25/02/2016

Economics: Current Climate Models Are Grossly Misleading

Nature - Nicholas Stern

Nicholas Stern calls on scientists, engineers and economists to help policymakers by better modelling the immense risks to future generations, and the potential for action.
Sathkira District, Bangladesh, still flooded a year after 2009's Cyclone Aila. Jonas Bendiksen/Magnum
The twin defining challenges of our century are overcoming poverty and managing climate change. If we can tackle these issues together, we will create a secure and prosperous world for generations to come. If we don't, the future is at grave risk.
Researchers across a range of disciplines must work together to help decision-makers in the public, private and non-profit sectors to rise to these challenges. Economists, in particular, need more help from scientists and engineers to devise models that provide better guidance about what will happen if we succeed or if we fail.
As the 2015 Paris agreement on climate change made clear, we must achieve a net-zero carbon economy this century. Doing so will require policies that drive innovation, investment and entrepreneurship. The political will to make the necessary decisions depends partly on improving the analysis and estimates of the economics of climate change. Then the consequences of unmanaged global warming can be weighed much more transparently against the investments and innovations necessary to mitigate it.
Current economic models tend to underestimate seriously both the potential impacts of dangerous climate change and the wider benefits of a transition to low-carbon growth. There is an urgent need for a new generation of models that give a more accurate picture.

Dark impacts
The Fifth Assessment Report of the Intergovernmental Panel on Climate Change (IPCC), published in 2013 and 2014, provided a comprehensive overview of the literature on the costs of action and inaction. But the assessment understated the limitations of the research done so far. Essentially, it reported on a body of literature that had systematically and grossly underestimated the risks of unmanaged climate change. Furthermore, that literature had failed to capture the learning processes and economies of scale involved in radical structural and technical change, and the benefits of reducing fossil-fuel pollution, protecting biodiversity and forests, and so on.
The IPCC pointed out1 that estimates of losses resulting from a 2 °C increase in mean global temperature above pre-industrial levels ranged from 0.2% to 2% of global gross domestic product. It admitted that the global economic impacts are "difficult to estimate" and that attempts depend on a large number of "disputable" assumptions. Moreover, many estimates do not account for factors such as catastrophic changes and tipping points.
It is these hard-to-predict impacts that are the most troubling potential consequences of inaction. The next IPCC report needs to be based on a much more robust body of economics literature, which we must create now. It could make a crucial difference.
Many estimates of economic losses are based on the outputs of integrated assessment models (IAMs). These models attempt to combine the key elements of biophysical and economic systems. This is a worthy endeavour. Sadly, most IAMs struggle to incorporate the scale of the scientific risks, such as the thawing of permafrost, release of methane, and other potential tipping points. Furthermore, many of the largest potential impacts are omitted, such as widespread conflict as a result of large-scale human migration to escape the worst-affected areas.
For instance, there is evidence that temperature increases of 1.5 °C and 2 °C would lead to differing extents of sea-level rise and extreme weather events2, with obvious implications for small island states and coastal communities. These differences are simply not represented in the flawed estimates of economic losses.
IAMs are also used to calculate the social cost of carbon (SCC). They attempt to model the incremental change in, or damage to, global economic output resulting from 1 tonne of anthropogenic carbon dioxide emissions or equivalent. These SCC estimates are used by policymakers in cost–benefit analyses of climate-change-mitigation policies.
Because the IAMs omit so many of the big risks, SCC estimates are often way too low. As a first step, the consequences being assessed should include the damages to human well-being and loss of life beyond simply reduced economic output. And the very large uncertainty, usually involving downward bias, in SCC estimates should always be made explicit.
As the IPCC acknowledged2, published SCC estimates "lie between a few dollars and several hundreds of dollars". These values often depend crucially on the 'discounting' used to translate future costs to current dollars. The high discount rates that predominate essentially assume that benefits to people in the future are much less important than benefits today.
These discount rates are central to any discussion of our hand in the fate of future generations. Most current models of climate-change impacts make two flawed assumptions: that people will be much wealthier in the future and that lives in the future are less important than lives now.
The former assumption ignores the great risks of severe damage and disruption to livelihoods from climate change. The latter assumption is 'discrimination by date of birth'. It is a value judgement that is rarely scrutinized, difficult to defend and in conflict with most moral codes.

