Energy

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Petropolitics

Petropolitics

Petroleum Development, Markets and Regulations, Alberta as an Illustrative History
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L'Alberta Autophage

L'Alberta Autophage

Identités, mythes et discours du pétrole dans l'Ouest canadien
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Cocktail Party Guide to Green Energy

Cocktail Party Guide to Green Energy

Everything you need to know to converse intelligently about alternative energy
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Mad Like Tesla

Mad Like Tesla

Underdog Inventors and their Relentless Pursuit of Clean Energy
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I will never forget a private meeting I attended in Toronto on May 8, 2009, with British scientist James Lovelock, whose Gaia theory explains the Earth’s biosphere as a self–regulating entity quite capable of adapting to climate change. Humans, however, will be, in his view, a casualty of that adaptation. Commenting on the impact of climate change over the next few decades, Lovelock, two months shy of his 90th birthday, painted a shockingly grim picture. “Anything that overgrows its resources gets smacked back down,” he told us. “I foresee a loss of as much as 80 or 90 percent of the people on Earth by the end of the century. It’s a distinct possibility, and I don’t think there is much we can do to stop it. You have to make sure those who remain will be able to survive it.” I still recall looking around that room at a dozen or so people seized with despair as they listened to this otherwise lovable old man throw in the towel on behalf of humanity.16 Lovelock’s perspective may be extreme in its hopelessness, but you get the picture — we’re heading in the wrong direction on energy and need to change how we use it and where we get it.

 

Harvard University professor John Holdren, science and technology advisor to U.S. President Barack Obama and a former president of the American Association for the Advancement of Science, put it succinctly when he outlined the three choices we have in our faceoff against climate change: mitigation, adaptation, or suffering. “We’re going to do some of each,” he said. “The question is what the mix is going to be. The more mitigation we do, the less adaptation will be required and the less suffering there will be.”17 The need to reduce our reliance on fossil fuels, become more efficient in how we use energy, and increase our use of low–carbon technologies — the core part of any mitigation strategy — has sparked an era of energy innovation that even Nikola Tesla would find unimaginable. “Scientists, engineers, and entrepreneurs across the globe are responding with unprecedented innovation,” according to Christopher Flavin, president of the Worldwatch Institute, an energy and environmental think tank based out of Washington, D.C. “Overnight, the energy business has begun to resemble the it industry more than it does the energy industry of the past.”18

Another motivating factor relates to energy security. There’s a growing recognition out there that the fossil fuels we have come to depend on to power our economies are going to become more expensive and, from a price perspective, more volatile. I don’t think we’ll ever run out of fossil fuels, even though they are non–renewable. That’s because the cost of finding and extracting and bringing them to market is only going one way: up. We’ll simply start using less and less as they lose their competitive edge over alternative energy sources or technologies that help us use energy more efficiently. Creating climate policies that put a meaningful price on carbon will only accelerate this transition. “It should be apparent by now that the future is not going to look like the present. It simply cannot,” wrote geoscientist J. David Hughes, who spent 32 years as a scientist with the Geological Survey of Canada.19 Take oil — the cheap, easy–to–drill stuff is running out, and increasingly we’re relying on the more expensive sources that are harder and more energy–intensive to extract, where they’re not kept off limits to exploration. With China, India, and other emerging economies jacking up demand for fossil fuels, our current situation is not sustainable. “The party’s coming to an end,” warned Hughes.

This battle against climate change and concern over the rising volatility of fossil fuel markets, together with projections that the world’s population will reach nine billion by 2050, have major economic implications. One, which British economist Nicholas Stern drew attention to in 2006, is the cost of inaction that under a worse–case scenario would amount to trillions of dollars of lost global gdp.20 The cost of action would be small by comparison, Stern concluded. The second economic implication relates to the new industries and technologies — and jobs — that will be created as we tackle these growing problems. Already, countries are jockeying for position to become global leaders in a new “green economy,” and clean technology is the world’s fastest growing investment segment. “The green economy is poised to be the mother of all markets, the economic investment opportunity of a lifetime, because it has become so fundamental,” Lois Quam, founder of strategic consulting firm Tysvar and former managing director of venture capital firm Piper Jaffray, told New York Times columnist Thomas Friedman. “To find an equivalent economic transformation, you have to go back to the Industrial Revolution.”21

Clearly, there’s never been a greater need for new ideas and risk–taking, even in the presence of what may seem impossible or unlikely. Tesla, if he lived today and wasn’t trapped in a mental institution, would have been in his element. Does this “need” mean the transition to clean energy sources and technologies will come faster than past energy transitions? It remains to be seen. What is becoming evident is that the energy transition currently in play isn’t about moving from one dominant fuel or technology to another; it’s about moving from a handful of dominant sources to hundreds. “My strategy on energy technology is to build robustness, to build a portfolio,” says sdtc’s Whittaker. “Is there a single technology that’s going to save us? I wouldn’t count on it. It’s got to be a whole bunch of little things.” We like to think about silver bullets, but, to borrow what is perhaps an overused analogy, we should be thinking about silver buckshot — small projectiles moving together and capable of hitting a much wider target. And we don’t need to wait for new breakthroughs before we pull the trigger. Much can be accomplished over the next two decades by more aggressively deploying technologies we have today, including wind, co–generation, geothermal, solar– thermal power, solar photovoltaics, all–electric and hybrid–electric vehicles, second–generation biofuels, and ground–source heat pumps. (For context, discussion of some of these technologies is included in the chapters that follow.) Just as important are the policies needed to support their widespread deployment. “You need intelligent government regulations infinitely more than you need a massive effort to find breakthrough technologies,” says climate blogger Joseph Romm, who was acting assistant secretary of the U.S. Department of Energy during the Clinton administration.22

I agree with Romm: the search for breakthroughs shouldn’t distract us from what we can and must accomplish now. At the same time, the hunt for true breakthroughs, as rare as they may be, is still necessary to sustain us over the long term. We need both leaps and incremental steps. The individual efforts profiled in this book may prove an “impossible waste of time.” They may lead to dead ends. Whatever the outcome, there is immense value in the journey. The left–behind morsels of innovations won’t necessarily go to waste. They can be picked up and used by others who embark on their own ambitious journeys. But there’s also a chance these efforts will lead to triumph. And perhaps years, but likely decades, from now we or our children will know, in hindsight, the degree to which these innovators’ labors improved our lives.

