Apr 30, 2014 | Alumni, Food & Water
Eric F. Wood is a hydrologist at Princeton University, well-known for his work in hydrology, climate, and meteorology. He worked as a research scholar in IIASA’s Water program from 1974 to 1976. On 30 April, 2014, he received the European Geophysical Union’s Alfred Wegener Medal in Vienna, Austria.
Eric F. Wood (Credit: Princeton University)
IIASA: How did you get interested in hydrology? What drew you to the field?
EW: I came to IIASA after I finished my doctorate at MIT. I worked in the areas of system analysis and statistics related to water resources. During my first sabbatical leave at the Institute of Hydrology in the UK (now the Center for Hydrology and Ecology), I started to collaborate with Keith Beven on hydrological modeling, which started my transition towards the physical side of the water cycle from the policy and systems analysis side.
A few years later, Robert Gurney, then at NASA and now at the University of Reading (UK), asked if I would be on the Science Advisory Committee for NASA’s Earth Observing System (EOS), which was just starting to be planned. This started my research activities in terrestrial remote sensing. Over the next 25 years these elements have played heavily in my research activities.
What have been the biggest changes in hydrology and earth science over your career – either in terms of new understandings, or in how the science is done?
I can name three huge changes, all inter-connected: One is the increase in computational resources. High performance computing—petabyte computing using 500,000+ cores—is now available that allows us to simulate the terrestrial water and energy budgets using physics resolving land surface models at 100m to 1km resolutions over continental scales, and soon at global scales. The second big change is the availability of remotely sensed observations. There are satellite missions that have lasted far beyond their planned lifetimes, such as the NASA EOS Terra mission, where we now have over 15 years of consistent observations. These observations have been reprocessed as algorithms have improved so we can now use the information to understand environmental change at regional to global scales. The third major shift has been computer storage. Large amounts are available at low prices. We have about 500 Terabytes of RAID storage, and can acquire 150TB for about $10,000 or less. This allows us to store model simulations, remote sensing data, and do analyses that were once impossible. Together, these three changes have transformed my field, and the field of climate change related to terrestrial hydrology. Going forward, we have the data, the projections and analytical tools to look at water security in the 21st Century under environmental change.
What insights has remote sensing brought to hydrology?
Remote sensing offers a global consistency that is unavailable with in-situ observations, and offers observations over regions without ground data. This permits us to analyze hydrologic events such as droughts within a global context, and relate these hydrologic events to other drivers like ENSO (tropical Pacific sea surface temperature anomalies) that affect weather and seasonal climate patterns.
Wood’s work has focused in part on drought and climate change. Badwater, California, a huge salt flat drainage system for the Death Valley desert. Credit: Carolina Reyes (distributed via imaggeo.egu.eu)
What do you see as the key questions currently facing water resources?
The biggest question I see over the next decades is how water security will be affected by environmental change. By environmental change I mean climate change, global urbanization, increasing demand for food, land use and land cover change, pollution, etc. Water security is coupled to food and energy security, and water security is and it is intrinsically linked to the climate system and how that may be changing.
How did IIASA influence your research interests or career?
I made many friendships during my stay at IIASA and I was exposed to world-class research and researchers. This helped me in thinking about important research questions and the types of problems and research that will have impact.
What do you think is the role for IIASA in the worldwide research community?
There are many answers to this question. IIASA plays an important role in providing critical scientific information and analyses related to global issues that go beyond countries – transboundary analyses, and therefore that can provide the scientific basis for global policies. There is an urgent need for more global policies on environmental change and adaptation, food and water security, and environmental refugees, to name just a couple examples in my area.
IIASA has also developed scientific methods and data that can be applied by various groups. For example, IIASA’s world renowned integrated assessment models have been used in climate change modeling for the IPCC and Coupled Model intercomparison Project (CMIP).
Note: This article gives the views of the author, and not the position of the Nexus blog, nor of the International Institute for Applied Systems Analysis.
Apr 15, 2014 | Energy & Climate, Science and Policy
By Jessica Jewell, Research Scholar, IIASA Energy Program
How would action to mitigate climate change affect energy security for countries around the world? In two recent studies that I worked on with colleagues in IIASA’s Energy Program and three other European research centers, we explored this question under a range of different policy scenarios. We found that in the long term – 40 to 90 years from now – climate policies would actually benefit energy security. Our studies showed that policies to limit climate change would lead to lower oil and gas trade. Since both of these fuels are supplied by only a few countries, shifting to other fuels could alleviate concerns for countries which import these energy sources. Our research also shows that a climate-friendly energy system would be more resilient to energy supply and price shocks as well as economic and fossil resource uncertainty.
