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A nuclear blast and runaway climate change could propel us into the Plutocene. mwreck/Shutterstock.com

On January 27, 2017, the Bulletin of the Atomic Scientists moved the arms of its doomsday clock to 2.5 minutes to midnight – the closest it has been since 1953. Meanwhile, atmospheric carbon dioxide levels now hover above 400 parts per million.

Why are these two facts related? Because they illustrate the two factors that could transport us beyond the Anthropocene – the geological epoch marked by humankind’s fingerprint on the planet – and into yet another new, even more hostile era of our own making.

My new book, titled The Plutocene: Blueprints for a post-Anthropocene Greenhouse Earth, describes the future world we are on course to inhabit, now that it has become clear that we are still busy building nuclear weapons rather than working together to defend our planet.

Read more: An offical welcome to the Anthropocene epoch – but who gets to decide it’s here?.

I have coined the term Plutocene to describe a post-Anthropocene period marked by a plutonium-rich sedimentary layer in the oceans. The Anthropocene is very short, having begun (depending on your definition) either with the Industrial Revolution in about 1750, or with the onset of nuclear weapons and sharply rising greenhouse emissions in the mid-20th century. The future length of the Plutocene would depend on two factors: the half-life of radioactive plutonium-239 of 24,100 years, and how long our CO₂ will stay in the atmosphere – potentially up to 20,000 years.

During the Plutocene, temperatures would be much higher than today. Perhaps they would be similar to those during the Pliocene (2.6 million to 5.3 million years ago), when average temperatures were about 2℃ above those of pre-industrial times, or the Miocene (roughly 5.3 million to 23 million years ago), when average temperatures were another 2℃ warmer than that, and sea levels were 20–40m higher than today.

Under these conditions, population and farming centres in low coastal zones and river valleys would be inundated, and humans would be forced to seek higher latitudes and altitudes to survive – as well as potentially having to contend with the fallout of nuclear conflict. The most extreme scenario is that evolution takes a new turn – one that favours animals best equipped to withstand heat and radiation.

Climates past

While we have a range of tools for studying prehistoric climates, including ice cores and tree rings, these methods do not of course tell us what the future holds.

However, the basic laws of physics, the principles of climate science, and the lessons from past and current climate trends, help us work out the factors that will dictate our future climate.

Broadly speaking, the climate is shaped by three broad factors: trends in solar cycles; the concentration of atmospheric greenhouse gases; and intermittent events such as volcanic eruptions or asteroid impacts.

Solar cycles are readily predicted, and indeed can be seen in the geological record, whereas intermittent events are harder to account for. The factor over which we have the most control is our own greenhouse emissions.

CO₂ levels have previously climbed as high as 2,000 parts per million (ppm), most recently during the early Eocene, roughly 55-45 million years ago. The subsequent decline of CO₂ levels to just a few hundred parts per million then cooled the planet, creating the conditions that allowed Earth’s current inhabitants (much later including humans) to flourish.

But what of the future? Based on these observations, as reported by the Intergovernmental Panel on Climate Change (IPCC), several projections of future climates indicate an extension of the current interglacial period by about 30,000 years, consistent with the longevity of atmospheric CO₂.

If global warming were to reach 4℃, as suggested by Hans Joachim Schellnhuber, chief climate advisor to the German government, the resulting amplification effects on the climate would pose an existential threat both to nature and human civilisation.

Barring effective sequestration of carbon gases, and given amplifying feedback effects from the melting of ice sheets, warming of oceans, and drying out of land surfaces, Earth is bound to reach an average of 4℃ above pre-industrial levels within a time frame to which numerous species, including humans, may hardly be able to adapt. The increase in evaporation from the oceans and thereby water vapour contents of the atmosphere leads to mega-cyclones, mega-floods and super-tropical terrestrial environments. Arid and semi-arid regions would become overheated, severely affecting flora and fauna habitats.

The transition to such conditions is unlikely to be smooth and gradual, but may instead feature sharp transient cool intervals called “stadials”. Increasingly, signs of a possible stadial are being seen south of Greenland.

