
Helen McGregor receives funding from the Australian Research Council and the University of Wollongong, Australia.
Joelle Gergis receives funding from the Australian Research Council.
Nerilie Abram receives funding from the Australian Research Council.
Steven Phipps receives funding from the Australian Antarctic Science Program, the Australian Research Council, the International Union for Quaternary Research, the National Computational Infrastructure Merit Allocation Scheme, the New Zealand Marsden Fund, the University of Tasmania and UNSW Australia.
Sustainable housing's expensive, right? Not when you look at the whole equation
Low-energy or zero-energy housing is international best practice, but is still considered costly. Part of the problem is that studies of housing standards typically use only cost-benefit analysis to assess their value, and so often wrongly conclude that sustainable housing is unaffordable.
Our new research shows how such analyses may miss some flow-on financial benefits – such as reduced energy bills and lower mobility costs. Most importantly, these analyses also overlook effects on householders' health and quality of life arising from factors such as improved thermal comfort.
Sustainable housing can also have important benefits for some of the most vulnerable members of our community, as the report released this week shows.
The environmental performance of Australian housing has improved slowly, associated with changes in minimum building regulations and the creation of subsidies such as solar rebates. This is despite sustainable housing having many documented benefits, including lower (or non-existent) utility bills and greenhouse gas emissions, and improved comfort and health.
Conventional cost-benefit analyses exclude these benefits. That leaves significant gaps in the story that could be used to support investment in sustainable housing.
What did the study assess?Our study involved a three-year, mixed-method evaluation of a small sustainable housing development in Horsham, Victoria. Commissioned by the Victorian Department of Health and Human Services (DHHS), the study used both quantitative and qualitative methods, which are rarely combined to assess housing policy and environmental performance.
Four two-bedroom, nine-star-rated (under the National House Energy Rating Scheme, NatHERS) houses were built to maximise passive solar principles. The design elements and technologies used included (partial) reverse brick-veneer construction, double-glazed windows, solar hot water, a 1.5-kilowatt solar photovoltaic system and a shared 5,000-litre rainwater tank.
The houses were built without air conditioning. They do have ceiling fans and gas heating in the living area.
We evaluated these nine-star houses against seven control houses also in Horsham and built to DHHS standards, with a six-star NatHERS rating. We also compared the results to a DHHS technical model of standard industry practice. We conducted a traditional cost-benefit analysis, technical performance analysis (utility consumption, internal temperature), three rounds of interviews with the householders during different seasons, and a personalised household sustainability assessment.
Through a traditional cost-benefit lens, the nine-star housing was not financially viable for DHHS. Even if DHHS was able to capture the savings to the householders, payback was only achieved within 40 years for one of the four dwellings in a high-energy-price future. This was due to higher-than-expected capital costs for the sustainability initiatives.
Falling short: the conventional cost-benefit outcome for the nine-star houses. RMIT Centre for Urban Research, DHHSHowever, resale value could be up to A$40,000 higher per unit. The technical performance analysis also identified significant benefits for the nine-star households. These included reduced utility consumption and bills. One occupant told us:
Look, I haven’t paid any off my power bill in six months and I’m still in credit.
We found that these households:
were A$1,000 a year better off as a result of reduced utility consumption (including solar feed-in tariff);
purchased 45% less electricity than the control households (and 73% less than the standard industry practice);
consumed 22% less water (30% less than the industry standard);
had 40% less CO₂ environmental impact from power use (63% less than the industry standard); and
- were comfortable with the indoor temperature of their house for 10% more of the time (even without air conditioning).
Extreme weather events magnified the comfort benefits. On a second consecutive day above 41℃, the nine-star houses were up to 16.6℃ cooler (without air conditioning) compared to the department’s standard six-star house (which had air conditioning).
This meant householders could stay at home during heatwaves rather than needing to seek alternative accommodation, which happened sometimes for the control households. One occupant said:
…in summer I would sit down at the supermarket, you know, because it was cool … [Now] I can stay home and veg out.
Temperature in the living rooms of monitored houses and external temperature for January 18-19, 2013. RMIT Centre for Urban Research, DHHS Residents confirm well-being benefitsInterviews with residents highlighted positive social outcomes from living in sustainable housing, which supported the technical data. The benefits they described included improved health and personal finances.