An oil rig off the coast of California. New research shows that transitioning away from fossil fuels would be good for long-term energy security. Credit: Arby Reed via Flickr: Creative Commons License
Taking action to slow climate change requires a massive change in how our society supplies and uses energy. But achieving a low-carbon energy system – one which releases less greenhouse gases – will only be possible if it doesn’t compromise national energy priorities. One of the main energy priorities for decision-makers is ensuring energy security – that is, the stability and resilience of energy supply and infrastructures.
In our studies, published in Energy Policy and Climatic Change we aimed to figure out whether phasing out fossil fuels would alleviate energy dependence concerns or if decarbonization would simply replace existing vulnerabilities with new ones. Intuitively, addressing climate change would mean increasing renewables and would clearly lead to lower energy dependence. After all, Putin doesn’t own the wind. But would climate policies lead to some unintended consequences? Would oil be phased out only to be replaced with biofuels and Brazil as the new fuel-exporting superpower? And what would happen without climate policies? Would energy trade naturally decline as oil and gas reserves are used up or would it continue to increase?
In our research we used a number of energy scenarios which depict:
- a world with an energy system which continues to develop in the same way it has developed over the last 50 years (i.e. business as usual)
- a world which implements ambitious policies to mitigate climate change and stabilize the climate at 2°C above pre-industrial levels (i.e. climate scenarios).
We looked at each type of world under a range of different policy choices: for example, phasing out nuclear energy or limiting the penetration of solar and wind energy, and including uncertainties such as different growth rates and fossil fuel availability over the long term.
We found that under a business as usual scenario global trade in oil, gas, and coal quadruples. Under a range of different climate-friendly scenarios, trade stabilizes at between half and twice the current level by 2030 and then falls throughout the rest of the century.
Falling trade would have significant implications for the interconnectedness of different world regions. In a business as usual scenario, the energy systems of all world regions remain interconnected, and becomes even more so. But under climate policies, regional energy systems diverge as each region gravitates to its own energy mix. This could decrease states’ investment in existing energy institutions and lead to a massive upheaval in the global energy governance landscape – thus rendering existing institutions obsolete.
Climate policies would affect not only the volume of energy trade but also how and where energy is exported and imported. Today, oil accounts for over 90% of transport demand and there are no real substitutes for fuel cars, trains and planes. Half of all countries in the world import more than 75% of their oil from only a few number of countries. That makes oil the most problematic fuel for energy security (for more on this see the Global Energy Assessment). Under the business-as-usual scenarios, these dynamics get worse over the next few decades.. However, under de-carbonization oil is phased out and no other fuel takes on similarly problematic dynamics.
It’s important to note though that over the short-term, climate policies could make oil even more of a problem: as cheap unconventional resources rise in price due to their carbon intensity, the geographical concentration of oil production would actually rise.
However, over the medium and long-term (three to four decades), climate action would make the energy system much more resilient compared to the business-as-usual case. Resilience, or the capacity for energy systems to respond to disruptions is just as important as avoiding risks such as decreasing energy dependence. Under climate scenarios, the diversity of energy options rises which means all our “energy eggs” would be distributed between different baskets. In addition, the energy system would become less sensitive to fluctuations in GDP, fossil resource assumptions, and energy intensity. This means that a low-carbon energy system would be less exposed to both price and supply shocks.
Reference
Jessica Jewell, Aleh Cherp, Keywan Riahi. (2014). Energy security under de-carbonization scenarios: An assessment framework and evaluation under different technology and policy choices. Energy Policy. Volume 65, February 2014, Pages 743–760 http://www.sciencedirect.com/science/article/pii/S0301421513010744
Aleh Cherp, Jessica Jewell, Vadim Vinichenko, Nico Bauer, Enrica De Cian. (2013). Global energy security under different climate policies, GDP growth rates and fossil resource availabilities. Climatic Change. November 2013. http://link.springer.com/article/10.1007%2Fs10584-013-0950-x
Note: This article gives the views of the author, and not the position of the Nexus blog, nor of the International Institute for Applied Systems Analysis.