A close analogy can be drawn between future events and the Eocene-Paleocene Thermal Maximum about 55 million years ago, when release of methane from Earth’s crust resulted in extreme rise in temperature. But as shown below, the current rate of temperature rise is far more rapid – and more akin to the planet-heating effects of an asteroid strike.

Rate of global average temperature rise during (1) the end of the last Ice Age; (2) the Paleocene-Eocene Thermal Maximum; (3) the current bout of global warming; and (4) during an asteroid impact. Author provided Mounting our defence

Defending ourselves from global warming and nuclear disaster requires us to do two things: stop fighting destructive wars, and start fighting to save our planet. There is a range of tactics we can use to help achieve the second goal, including large-scale seagrass cultivation, extensive biochar development, and restoring huge swathes of the world’s forests.

Space exploration is wonderful, but we still only know of one planet that supports life (bacteria possibly excepted). This is our home, and there is currently little prospect of realising science fiction’s visions of an escape from a scorched Earth to some other world.

Read more: What is a pre-industrial climate and why does it matter?.

Yet still we waver. Many media outlets operate in apparent denial of the connection between global warming and extreme weather. Meanwhile, despite diplomatic progress on nuclear weapons, the Sword of Damocles continues to hang over our heads, as 14,900 nuclear warheads sit aimed at one another, waiting for accidental or deliberate release.

If the clock does strike nuclear midnight, and if we don’t take urgent action to defend our planet, life as we know it will not be able to continue. Humans will survive in relatively cold high latitudes and altitudes. A new cycle would begin.

Andrew Glikson does not work for, consult, own shares in or receive funding from any company or organization that would benefit from this article, and has disclosed no relevant affiliations beyond the academic appointment above.

A team of scientists and reef managers say it’s time to consider ‘riskier’ and unconventional ways to save the world’s coral habitats.

As the metaphorical canary in the global warming coalmine goes, the planet’s coral reefs are hard to beat.

Swathes of corals in all tropical basins have been hit by the longest mass bleaching event yet recorded that kicked off in 2014 and ended, at least officially, in June.

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Ripples in the fabric of space-time are sensed again - this time using three different laser systems.

Family rivalry and Brazil’s Catholic church helped miners devastate an indigenous territory that was once a leader in the fight against deforestation. Climate Home reports

The Paiter-Suruí are a tribe of roughly 1,400 people, uncontacted until 1969, who live in the Amazon forest on the border between the Brazilian states of Rondônia and Mato Grosso.

In 2013, they became the first indigenous population in the world to sell carbon credits under the UN’s major anti-deforestation scheme. Then, last year, they discovered the earth beneath their forest was rich with diamonds, and all hell broke loose.

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The BBC is going under the waves with David Attenborough in a second series of Blue Planet, which was first shown in 2001.

Diprotodon, an extinct Ice Age marsupial of Australia, would trek long distances each year for food.

Capital is given emergency warning as polluted air from the continent combines with toxic air at home

The mayor of London, Sadiq Khan, has triggered the capital’s emergency air quality alert as polluted air from the continent combines with toxic air in London to create dangerous levels of pollution.

The alerts will see warnings displayed at bus stops, road signs and on the underground. Khan has also asked TV and radio stations across the capital to warn their viewers and listeners in news bulletins.

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As usual, conservative media outlets distorted a climate science paper to advance the denialist agenda

Last week, Nature Geoscience published a study suggesting that we have a bigger remaining carbon budget than previously thought to keep global warming below the 1.5°C aggressive Paris climate target. Many scientists quickly commented that the paper’s conclusion was based on some questionable assumptions, and this single study shouldn’t be blindly accepted as gospel truth.

Conservative media outlets did even worse than that. They took one part of the paper’s analysis out of context and grossly distorted its conclusions to advance their anti-climate agenda.

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The ex-chief scientist says the government should be made to enshrine a zero-emissions target in law.

Solar projects tendering for Queensland government's 400MW of large-scale renewables contracts will have to add storage to their projects.

Green industrial revolution continues at Whyalla, with Adani Group's 140MW solar farm approved for construction.