Costing transition
The other role of IAMs — to estimate the costs of climate-change mitigation — also suffers from major shortcomings.
The IPCC's mitigation assessment3 concluded from its review of IAM outputs that the reduction in emissions needed to provide a 66% chance of achieving the 2°C goal would cut overall global consumption by between 2.9% and 11.4% in 2100. This was measured relative to a 'business as usual' scenario. Clearly, growth itself can be derailed by climate change from business-as-usual emissions.
So the business-as-usual baseline, against which costs of action are measured, conveys a profoundly misleading message to policymakers that there is an alternative option in which fossil fuels are consumed in ever greater quantities without any negative consequences to growth itself.
Crucially, IAMs generally omit the potentially huge costs of air pollution from fossil fuels — which are saved if alternative fuels are used4. IAMs struggle to describe developments in alternative energy. They fail, in general, to capture the feedback loops in the innovation process that interact across the economy, prompting institutional and behavioural change, possible discoveries and economies of scale. There is empirical evidence, for example, that the geographical location of researchers and inventors can affect whether a firm chooses to do clean or dirty innovation.
"Discount rates are central to any discussion of our hand in the fate of future generations."
The initial investment required to catalyse the transition to a low-carbon pathway might lead to great economic benefits in the long run. These could go well beyond avoided climate risks5. The knowledge spillover from low-carbon innovation into the wider economy — for instance, a battery developed for electric vehicles being used in wheelchairs — seems to be greater overall than that from high-carbon-energy technologies6.
As engineers learn how to install, connect and repair technology cheaply, unit costs fall faster for many new technologies than for existing ones. This has already allowed solar-photovoltaic and onshore-wind technologies to become competitive with natural gas and coal in several locations, even without emissions taxation.
Also influential will be the emergence of new networks, such as the integration of electric-vehicle-energy storage into smart grids, as well as rapid technical progress. And these steps can be accelerated if, for example, consumers change behaviour and demand support for resource efficiency, recycling and pedestrianization. It is clear that much will depend on urban management and design; as cities grow rapidly, damaging infrastructure can become 'locked in'.

What's needed?
There is much that can be done to make the assumptions in standard IAMs more realistic with respect to the scale and nature of damages7, 4. But to give policymakers the reliable information that they need when implementing the Paris agreement, incremental improvements7, 8 to the present generation of IAMs may not be enough.
A comprehensive review of the problems of using IAMs in climate economics5 called for the research community to develop a "third wave" of models. The authors identify various types of model that might offer advances. Two are: dynamic stochastic computable general equilibrium (DSGE) models, and agent-based models (ABMs).
Like current IAMs, DSGE models can explicitly account for uncertainty about the future through the introduction of shocks, for instance, to economic output, consumption or climate damages9. ABMs, by contrast, seek to provide more-realistic representations of socio-economics by simulating the economy through the interactions of a large number of different agents, on the basis of specific rules. ABMs are widely used in finance, but have yet to be seriously applied to climate change. These are promising developments.
Now, a concerted effort is required by the research community to explore as many potential avenues as possible to better estimate the costs of action and inaction on climate change. The IPCC should distil what policymakers need to inform their decision-making. Learned societies and national academies must bring together researchers from a wide range of relevant disciplines to focus attention on improving economic modelling quickly.
Bangladeshi farmers and Cairo city-dwellers are at severe risk of flooding and storms; southern Europe and parts of Africa and the Americas are threatened by desertification. Perhaps hundreds of millions of people may need to migrate as a result, posing an immense risk of conflict.
There is huge potential in future technologies that can drive change. These are omitted or badly underestimated in our current climate modelling — deeply damaging our guidance for policymaking. The well-being and prosperity of future generations are worth more.