Interviewed for an article that appeared on August 22, 1937, in the New York Herald Tribune, Tesla — 81 years old at the time, less than six years before his death — looked back on his life and seemed quite satisfied that he had repeatedly proved his doubters wrong. “They laughed in 1896 … when I told them about cosmic rays. They jeered 35 years ago when I discovered the rotating field principle of alternating currents. They called me crazy when I predicted the radio. And when I sent the first impulse around the world, they said it couldn’t be done.”23

They have often been wrong.

NOTES
16 Lovelock told the U.K.’s Guardian (March 29, 2010) that humans aren’t clever enough to deal with climate change and that the failures of democracy partly explain our human inertia on the issue. His comment about cleverness is not a reflection on our ability to invent and innovation. Rather, he’s being critical of the institutions we have created, which are ineffective in dealing with an issue as complex as climate change.
17 Oxfam, “Adapting to Climate Change.” May 29, 2007.
18 Christopher Flavin, “Renewable Surge Despite Economic Crisis,” WorldWatch Institute. May 15, 2009. http://www.worldwatch.org/node/6111.
19 J. David Hughes, “The Energy Issue,” Carbon Shift (Toronto: Random House Canada, 2009), 58–96.
20 Nicholas Stern, “The Stern Review on the Economics of Climate Change,” U.K. government publication. October 30, 2006.
21 Thomas Friedman, Hot, Flat, and Crowded (New York: Farrar, Straus and Giroux, 2008), 172.
22 Joseph Romm, “Breaking the Technology Breakthrough Myth … ,” ClimateProgress.org. April 9, 2008.
23 John J. O’Neill, “In the Realm of Science: Tesla, who predicted radio, now looks forward to sending waves to the Moon,” New York Herald Tribune. August 22, 1937.

 

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Carbon Shift

Carbon Shift

How Peak Oil and the Climate Crisis Will Change Canada (and Our Lives)
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Foreward
Civilizations are built on knowledge, population – and energy. They thrive only when a good balance is struck between these three, a balance dependent (like that of a bicycle) on motion, which is to say on growth. Human successes are always taken from the past or borrowed from the future: sooner or later the bike runs out of road. The first humans evolved by devouring the great wild beasts that once roamed all parts of the Earth. When they exhausted this primordial energy hoard at the end of the last ice age, they starved; and the humble survivors – our ancestors – became more and more dependent on plants.

Over time, early civilizations arose with the development of systematic agriculture. Through crop breeding, animal husbandry, deforestation and irrigation, they concentrated the energy of soil and seeds into the muscle power of domesticated animals and equally domesticated human beings. Towns, cities, governments and priesthoods rose like pyramids on a broadening agrarian base. Despite booms and busts along the way, humanity grew at an ever-increasing rate, especially after the crops of the Americas (such as maize and potatoes) spread around the world. By some two hundred years ago, human beings had reached the maximum number who could feed themselves by muscle power and pre-industrial machinery. That number was about one billion.

What has allowed us to soar nearly sevenfold since then was not any breakthrough in new food: all our crops are ancient; we have raised yields by tinkering, but we have developed no new staples from scratch since prehistoric times. The breakthrough was in energy – in finding new ways to use the vast stocks of fossil carbon that Nature had buried under the planet’s skin long before the first mammal crawled upon it.

We tend to think of the looming energy crisis in terms of cars, factories, heating and air conditioning, but the first thing to keep in mind is that fossil fuels are feeding us. We all know that coal and oil drive the tractors, trains, trucks, ships and freezers that grow, store and move food from farm to city, nation to nation. But how many are aware that we have literally been eating oil and gas for more than a hundred years? Fossil carbon is a prime ingredient of the artificial fertilizers that have sidestepped the decline of natural fertility each time a crop is taken off a field. A two-century carbon binge has allowed mankind to fill its planet way beyond the natural carrying capacity for feckless, reckless, self-indulgent apes. If we run out of carbon or fail to find good substitutes, we are back to dung and muscle power. Billions will die.

An absolute shortage of fossil energy is still a long way off. But the amount that can be easily, cheaply and above all safely exploited is indeed running low. Because of carbon dioxide’s effect on climate, an abundance of carbon fuel – especially in its dirtier forms such as coal and tar sand – is far more dangerous than a dearth. Long before fossil fuel gets truly scarce, its consumption will overthrow the predictable weather patterns on which all farming has relied for the past ten thousand years. In short, the industrial carbon economy has turned out to be what I call a “progress trap” – a seductive and seemingly benign development which, upon reaching a certain scale, becomes a dead end.

Even if abundant sources of clean energy were to come on stream tomorrow, we would still face problems of overpopulation, overconsumption, soil erosion and the most unequal distribution of wealth and health in history. But, as the essays in this important book explore and document in different ways, a “carbon shift” – a swift transition to much cleaner energy – is our only hope of escaping the dire consequences of our runaway success.

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Cocktail Party Guide to Global Warming

Cocktail Party Guide to Global Warming

everything you need to know to converse intelligently about global warming
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