The City of Adelaide is now a hub for South Australia’s electric vehicle charging network with eight fast charging stations opening today within a new dedicated EV parking area.

Hackett steps down from twin roles at Redflow as company focuses on new manufacturing facility and cutting costs.

The Parker Solar Probe is going to be the first spacecraft to journey deep into the sun's atmosphere.

Whither coal? India's new electrification scheme will dedicate 80% of $2.5bn budget to rolling out solar and battery banks to rural and remote homes.

The 10 MW Clayhill solar farm and storage facility, developed by Anesco, was officially opened by UK climate change minister Claire Perry.

The price of new-build renewable energy is expected to fall significantly relative to new-build coal energy in coming years.

In a recent Conversation FactCheck I examined the question: “Is coal still cheaper than renewables as an energy source?” In that article, we assessed how things stand today. Now let’s look to the future.

In Australia, 87% of our electricity generation comes from fossil fuels. That’s one of the highest levels of fossil fuel generation in the world.

So we have important decisions to make about how we’ll generate energy as Australia’s fleet of coal-fired power stations reach the end of their operating lives, and as we move to decarbonise the economy to meet our climate goals following the Paris agreement.

What will the cost of coal-fired and renewable energy be in the coming decades? Let’s look at the numbers.

Improvements in technology will make renewables cheaper

As technology and economies of scale improve over time, the initial capital cost of building an energy generator decreases. This is known as the “learning rate”. Improvements in technology are expected to reduce the price of renewables more so than coal in coming years.

The chart below, produced by consulting firm Jacobs Group and published in the recent Finkel review of the National Electricity Market, shows the projected levelised cost of electricity (LCOE) for a range of technologies in 2020, 2030 and 2050.

The chart shows a significant reduction in the cost of solar and wind, and a relatively static cost for mature technologies such as coal and gas. It also shows that large-scale solar photovoltaic (PV) generation, with a faster learning rate, is projected to be cheaper than wind generation from around 2020.

Notes: Numbers in Figure A.1 refer to the average. For each generation technology shown in the chart, the range shows the lowest cost to the highest cost project available in Jacobs’ model, based on the input assumptions in the relevant year. The average is the average cost across the range of projects; it may not be the midpoint between the highest and lowest cost project. Large-scale Solar Photovoltaic includes fixed plate, single and double axis tracking. Large-scale Solar Photovoltaic with storage includes 3 hours storage at 100 per cent capacity. Solar Thermal with storage includes 12 hours storage at 100 per cent capacity. Cost of capital assumptions are consistent with those used in policy cases, that is, without the risk premium applied. The assumptions for the electricity modelling were finalised in February 2017 and do not take into account recent reductions in technology costs (e.g. recent wind farm announcements). Independent Review into the Future Security of the National Electricity Market

Wind prices are already falling rapidly. For example: the graph above shows the 2020 price for wind at A$92 per megawatt-hour (MWh). But when the assumptions for the electricity modelling were finalised in February 2017, that price was already out of date.

In its 2016 Next Generation Renewables Auction, the Australian Capital Territory government secured a fixed price for wind of A$73 per MWh over 20 years (or A$56 per MWh in constant dollars at 3% inflation).

In May 2017, the Victorian renewable energy auction set a record low fixed price for wind of A$50-60 per MWh over 12 years (or A$43-51 per MWh in constant dollars at 3% inflation). This is below the AGL price for electricity from the Silverton wind farm of $65 per MWh fixed over five years.

These long-term renewable contracts are similar to a LCOE, because they extend over a large fraction of the lifetime of the wind farm.

The tables and graph below show a selection of renewable energy long-term contract prices across Australia in recent years, and illustrate a gradual decline in wind energy auction results (in constant 2016 dollars), consistent with improvements in technology and economies of scale.

But this analysis is still based on LCOE comparisons – or what it would cost to use these technologies for a simple “plug and play” replacement of an old generator.

Now let’s price in the cost of changes needed to the entire electricity network to support the use of renewables, and to price in other factors, such as climate change.