Mar 26, 2014 | Energy & Climate, Risk and resilience
By Reinhard Mechler, IIASA Risk, Policy, and Vulnerability Program
On March 25, member countries of the Intergovernmental Panel on Climate Change (IPCC) started discussing the key findings of the second volume of the Fifth Assessment Report (AR5) in Yokohama, Japan. The report focuses on climate-related impacts, risks and adaptation. Once approved by the 150+ governments present, together with IPCC’s other two parts of the report on physical climate science and mitigating greenhouse gases, it will constitute the scientific backbone for informing national and international climate policy over the coming years.
Flooded marketplace in Jakarta. Credit: Charles Wiriawan/Flickr (Creative Commons License)
A key aspect in climate adaptation is dealing with extreme events including natural disasters. It has become clear that extreme event risk constitutes a large part of the adaptation problem, particularly for developing countries and communities.
Despite this growing awareness, the international adaptation policy process is moving forward only slowly. Specifically, there is need for concrete advice for the Loss and Damage Mechanism, the main vehicle under the Climate Convention for dealing with climate-related impacts, which was agreed in Warsaw at the last Conference of the Parties in late 2013
In our commentary, published today in Nature Climate Change with colleagues from LSE, IVM and Deltares, we suggest that better understanding climate-related disaster risk and risk management can inform effective action on climate adaptation and point a way forward for policy and practice.
A key to moving forward is an actionable concept of risk. This involves identifying efficient and acceptable interventions based on recurrency of hazards—a concept known as risk layering. For example, for flood risk, this could mean identifying physical flood protection to deal with more frequent events, considering risk financing for infrequent disasters as well as relying on public and international compensation for extreme catastrophes. Risk layering overall points towards considering risk comprehensively as determined by climatic and non-climatic factors as well as considering portfolios of options that manage risks today and in the future.
The concept of risk layering underlies many areas of risk policy and management in agriculture, finance and insurance. It has been applied for disaster risks, mostly for insurance options, but not informed thinking on comprehensive risk management portfolios. Such broad understanding of risk management can also be helpful in identifying risks that are beyond adaptation–meriting international support, such as from the Green Climate Fund.
Climate risk management has now moved beyond theory. As one example, the megacity of Jakarta currently is setting up a multi-billion dollar program to manage increasing risk from sea level rise with large levees. This effort is integrated with a concern for managing flood risk and land subsidence, which are shaped by non-climatic factors, such as unplanned urbanization. The effort, therefore, involves options to implement acceptable building and zoning regulations for reducing exposure and vulnerability of houses and infrastructure to flooding.
Many policy-and implementation-specific questions remain. Over the coming months, IIASA researchers and our network will take the agenda on climate risk management forward with a focus on informing policy as well as providing actionable information on the ground.
Reference
Reinhard Mechler, Laurens M. Bouwer, Joanne Linnerooth-Bayer, Stefan Hochrainer-Stigler, Jeroen C. J. H. Aerts, Swenja Surminski & Keith Williges. 2014. Managing unnatural disaster risk from climate extremes. Nature Climate Change. March 26, 2014. http://www.nature.com/nclimate/journal/v4/n4/full/nclimate2137.html
Note: This article gives the views of the author, and not the position of the Nexus blog, nor of the International Institute for Applied Systems Analysis.
Mar 12, 2014 | IIASA Network, Science and Policy
Jeffrey D. Sachs, Director of the Earth Institute at Columbia University and Director of the UN Sustainable Development Solutions Network is an expert on economics, development, and sustainability, and a founding member of IIASA and European Forum Alpbach’s Global Think Tank, which is holding its first meeting in Laxenburg this week.
On Wednesday, 12 March Sachs will give a public lecture on the topic at the Austrian Academy of Sciences in Vienna.
Jeff Sachs speaks at the Alpbach Forum in 2013. Photo Credit: European Forum Alpbach
IIASA: Your work spans a large area of research: from economics, to Earth science, to sustainable development. What is the common thread that ties all this together?
JS: The common thread is the challenge that we face on the planet. We can no longer separate economic, environment, and social challenges because we find that if we try to pursue any one of those alone, we end up jeopardizing the others.
For too long, economists have focused simply on economic growth, and clearly that strategy by now has put Earth and humanity at great peril. There’s no shortcut anymore. We have to be able to combine a vision that includes all the major dimensions of the complicated global reality that we face. Economics, divided societies, environmental crises, and rapidly changing geopolitics. It’s not simple to integrate all of these different areas. Our traditional intellectual disciplines do not accomplish that.
IIASA has been one of the world’s leading champions of this kind of integrated vision. Systems thinking applied to massive human problems, bringing together very diverse areas of natural science, social science, and I would say ethical considerations as well. This kind of holistic approach is central to IIASA’s whole strategy. That’s one of the reasons I’m so proud of my connection to the Institute.
