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The Climate Tipping Point and Timeline ... Accelerated
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Discussions of our proximity to a "global tipping point" on climate have now become commonplace.
Today the carbon dioxide concentration in the atmosphere is about 385 parts per million -- more than 100 parts per million higher than before the Industrial Revolution. Just when and where the climate will begin to change in large, unpredictable ways remains a threat that all our environmental models say is coming, even if they cannot be forecast with any real accuracy.
James Hansen, the tremendously well-respected climate scientist and director of the NASA Goddard institute for Space Studies, has often been quoted on this topic.
"We don't understand how fast ice sheets can respond," Hansen said in a podcast interview with Earth & Sky. "But what we're learning is that they're responding a lot faster than we realized even a few years ago. So I think that we're getting close to the point of no return, and that's why we have to begin to make changes within the next few years, or we very well may be beyond the point of no return."
These tipping points are not confined to ice, but relate to ocean temperatures and fisheries and coral survivability, severe storms such as Hurricane Katrina (no matter what was the climatological origin of Katrina itself), devastating forest fires and heat waves. Around each of these issues, and indeed many more, the same story can be heard: clear evidence exists that the planet is changing -- often unpredictably. What has been clear, however, is that the rate of change is faster than even the most aggressive models indicate.
Two points are of greatest underlying concern. First, the ability of the planetary system -- notably the carbon "sinks" of the forests and the 800-pound gorilla in the room -- the oceans -- are slowing in their ability and capacity to absorb added carbon emissions. That is a problem, to say the least. What is also a problem is that our one collective success story -- something termed 'decarbonization' -- has slowed to a halt.
Decarbonization, the process of making our economic engine more carbon efficient, had been improving globally for decades. This change was largely due to greater industrial efficiency -- making products with less waste and less energy inputs is simply good business -- and the progression of energy efficiency efforts in a number of cities, states, and nations.
Now, we see that over the last eight to 10 years, that pace of improvement -- roughly 1 percent per year globally, and as much as 4 percent to 6 percent per year in some of the most efficient nations and/or during spells of enhanced innovation -- has stagnated. This is a disaster on many levels. First it means that in a world with a growing economy emissions are rising fairly rapidly, and in a global economy that is slowing, few energy policy-makers will have the leeway to implement aggressive new programs -- as we need -- for fear of contributing to a weak economic system.
This last point, of course, turns out to be factually incorrect (efficiency is good for business), but yet it remains widespread in the psyche of many stewards of energy and industrial policy.
This trend is deeply troubling on its own, particularly in light of the economic benefits of using less materials and fuels to grow the economy. It is equally troubling because of the wealth of technologies and policies available to encourage the deployment of energy efficient practices.
A second lurking issue, however, is what this means for all the individual climate protection plans that are under development or early implementation in individual U.S. states and regions, such as California and the Northeast, and in a number of nations, such as Germany, Japan and New Zealand, among others.
With the rate of decarbonization slowing or coming to a halt -- just when the climatic consensus agrees that we are now truly in the key window of time where our choices will dictate our collective climate future -- the ability to "simply" accelerate a slowly evolving trend will weaken.
Policy tipping points may follow, or in some cases lead technological development and deployment tipping points, but what is clear is that the ecological tipping point looms all that much closer when even the positive energy and economic trends slow or stop.
Green-Biz Editor-at-Large Daniel M. Kammen is the Class of 1935 Distinguished Professor of Energy at the University of California. He co-directs the Berkeley Institute of the Environment and is founding director of the Renewable and Appropriate Energy Laboratory. Kammen has served as a lead author for the Intergovernmental Panel on Climate Change, which shared the 2007 Nobel Peace Prize. He has appointments in the Energy and Resources Group and the Goldman School of Public Policy.
Recent Blogs by Daniel Kammen
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At a recent Capitol Hill hearing I was surprised to learn that it was far from common knowledge just how competitive wind power has become. As a result, a bit of a data and price update memo may be of use, even to those who follow the industry. In addition, I will summarize the data on a few of the least cost wind farms in the nation. Wind energy in the United States has continued to grow, and represented 19 percent of the new nameplate capacity added to the electrical grid in 2006 . With a total cumulative U.S. capacity of 11,575 MW (1 percent of total U.S. nameplate capacity) at the end of 2006, wind energy is now often directly cost competitive with fossil-fuel generation, and at times is a least-cost supply option. Representative Wind Project and Wind Power Costs Lawrence Berkeley
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The risks of climate change and, of course, high oil prices have unleashed a wave of interest and commitment to changing our energy economy that, perhaps, could safeguard the planet. City, state, federal and international proposals and legislation are today all in play -- and in flux -- to lay out targets for greenhouse gas reductions. Some of the most notable are the 25 percent reduction in GHG emissions by 2025 and the 80 percent reduction by 2050 that California has adopted, the 70 percent or more reductions proposed in the United Kingdom, New Zealand, and the Japanese proposals, and the 100 percent fossil-fuel-free plans of Sweden, and a number of progressive cities intent on making climate-wise statements. How these diverse and ambitious plans pan out is anybody's guess -- or more
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Over the next five decades progress to meaningfully address the risk of significant climate change will require an estimated 80 percent, or more, reduction in the global emissions of greenhouse gases. From the baseline in 2007 of over seven billion tons of greenhouse gas emissions, three-quarters of which comes from fossil fuel combustion (with the remainder largely from land conversion and forest burning), the reductions required are from a global emissions portfolio that is currently increasing. As the largest current emitter, at roughly 25 percent of the global total -- but more importantly as the nation with the largest energy resource and research base to affect change -- the United States and its inaction on climate protection for the last several years is poised to play a critical
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Energy and climate are now all over the news these days. Remarkable agreements between many an erstwhile nemesis -- Democrat and Republican, environmentalist and venture capitalist, public official and industry leader, evangelist and reductionist/rationalist/scientist/atheist -- show that they are now, roughly, on the same wavelength. In fact, the convergence is so strong that there is an evolving common international language around the need to investigate not just the science of global warming, but the specific local impacts of change -- from flooding to Great Britain, to hurricanes in the United States, to changes in ocean chemistry and coral growth. Global warming has, for many become a common language of carbon management. There is a recognized need to explore the mechanisms of
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Solar photovolaics (PV) have undergone a remarkable evolution, really a transformation, since the beginning of the industry in the 1960s. Initially solar was so expensive -- well over $100 per kilowatt hour -- that only super-high value or remote applications, such as satellite and spacecraft missions, could be justified. Following the OPEC embargoes of the 1970s, a wave of investment took place in the industry that, while brief, helped to bring a number of largely silicon-based technologies to niche markets. Since then scientific and materials engineering progress in the solar field has been steady, with an evolution away from silicon as the only material, to a truly exciting and promising range of plastic, thin film, nano-based, and organic cells. While the potential for solar has