Carbon pricing will increase the cost of coal-fired power

The economic, environmental and social costs of greenhouse gas emissions are not included in simple electricity cost calculations, such as the LCOE analysis above. Neither are the costs of other factors, such as the health effects of air particle pollution, or deaths arising from coal mining.

The risk of the possible introduction of carbon emissions mitigation policies can be indirectly factored into the LCOE of coal-fired power through higher rates for the weighted average cost of capital (in other words, higher interest rates for loans).

The Jacobs report to the Finkel Review estimates that the weighted average cost of capital for coal will be 15%, compared with 7% for renewables.

The cost of greenhouse gas emissions can be incorporated more directly into energy prices by putting a price on carbon. Many economists maintain that carbon pricing is the most cost-effective way to reduce global carbon emissions.

One megawatt-hour of coal-fired electricity creates approximately one tonne of carbon dioxide. So even a conservative carbon price of around A$20 per tonne would increase the levelised cost of coal generation by around A$20 per MWh, putting it at almost A$100 per MWh in 2020.

According to the Jacobs analysis, this would make both wind and large-scale photovoltaics – at A$92 and A$91 per MWh, respectively – cheaper than any fossil fuel source from the year 2020.

It’s worth noting here the ultimate inevitability of a price signal on carbon, even if Australia continues to resist the idea of implementing a simple carbon price. Other policies currently under consideration, including some form of a clean energy target, would put similar upward price pressure on coal relative to renewables, while the global move towards carbon pricing will eventually see Australia follow suit or risk imposts on its carbon-exposed exports.

Australia’s grid needs an upgrade

Renewable energy (excluding hydro power) accounted for around 6% of Australia’s energy supply in the 2015-16 financial year. Once renewable energy exceeds say, 50%, of Australia’s total energy supply, the LCOE for renewables should be used with caution.

This is because most renewable energy – like that generated by wind and solar – is intermittent, and needs to be “balanced” (or backed up) in order to be reliable. This requires investment in energy storage. We also need more transmission lines within the electricity grid to ensure ready access to renewable energy and storage in different regions, which increases transmission costs.

And, there are additional engineering requirements, like building “inertia” into the electricity system to maintain voltage and frequency stability. Each additional requirement increases the cost of electricity beyond the levelised cost. But by how much?

Australian National University researchers calculated that the addition of pumped-hydro storage and extra network construction would add a levelised cost of balancing of A$25-30 per MWh to the levelised cost of renewable electricity.

The researchers predicted that eventually a future 100% renewable energy system would have a levelised cost of generation in current dollars of around A$50 per MWh, to which adding the levelised cost of balancing would yield a network-adjusted LCOE of around A$75-80 per MWh.

The Australian National University result is similar to the Jacobs 2050 LCOE prediction for large-scale solar photovoltaic plus pumped hydro of around A$69 per MWh, which doesn’t include extra network costs.

The AEMO 100% Renewables Study indicated that this would add another A$6-10 per MWh, yielding a comparable total in the range A$75-79 per MWh.

This would make a 100% renewables system competitive with new-build supercritical (ultrasupercritical) coal, which, according to the Jacobs calculations in the chart above, would come in at around A$75(80) per MWh between 2020 and 2050.

This projection for supercritical coal is consistent with other studies by the CO2CRC in 2015 (A$80 per MWh) and used by CSIRO in 2017 (A$65-80 per MWh).

So, what’s the bottom line?

By the time renewables dominate electricity supply in Australia, it’s highly likely that a price on carbon will have been introduced. A conservative carbon price of at least A$20 per tonne would put coal in the A$100-plus bracket for a megawatt-hour of electricity. A completely renewable electricity system, at A$75-80 per MWh, would then be more affordable than coal economically, and more desirable environmentally.

Ken Baldwin receives funding from the Australian Research Council.

AGL outlines plans to install 250MW of battery storage at Liddell, and to invest in Bayswater upgrade, new gas generators, demand response, and huge amount of wind and solar to replace Liddell.

Goulburn Council to commission feasibility studies into installing floating solar on government water stores, to slash power costs.