What do you see as the biggest problems facing our planet?
We have become an enormously crowded and interconnected global society overnight, because of the technological reach of our economies and because of the remarkable growth of the world’s population during the last century. With 7.2 billion people on the planet now, we are putting vast parts of the biosphere and human well-being at dire risk. We are only slowly waking up to this reality.
All of history, humans have faced local challenges, but we have never faced such a confluence of massive global challenges at the same time. We don’t yet have the institutions, the insight, or the moral outlook to handle this set of challenges, and yet they are bearing down on us very fast.
In your lecture you’ll argue that it is realistic to think we could solve many of these challenges, for example, ending extreme poverty. What would need to be done to accomplish that goal, and why do you think it can be done?
When one thinks about the challenge of ending poverty you quickly realize that while the challenge is great, we also have unique positive opportunities. With the revolutions in communications technology, communities that until five years ago were isolated, impoverished, and with little prospect of escaping from poverty are now connected to global information, as well as to local markets and health clinics. Schoolchildren can get access to the world of information online. Finance has come to rural areas through mobile banking. All of these are examples of the kinds of breakthroughs that are now possible in addressing what have been extraordinarily tough problems of poverty.
We also see the poverty rate coming down now at an unprecedented speed, even in some of the poorest places on the planet. Major advances have been achieved in East Asia during the past quarter century, and increasingly, Africa too is now finally turning the corner on extreme poverty. I have argued that we could mobilize technologies and use directed investments in public health, education, infrastructure, and agriculture to make a decisive breakthrough within our generation.
In my book, “The End of Poverty,” I said that by 2025 we could end extreme poverty. I am afraid that the date is slipping a little because of the lack of concerted effort, but it’s notable for me and gratifying that the World Bank this past year adopted formally the goal of ending extreme poverty by the year 2030. And I believe that the United Nations member states will also adopt such a goal next year when they create the new Sustainable Development Goals or SDGs.
There are two huge risks that could absolutely defeat this possibility. One is the still greatly excessive population growth in some of the world’s poorest countries. The second is climate change, which left out of control will devastate large parts of the world including regions where many of the world’s poorest people live, for instance the arid regions of the world.
What about climate change? Do you think it’s really possible, at this point, to limit climate change to the internationally agreed target of 2 degrees?
I believe that we are at the very last chance to reach that goal. We have cliff ahead of us, with a sign that says, “Do not go beyond this point.” This point is the 2 degrees centigrade limit. We know from all the physical evidence and all the economic trends that we’re just within a hair’s width of exhausting the possibility of meeting that goal. And I worry that if we fail to achieve that goal we are going to slide very far and very fast down the mountainside, as it were. The world is negotiating a climate agreement in Paris in December 2015, and I believe that’s the very last chance to achieve the 2 degree centigrade goal.
I am not especially optimistic, but I don’t think that all is lost yet. Much depends on a much greater seriousness in the next year and ten months than we have shown in the last 22 years since the climate treaty was adopted.
Your lecture is entitled “The Age of Sustainable Development” what do you mean by that term? Why is now the time to be thinking about these topics?
I argue that we have entered an era when the concept of sustainable development has become the necessary concept for our time. When I say sustainable development, I mean on the analytical side the integrated vision of economic, social, and environmental dynamics; and on the normative side the shared goals of economic prosperity, social inclusion, and environmental sustainability. I believe that we have a reasonable chance that this will be formally recognized by the UN member states in 2015, when they formally adopt the new Sustainable Development Goals.
My talk in Vienna is about why the concept of sustainable development is so important, and what it means. It’s not a household phrase, and I think there is a tremendous amount of public education that will be needed to understand what the opportunities are and what the threats that we face in this generation are. My basic point is that every generation faces its distinct challenges and sustainable development is our distinct challenge.
What do you see as the role for researchers and for institutions like IIASA in solving these global challenges?
I believe that these problems are inherently complex because they are about managing interconnected complex systems. There’s nothing simple about the world economy, nothing simple about global social dynamics, and nothing simple about interconnected Earth systems. And yet we have to master the risks that attend to each of those and the interconnections among them. It’s quite obvious in that regard that IIASA has a unique role to play. IIASA has been in the forefront of climate modeling, demographic modeling, and agricultural modeling for many years. I’ve been a huge admirer of the Institute’s work, and I look forward to working more closely with IIASA in the future.