References
  1. IPCC. Climate Change 2014: Impacts, Adaptation, and Vulnerability. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (Cambridge Univ. Press, (2014).
  2. Schaeffer, M. et al. Nature Clim. Change 2, 867870 (2012).
  3. IPCC. Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (Cambridge Univ. Press, 2014).
  4. Stern, N. Why are We Waiting?: The Logic, Urgency, and Promise of Tackling Climate Change (MIT Press, 2015).
  5. Aghion, P. et al. Path Dependence, Innovation and the Economics of Climate Change (Grantham Research Inst., 2014).
  6. Dechezleprêtre, A., Martin, R. & Mohnen, M. Knowledge Spillovers from Clean and Dirty Technologies: A Patent Citation Analysis (Grantham Research Inst., 2013).
  7. Dietz, S. & Stern, N. Econ. J. 583, 574620 (2015).
  8. Gillingham, K. et al. National Bureau of Economic Research Working Paper No. 21637 (2015).
  9. Golosov, M. et al. Econometrica 82, 4188 (2014).
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CSIRO Executives To Face Fresh Scrutiny Over Planned Cuts To Climate Science

Fairfax - Peter Hannam
CSIRO chief executive Larry Marshall is expected to face another grilling over the plans to cut 350 scientists. Photo: Daniel Munoz
CSIRO executives are likely to face another grilling over their plans to lop 350 jobs, including many climate scientists, with a Senate committee planning a fresh inquiry next month.
Greens Senator Peter Whish-Wilson will use the scrutiny of budget measures committee that he heads to dig deeper into the strategy behind the cuts – announced on February 4 – at a special hearing "as soon as possible" in Hobart.
"This will give the scientific community and other stakeholders a chance to make submissions," the Tasmanian senator told Fairfax Media.
"Evidence to date suggests the decision was made with little insight or understanding of its consequences."
The Senate also turned the heat up further on CSIRO management on Wednesday by passing an order for the production of documents proposed by deputy Greens leader Larissa Waters.
CSIRO executives will have to provide a series of documents by no later than March 3, including internal communications that saw a proposed cut of about 35 staff to two key climate units doing monitoring and model work swell to almost triple that figure within about a month over Christmas.
The race may be tight, though, with staff in Ocean and Atmosphere and the Land and Water divisions told in separate meetings this week that staff to be made redundant will be informed by March 14, a senior scientist told Fairfax Media.
Fairfax Media sought comment on the Senate moves from CSIRO.
At Senate estimates earlier this month, chief executive Larry Marshall said the two units within the Oceans and Atmosphere division would eventually halve the current levels of 140.
The cuts were necessary to divert more resources to climate change mitigation and adaptation, Dr Marshall said.
Other cuts in the 350 tally, though, are likely to fall heavily on climate change adaptation programs within the Land and Water division.
An all-staff meeting of the division on Tuesday also heard that the promise that the reductions would be made up over two years – as Dr Marshall has stated – would hinge on whether revenue in the division increased, Fairfax Media has learned from a senior researcher who listened in to the discussion.

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Global Ocean Monitoring Program Struggling To Stay Afloat, Warn Scientists

The Guardian

The Argo array of ocean floats supported by 31 countries has 'revolutionised' our understanding of the oceans but its future is uncertain
An Argo float is deployed into the ocean Photograph: CSIRO

Right now, roughly a kilometre below the surface of an ocean near you, a yellow cylinder about the size of a golf bag is taking measurements of the temperature and saltiness of the water.
Every couple of days, the float will drop deeper – down to 2km – and then rise to the surface to transmit its data, before disappearing back into the depths to do the whole thing again.
These floats do this for as long as eight years, until the poor little things die of exhaustion (well, their batteries run out).
There are about 3,800 of these floats scattered across the globe as part of a program called Argo, supported by more than 30 countries.
It's likely you've never heard of Argo and much less likely you've ever seen one of the floats.
But for the last decade, climate scientists and oceanographers have been using the data from these Argo floats to plug a gaping ocean-sized hole in our understanding of global warming.
Scientific papers that use the data from these floats are now appearing in science journals at the rate of about one per day.
But now, scientists are sounding an alarm for the future of this ocean monitoring system. In a commentary in the journal Nature Climate Change, scientists say cracks are starting to appear in the network, largely because of uncertainties over funding.
The commentary predicts it could be only two years before the number of floats drops below a critical threshold of 3,200, which would "considerably undermine the ability of the observing system to monitor and measure the global ocean".
Chart showing forecasted deployments of Argo ocean monitoring floats Photograph: Paul Durack