For example, these householders said they had extra spending money due to low (or no) utility bills. This meant they could buy children Christmas presents, avoid personal debt and lay-by, or go on a holiday.
I do go clothes shopping on occasion now instead of thinking, “Oh God, I have to go and lay-by that.”
Householders described how this led to reduced stress and better mental health.
The research demonstrates that the housing sector’s over-reliance on cost-benefit analysis may be overlooking important benefits (and detriments) of different housing arrangements. Combining qualitative and quantitative evaluation methods can help uncover a more detailed and complete picture of how housing affects people’s lives.
Our research also highlights how sustainable housing benefits extend beyond the environment. These flow-on effects can improve the living conditions of some of the most vulnerable members of society. This, in turn, potentially reduces pressure on health and other support systems and sectors.
Combining sustainable and affordable housingOur study is part of an emerging body of research that challenges the idea that sustainable housing is unaffordable.
The evidence increasingly shows that sustainability and good design can improve affordability when fuller cost-benefit analyses are undertaken and non-monetised social, health and well-being benefits are considered.
To date, however, there is limited “real world” research into people living in sustainable housing, particularly in the affordable housing sector. Without more multidisciplinary evaluations of this kind, we are left with an incomplete picture of the benefits of this type of housing.
Such studies will be critically important as Australia seeks to make the transition to a more sustainable future. Climate change and increased livability costs are likely to add to the challenges for social housing organisations and the tenants who depend on their services.
Trivess Moore receives funding from various organisations including the Australian Research Council and Victorian Department of Health and Human Services.
Cecily Maller receives funding from the National Environmental Science Program of the Australian Government, the Australian Research Council, and the Victorian Government's Department of Housing and Human Services. She is affiliated with the Institute of Australian Geographers and The Australian Sociological Association.
Ralph Horne receives funding from various organisations including the Australian Research Council and Victorian Department of Health and Human Services. He is also currently Director of the United Nations Global Compact - Cities Programme.
Yolande Strengers receives funding from the Australian Research Council, Energy Consumers Australia and the Victorian Government's Department of Health and Human Services.
An open letter to the Prime Minister on the climate crisis, from 154 scientists
Dear The Hon. Malcolm Turnbull MP, Prime Minister of Australia,
The following is an open letter signed by 154 Australian atmospheric, marine, environmental, biological and medical scientists, including several leading climatologists, for your and your government’s attention.
There is no Planet BIn July 2016, global temperatures soared to the hottest in the 136 years of the instrumental record, 0.1℃ warmer than previous warm Julys in 2015, 2011 and 2009. It followed a succession of rising temperatures, moving from 0.42℃ above average in 2000, to 0.87℃ above average by 2015.
Developments in the atmosphere-ocean system reported by major climate research organisations (including NASA, the US National Oceanic and Atmospheric Administration, the US National Snow & Ice Data Center, the UK Met Office Hadley Centre, the Tyndall Centre, the Potsdam Institute; the science academics of dozens of nations; and in Australia the CSIRO and Bureau of Meteorology) include:
A rise of atmospheric carbon dioxide levels to 404.39 parts per million (ppm; as of July 2016), an average rise of 3.08 ppm per year. This rate is unprecedented in the geological record of the past 55 million years, and is tracking towards the stability threshold of the Antarctic ice sheet, estimated at around 450ppm atmospheric CO₂.
The rise in greenhouse gas levels in the atmosphere and oceans is leading to an increase in extreme weather events relative to the period 1950-60, including tropical storms such as those in Fiji, Vanuatu and the Philippines, with lives lost and damage estimated in the billions of dollars. In Australia the frequency of extreme weather events has been increasing, and since 2001 the number of extreme heat records has outnumbered extreme cool records by almost three to one for daytime maximum temperatures, and around five to one for night-time minimum temperatures.
Impacts on a similar scale are taking place in the ocean, where the CO₂ rise has caused an increase in acidity from pH 8.2 to 8.1 already. The pH is predicted to decrease to 7.8 by 2100, affecting coral reefs and the marine food chain.
