Interesting article. It's quite long, but a very interesting read. I'm just pasting a few parts that I like.
The Future Of Energy
The Future Of Energy
My personal guess is that NG based products take us into the future until nanotechnology makes solar power the viable economic choice.Perhaps even more than exposing the instability of the worldwide economic ponzi system, so far 2011 has been most remarkable for fully demonstrating the fragility of the global energy complex, which in the aftermath of the Fukushima nuclear crisis (and the moratorium on nuclear energy in Germany now, and soon other places), and the MENA revolutions, have raised the question of what happens in a world in which crude is getting ever scarcer, while the one main legacy energy alternative, fission-based nuclear power, just took a giant step back. The topic of limitations in conventional and possibilites in alternative energy has gripped the general public's mind to such an extent that Popular Science magazine has dedicated its entire July edition to answering that very critical question. As PopSci says: "Oil’s amazing efficiency is one reason it remains in such high demand, especially for transportation, and it’s also why finding an alternative will be so difficult. But find one we must. We have already burned our way through most of the world’s easy oil. Now we’re drilling for the hard stuff: unconventional resources such as shale and heavy oil that will be more difficult and expensive to discover, extract, and refine. The environmental costs are also on the rise." So what is the existing line up of future alternatives to the current crude oil-dominated energy paradigm. Below we present the complete list.
Next Generation Nukes.
Nuclear power may have taken a major step back after the biggest nuclear catastrophe since Fukushima, but that does not mean existing Generation III projects (the Fukushima reactor is a Gen II) are not viable and safe. Below is a summary of the key aspects of this program now coming on line in Japan, France and Russia.
Summarizing a typical Gen III schematic:
Shale
Total reserves: 3 trillion barrels of oil equivalent (BOE)
Given the political anxiety surrounding the prospect of importing oil, U.S. policymakers will be understandably tempted to reach first for the closest, richest oil resource. For many, that would suggest shale oil. The vast deposits located beneath Colorado, Utah and Wyoming alone could generate up to 800 billion barrels of oil. But policymakers should resist that urge.
Oil shale is created when kerogen, the organic precursor to oil and natural gas, accumulates in rock formations without being subjected to enough heat to be completely cooked into oil. Petroleum engineers have long known how to finish the job, by heating the kerogen until it vaporizes, distilling the resulting gas into a synthetic crude, and refining that crude into gasoline or some other fuel. But the process is expensive. The kerogen must either be strip-mined and converted aboveground or cooked, often by electrical heaters, in the ground and then pumped to the surface. Either process pushes production costs up to $90 a barrel. As all crude prices rise, though, the added expense of shale oil may come to seem reasonable--and it is likely to drop in any case if the shale oil industry, now made up of relatively small pilot operations, scales up.
The problem is that the external costs of shale oil are also very high. It is not energy-dense (a ton of rock yields just 30 gallons of pure kerogen), so companies will be removing millions of tons of material from thousands of acres of land, which can introduce dangerous amounts of heavy metals into the water system. The in-ground method, meanwhile, can also contaminate groundwater (although Shell and other companies say this can be prevented by freezing the ground). Both methods are resource-intensive. Producing a barrel of synthetic crude requires as many as three barrels of water, a major constraint in the already parched Western U.S. With in-ground, the kerogen must be kept at temperatures as high as 700°F for more than two years, and aboveground processes use a lot of heat as well. Those demands, coupled with kerogen’s low energy density, yield returns ranging from 10:1 (that is, 10 barrels of output for every one barrel of input) to an abysmal 3:1.
Natural Gas
Total reserves: 1 trillion BOE
Natural gas, or simply “gas” in industry parlance, has long been oil’s biggest potential rival as a transport fuel. Gas is cleaner than oil--it emits fewer particulates and a quarter less carbon for the same amount of energy output--yet today it powers less than 3 percent of the U.S. transportation fleet (mainly in the form of compressed natural gas, or CNG). This proportion is poised to grow, though, in part because the overall supply of gas keeps growing.
With advances in a drilling technique called hydraulic fracturing, or “fracking,” companies can now profitably extract gas from previously hard-to-reach shale formations. Worldwide reserves of shale gas currently stand at 6,662 trillion cubic feet, the energy equivalent of 827 billion barrels of oil. And that doesn’t include the gas that is routinely discovered alongside oil in oil fields and that is sure to be found in some of those yet-to-be-explored deepwater basins.
Gas is so plentiful that, in energy-equivalent terms, its price is a quarter that of oil--a bargain that is already transforming CNG from a niche fuel, used mainly in bus fleets, to a product for general consumption. The Texas refiner Valero, for instance, will soon begin selling CNG at new stations in the U.S.
A gas-powered future could still have some high external costs, though. Fracking can be extremely hazardous to the local environment. The method uses high-pressure fluids to break open deep rock formations in which gas is trapped, and these fluids often contain toxins that might contaminate groundwater supplies. But such risks, which have received substantial media coverage and are now the focus of a new White House panel, may be controllable. Gas deposits are typically thousands of feet belowground, while groundwater tables are much closer to the surface, so most contamination is thought to take place where the rising bore intersects with the water table--a risk that could be minimized by requiring drillers to more carefully seal the walls of the bore.
That said, allocating too much natural gas to transportation might have surprisingly negative consequences. First, it would most likely increase demand for natural gas so much that prices would rise, thereby undermining the current cost advantage. Second, shifting a large volume of gas to the transportation sector would mean pulling that volume away from the power sector, where it is more constructively displacing coal, whose carbon content is far higher than oil’s. But converting specific sectors of the transportation system (delivery fleets, for instance, or buses) could simultaneously cut CO2 emissions and reduce oil demand.
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