I’ve been tasked by UN Secretary General Ban Ki-moon with helping to organize a global network of problem solving on sustainable development. This initiative is called the Sustainable Development Solutions Network (SDSN). IIASA will be a very important member and I would say leader of that effort, and IIASA’s Director General, Pavel Kabat, is a member of the leadership council of the SDSN. We have already begun to strategize on this with Pavel Kabat, IIASA Deputy Director General Nebojsa Nakicenovic, and many of IIASA’s world class researchers. There’s a tremendous timely opportunity to work with governments around the world and work with the United Nations to help identify safe pathways ahead.
Oct 2, 2013 | Alumni, Energy & Climate, Science and Policy
By Anthony Patt, ETH Zurich and IIASA (From ETH-Klimablog)
The first of three working group reports of the Intergovernmental Panel on Climate Change (IPCC) was made public last Friday. Previous reports served as guidepost for climate policy development. And yet some policies were clearly more effective than others.
Over the next several months, the IPCC will release a series of three volumes, one from each of its three working groups, together constituting its Fifth Assessment Report (AR5). The Working Group (WG) 1 report, on the science of climate change, was just published, while reports from WGs 2 and 3, covering climate impacts and adaptation, and the challenge of reducing or stopping climate change, respectively, appear in March and April of 2014.
Established by the United Nations in 1988, the role of the IPCC is to assess the state of the science, communicating it in a manner that is useful to policy-makers. Three of the previous four assessment reports have come at critical times in climate policy development. The first two supported negotiations of the current global treaty and its first major revision. The Nobel Peace Prize winning Fourth Assessment Report (AR4) was released in 2007, intended to guide the negotiations to the successor to Kyoto.
The AR4 delivered a convincing two part message: that to avoid dangerous climate change the world must embark on a pathway completely eliminating greenhouse gas emissions from industry and land use change by the second half of this century, and that such a pathway is both technically and economically feasible. Many expected this message to lead to a successful negotiation process to be completed in Copenhagen in 2009.
International climate negotiations have made little progress, but the IPCC still has value, argues Patt.
But negotiators failed to reach an agreement in Copenhagen, and have made remarkably little progress in the four years since. Moreover, both the recently published AR5 WG1 report and early drafts of the WG2 report on climate impacts and adaptation suggest that their findings will strengthen those from AR4, but will not add anything dramatically new. Some say that the IPCC is no longer of any value. I disagree, for two reasons.
First, the most ambitious policy developments are now happening at the national level, with countries like Germany, Switzerland, and even the United States planning exactly the kind of transition away from fossil fuels and high emissions pathways that the AR4 suggested was both necessary and possible.1 There is reason to believe that the actions of this smaller number of countries will deliver the technological progress to make a global transition possible. Without the AR4, it is easy to imagine such countries having behaved differently, while the AR5 WGs 1 and 2 reports ought to provide added justification.
Second, deep differences of opinion have emerged concerning the best policies to achieve national decarbonization goals. Ten years ago, almost all analysts were convinced that carbon markets, i.e. trading in CO2 emissions certificates, represented the ideal policy instrument. But these have worked poorly, while portfolios of other instruments, including subsidies and regulations, have exceeded expectations. Researchers have studied these outcomes.e.g. 2 They have found, for example, that the more successful policy instruments are those that work to minimize the risks that investors in new technologies face.
The AR5 makes clear that an energy system transition remains necessary, and indeed now appears even more urgent than it did a few years ago. It is now possible for the IPCC, in its WG3 report, to provide a critical appraisal of alternative strategies. This is badly needed.
This post was originally published on the ETH Zurich Klimablog (in German).
1. Lilliestam, J. et al. An alternative to a global climate deal may be unfolding before our eyes. Clim. Dev. 4, 1–4 (2012).
2. Peters, M., Schneider, M., Griesshaber, T. & Hoffmann, V. H. The impact of technology-push and demand-pull policies on technical change – Does the locus of policies matter? Res. Policy 41, 1296–1308 (2012).
About the author
Anthony Patt is Professor at ETH Zurich, and a Guest Research Scholar in IIASA’s Program on Risk, Policy and Vulnerability, where he serves as head of the Decisions and Governance Research Group. His research is on the effectiveness of policies at addressing risks and uncertainties in the area of climate change, considering both the restructuring of energy systems and adapting to climate impacts and vulnerabilities. Read more>>
Note: This article gives the views of the author, and not the position of the Nexus blog, nor of the International Institute for Applied Systems Analysis.
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