Ice sheet melt rates have been increasing and the rate of sea-level rise has been accelerating, from roughly 1.7mm per year over the past century to 3.2mm per year between 1993 and 2010, and to about 3.5mm per year today. This threatens low-lying islands, deltas and lower river valleys where billions of people live – a problem that is compounded by increased variability of river flows in terms of floods and draughts.
We are concerned that global warming, amplified by feedbacks from polar ice melt, methane release from permafrost, and extensive fires, may become irreversible, including the possible collapse of the Atlantic Meridional Overturning Circulation, a crucial component of the global climate system that transfers heat from the tropics to the North Atlantic.
According to James Hansen, NASA’s former chief climate scientist, “burning all fossil fuels would create a different planet than the one that humanity knows“. Joachim Schellnhuber, Germany’s chief climate scientist, has summed up the situation by saying: “We’re simply talking about the very life support system of this planet.”
We note your broad agreement with this point, in light of your 2010 statement that:
…we are as humans conducting a massive science experiment with this planet. It’s the only planet we have got… We know that the consequences of unchecked global warming would be catastrophic… We as a human species have a deep and abiding obligation to this planet and to the generations that will come after us.
While the Paris Agreement remains unbinding and global warming has received minimal attention in the recent elections, governments worldwide are presiding over a large-scale demise of the planetary ecosystems, which threatens to leave large parts of Earth uninhabitable.
We call on the Australian government to tackle the root causes of an unfolding climate tragedy and do what is required to protect future generations and nature, including meaningful reductions of Australia’s peak carbon emissions and coal exports, while there is still time.
There is no Planet B.
Yours sincerely,
Dr Christine Adams-Hosking, Conservation planner, University of Queensland
Associate Professor Stephen Adelstein, Medical scientist, University of Sydney
Professor Ross Alford, Tropical ecologist, James Cook University
Dr Wallace Ambrose, Archaeological anthropologist, ANU
Dr Martin Anda, Environmental engineer, Murdoch University
Dr Marion Anderston, Geochemist, Monash University
Professor Michael Archer, Paleontologist, UNSW Australia
Dr Leanne Armand, Marine Researcher, Macquarie University
Professor Patricia Armati, Medical scientist, University of Sydney
Professor Owen Atkin, Plant respiration researcher, ANU
Professor Elaine Baker, Marine scientist, University of Sydney
Associate Professor Cathy Banwell, Medical scientist, ANU
Dr Andrew Barnes, Aquatic animal health researcher, University of Queensland
Dr Fiona Beck, Renewable energy researcher, ANU
Dr Tom Beer, Climatic and environmental change researcher, CSIRO
Professor Andrew Blakers, Photovoltaics/energy storage researcher, ANU
Professor Phillip Board, Medical scientist, ANU
Professor Justin Borevitz, Plant geneticist, ANU
Dr Caryl Bosman, Environmental planning researcher, Griffith University
Professor David Bowman, Forestry researcher, University of Tasmania
Dr Timothy Broadribb, Plant Scientist, University of Tasmania
Dr Helen Brown, Environmental health researcher, Curtin University
Dr Tim Brown, Medicine and environment researcher, ANU
Professor Ralf Buckley, Conservation/ecotourism researcher, Griffith University
Dr Florian Busch, Plant scientist, ANU
Dr Jason Byrne, Urban design researcher, Curtin University
Professor Maria Byrne, Marine and developmental biologist, University of Sydney
Dr Martina Calais, Renewable energy researcher, Murdoch University
Associate Professor Craig Carter, Engineering and IT researcher, Murdoch University
Dr Phill Cassey, Ecologist, Adelaide University
Professor Carla Catterall, Ecologist, Griffith University
Dr Juleen Cavanaugh, Biomedical scientist, ANU
Professor Fred Chow, Plant biologist, ANU
Associate Professor David Cohen, Geochemist, UNSW Australia