Australian Dr Paul Durack, of the US government-funded Program for Climate Model Diagnosis and Intercomparison at the Lawrence Livermore National Laboratory, is one of the scientists sounding the alarm. He told me:
Argo is an amazing entity – there are at least 30 nations involved – and it's giving us observations that we have never had before. From about 2005, Argo gave us comprehensive ocean data – if you don't have data you can't say anything. Basically, it has completely changed the game.
Knowing what's happening in the globe's oceans is critical. About 90% of the extra heat from human-caused global warming has ended up there.
Some 31 countries have contributed to the Argo program, with floats costing about US$25,000 each. The United States funds about half, with about 2,142 of the floats currently in circulation.
France is the second-biggest supporter, with 356 floats, followed by Australia with 346. Two-thirds of the global ocean is in the southern hemisphere.
CSIRO's Dr Susan Wijffels is the co-chair of the global Argo program and also the lead scientist for Australia's contribution to Argo.
In the Nature Climate Change commentary, Wijffels says any drop in the number of deployments of floats could spell trouble. She told me:
Argo is fundamental because this all comes back to the heat problem. The key thing that matters for the Earth is how much extra heat is retained in the system.
While we have seen this huge debate over the last 15 years about this so-called 'hiatus', really what Argo shows us is that surface variability [in temperature] is just a re-organisation of heat.
When you get below a couple of hundred metres you see the inexorable growth of global warming happening in the oceans. That's driving a good chunk of the sea level rise. It is telling us what the radiation imbalance is at the top of the atmosphere.
Once that heat and that carbon is down there in the deep ocean it's there for decades – if not longer – and it's locking in that warming. We see that warming in Argo right down to the depths of our measurement – right down to two kilometres and its probably extending further.
Oceanographer Prof Dean Roemmich, of the Scripps Institution of Oceanography at the University of California, San Diego, is also a co-chair of the global Argo program. He told me why there's a fear the comprehensive coverage that Argo gives the world's oceans could be at risk.
In most nations Argo is supported by research funds – rather than as operational oceanography – with no mechanism for inflation or for long-term funding. So far Argo has been successful in increasing the lifetime of floats so that less deployments are needed to maintain the array and bringing in new national programs to sustain the level of total deployments.
Durack points out these advances are difficult to sustain and without them the array would decline. This is an important caution, and along with it we need to continue making the case for Argo's great value in order to increase support from Argo national programs.
Roemmich says Australian scientists are "world leaders in basic research using Argo data, particularly in the Southern Ocean" and that the country also provides critical operational support.
Tim Moltmann is the director of the Integrated Marine Observing System (IMOS), a program funded by the Department of Education and Training and which has provided about half the funding for Australia's Argo program over the past decade.
It has been revolutionary. What we knew about the subsurface ocean before Argo was pretty much limited to what we could get from ships – dropping instruments into the water and getting measurements. You can imagine that's pretty sparse.
What's critically important from an Australian perspective is that from a historical point of view, measurements of the oceans have been dominated by the northern hemisphere.
Argo has been critically important for Australia and the southern hemisphere because it has enabled us to bootstrap our subsurface observing capability in a remarkable way.
That's how we know that ocean heat content is changing. That's how we know that so-called 'pause' [in global warming] isn't really a pause if you look at the whole system, because the heat has been building up in the ocean.
IMOS has funded about half of Australia's Argo effort so far, says Moltmann.
Over the past decade, about 20% of the funding for Australia's Argo program has come from the CSIRO, which also employs about four full-time staff who work to understand and interpret the data and maintain the floats.
Paul Durack is also the scientist who helped to coordinate an open letter signed by almost 3,000 scientists from 60 countries calling on CSIRO to reconsider planned cuts to its climate change research.
He is worried those cuts could make matters worse for Argo. In the commentary, written before the cuts were announced, Durack writes:
Future forecasts are inherently difficult to generate, due to the short-term nature of national budgets, along with unanticipated technology and deployment problems or new technology breakthroughs. These are further confounded by a critical dependence on each and every nation that contributes to the array – and a loss of just one of these key contributors will have a profound impact.
CSIRO chairman David Thodey wrote last week that the agency was "committed" to "contribute to the international Argo floats program".
But when I asked for details of the commitment and whether the cuts would impact on Argo, a CSIRO spokesperson would only say the agency was "currently working through the impacts of the strategic realignment" with staff and research partners.

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