Professor Steven Cooper, Evolutionary biologist, SA Museum
Professor Rod Connolly, Marine scientist, Griffith University
Professor Jann Conroy, Plant scientist, Western Sydney University
Dr Lucy Coupland, Medical scientist, ANU
Dr Joseph Coventry, Solar energy researcher, ANU
Dr Chris Creagh, Physicist, Murdoch University
Professor Patricia Dale, Environment/planning researcher, Griffith University
Dr Armanda Davies, Planning geographer, Curtin University
Dr Ian Davies, Forestry fire management researcher, ANU
Dr Kirsten Davies, Ethno-ecology and environmental law researcher, Macquarie University
Dr Robert Davis, Vertebrate biologist, Edith Cowan University
Professor Keith Dear, Global health researcher, ANU
Dr Fjalar de Haan, Sustainability researcher, University of Melbourne
Professor Hans Peter Dietz, Medical scientist, Penrith Hospital
Professor Bob Douglas, Medical scientist, ANU
Associate Professor Mark Douglas, Medical scientist, University of Sydney
Dr Jen Drysdale, Climate and energy researcher, University of Melbourne
Professor Angela Dulhunty, Medical scientist, ANU
Professor Robyn Eckersley, Climate change governance researcher, University of Melbourne
Dr Elin Charles Edwards, Environmental geographer, University of Queensland
Professor David Eldridge, Evolutionary biologist, UNSW Australia
Professor David Elsworth, Environmental ecologist, Western Sydney University
Associate Professor Jason Evans, Climate change researcher, UNSW Australia
Dr Isabelle Ferru, Medical scientist, ANU
Professor Tim Flannery, Climate Council
Professor Barry Fox, Ecologist, UNSW Australia
Dr Evan Franklin, Solar energy researcher, ANU
Dr Diego Garcia-Bellido, Paleontologist, University of Adelaide
Dr Stephen Garnett, Conservation and sustainability researcher, Charles Darwin University
Dr John Gillen, Soil scientist, ANU
Dr Andrew Glikson, Paleoclimatologist, ANU
Dr Susan Gould, Climate change researcher, Griffith UNiversity
Professor Colin Groves, Anthropologist, ANU
Dr Huade Guan, Hydro-meteorologist, Flinders University
Professor Neil Gunningham, Global governance researcher, ANU
Dr Asish Hagar, Medical scientist, UNSW Australia
Dr Nina Hall, Sustainable water researcher, University of Queensland
Dr Willow Hallgren, Atmospheric scientist, Griffith University
Dr Elizabeth Hanna, Environmental health researcher, ANU
Associate Professor David Harley, Epidemiologist, ANU
Professor Robert S. Hill, Paleobotanist, University of Adelaide
Professor Ove Hoegh-Guldberg, Marine climatologist and Great Barrier Reef researcher, University of Queensland
Professor Geoff Hope, Archaeologist and natural history researcher, ANU
Associate Professor Michael Howes, Environmental scientist, Griffith University
Professor Lesley Hughes, Climate change and species researcher, University of Adelaide
Dr Paul Humphries, Environmental scientist, Charles Sturt University
Professor Phillip Jenning, Energy researcher, Murdoch University
Professor Darryl Jones, Behavioural ecologist, Griffith University
Dr Hugh Jones, Medical scientist, University of Western Australia
Dr Jochen Kaempf, Physical oceanographer, Flinders University
Professor Jeffrey Keelan, Medical scientist, University of Western Australia
Professor Peter Kershaw, Biogeographer and botanist, Monash University
Dr Carsten Kulheim, Plant physiologist, ANU
Professor Rakkesh Kumar, Medical scientist, UNSW Australia
Dr Lori Lach, Rainforest conservationist, James Cook University
Professor Barry Lacopetta, Medical scientist, University of Western Australia
Professor Trevor Lamb, Medical scientist, ANU
Professor Tony Larkum, Plant biologist, University of Technology Sydney
Dr Annie Lau, Geography and environmental management researcher, University of Quensland
Professor Bill Laurance, Tropical environment and sustainability researcher, James Cook University
Associate Professor Fred Leusch, Soil, water and energy researcher, Griffith University
Professor Andrew Lowe, Plant conservationist, University of Adelaide
Dr Fabio Luciano, Medical scientist, UNSW Australia
Professor Justin Marshall, Marine biologist, University of Queensland
Dr Melanie Massaro, Ecologist and ornithologist, Charles Sturt University
Associate Professor John F. McCarthy, Resource environment researcher, ANU
Dr Allison McInnes, Plant biologist, UTS
AssociateProfessor Andrew McKenzie, Landscape planning researcher, University of Canberra
Dr Kathryn McMahon, Environmental researcher, Edith Cowan University
Professor Andrew Millington, Land change scientist, Flinders University
Professor Angela Moles, Evolutionary ecologist, UNSW Australia
Professor Renee Morris, Medical scientist, UNSW Australia
Professor Barbara Norman, Urban planning researcher, University of Canberra
Professor Nikos Ntoumanis, Behavioural medicine researcher, Curtin University
Dr Bradley Opdyke, Climate historian, ANU
Professor Richard G. Pearson, Marine and tropical biologist, James Cook University
Dr Barrie Pittock, Climate scientist, CSIRO
Dr Jason Potas, Medical scientist, ANU
Professor Susan Prescott, Medical scientist, University of Western Australia
Dr Lynda Prior, Climate researcher, University of Tasmania
_Dr Thomas Prowse, Biologist, University of Adelaide
Professor Marie Ranson, Molecular biologist, University of Wollongong
Professor Steve Redman, Medical scientist, ANU
Associate Professor Tracy Rogers, Evolutionary ecologist, UNSW Australia
Professor Chris Ryan, Eco-innovation researcher, University of Melbourne
Dr Oz Sahnin, Climate change researcher, Griffith University
Associate Professor Peter Sainsbury, Climate and health researcher, University of Sydney
Professor David Sinclair, Medical scientist, UNSW Australia
Dr Tom Sobey, Medical scientist, UNSW Australia
Professor Will Steffen, Climate change researcher, ANU
_Professor Peter Steinberg, Marine scientist, UNSW Australia
Associate Professor Christian Stricker, Medical scientist, ANU
Professor Ian Suthers, Marine biologist, UNSW Australia
Associate Professor Sue Taylor, Medical scientist, University of Western Australia
Dr Sebastian Thomas, Sustainability researcher, University of Melbourne
_Dr Andrew Thomson, Solar researcher, ANU
Associate Professor Thomas Thorsten, Marine biologist, UNSW Australia
Associate Professor Ian Tibbetts, Marine Scientist, University of Queensland
Professor David Tissue, Plant ecophysiologist, Western Sydney University
Professor Matthias Tomczak, Oceanographer, Flinders University
Mr Shane Toohey, Medical scientist, University of Western Australia
Dr Gail Trapp, Medical scientist, UNSW Australia
Professor Patrick Troy, Human ecologist, ANU
Professor Tom Trull, Antarctic, oceans and atmosphere researcher, CSIRO
Professor David Tscharke, Medical scientist, ANU
Professor Chris Turney, Antarctic climatologist, UNSW Australia
Dr Tania Urmee, Renewable energy technologist, Murdoch University
Professor René Vaillancourt, Plant geneticist, University of Tasmania
Professor John Veevers, Earth scientist, Macquarie University
Professor Charlie Veron, Marine scientist, Australian Institute of Marine Science
Professor Phil Waite, Medical scientist, UNSW Australia
Dr Elaine Walker, Physics and energy researcher, Murdoch University
Dr Hayden Washington, Environmental researcher, UNSW Australia
Professor David Watson, Water and society ecologist, Charles Sturt University
Dr Scarla J. Weeks, Biophysical oceanographer, University of Queensland
Professor Adrian Werner, Hydrologist, Flinders University
_Mr Peter Weiske, Medical and environmental scientist, ANU
Dr Jonathan Whale, Energy researcher, Murdoch University
_Associate Professor George Wilson, Wildlife management researcher, ANU
Dr Phillip Zylstra, Forests and fire researcher, University of Wollongong
Andrew Glikson does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond the academic appointment above.
Queensland solar projects that could create 2,600 jobs at risk in federal cuts
Many schemes may not go ahead if the Australian Renewable Energy Agency is defunded in the government’s omnibus bill, ACF warns
Thousands of jobs could be created in Queensland if 10 large-scale solar projects were to receive funding, according to analysis by the Australian Conservation Foundation.
The projects, earmarked for funding by the Australian Renewable Energy Agency (Arena), would create around 2,695 jobs according to the study.
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