Mining "Ice That Burns"  

Posted by Big Gav in

Technology Review has a look at developments in the world of methane hydrates - Mining "Ice That Burns".

Trapped in molecular cages resembling ice, at the bottom of the ocean and in terrestrial permafrost all over the world, is a supply of natural gas that, by conservative estimates, is equivalent to twice the amount of energy contained in all other fossil fuels remaining in the earth's crust. The question has been whether or not this enormous reserve of energy, known as methane hydrates, existed in nature in a form that was worth pursuing, and whether or not the technology existed to harvest it.

Last Friday, the United States Geological Survey (USGS) announced the discovery of suitable conditions for mining methane hydrates 1,000 meters beneath the seabed in the Gulf of Mexico. Together with Chevron and the U.S. Department of Energy, the USGS discovered the reserve of hydrates in high concentrations in 15-to-30-meter-thick beds of sand--conditions very much like terrestrial methane hydrate reserves, which have already yielded commercially useful flow rates. These deposits are substantially different from the gas hydrates that have previously been discovered in U.S. coastal waters, which exist in relatively shallow waters at the surface of the seabed and have become a concern for climate scientists because of their potential to melt rapidly and release large quantities of methane into the atmosphere.

In the spring of 2008, a joint Canadian-Japanese expedition in Mallik in the Northwest Territories, Canada, established that methane hydrates could be harvested by using a water pump to depressurize a well already drilled into the reserve. This involved lowering the pressure pumping out the water that naturally accumulates in the well. Crucially, it required only 10 to 15 percent of the energy represented by the gas that flowed out of the well, making it a much more viable approach than earlier methods used to harvest hydrates, which involved melting them with warm water. Standard oil and gas drilling equipment was used to reenter an old well drilled to a depth of 3,500 feet and then "refurbish" it by casing the entire well with lengths of steel tubing that cemented into place in order to prevent it from collapsing.

Hydrates require both cold temperatures and high pressure to form; eliminating either condition frees the gas from its icy cage, but past attempts to do this by heating the hydrates proved prohibitively difficult. The Canadian-Japanese expedition successfully produced up to 4,000 cubic meters of gas a day during a six-day trial in 2008 using depressurization.

"I think [the Gulf of Mexico find] and Mallik are two revolutionary events," says Timothy Collett, a geologist with the USGS and one of the world's foremost authorities on gas hydrates.

While no one believes that all of the world's methane hydrates will be recoverable, the scale of global reserves has been described by the U.S. Department of Energy as "staggering." They occur anywhere that water, methane, low temperatures, and high pressure co-occur--in other words, in the 23 percent of the world's land area covered by permafrost and at the bottom of the ocean, particularly the continental shelf.

Increased interest in naturally occurring methane hydrates has been driven by the desire for energy independence from the Middle East and Russia and by the need to find energy sources with less of a potential impact on the climate than coal. (Natural gas produces half as much carbon as coal per unit of energy.) This is reflected by an exponential growth in the number of scientific papers published on the subject per year, according to Carolyn Koh, codirector of the Center for Hydrate Research at the Colorado School of Mines. More than a dozen expeditions designed to harvest or sample terrestrial and marine hydrate reserves have been launched since 2001, not only in the United States and Canada, but also in Japan, Korea, China, and India, according to Collett.

1 comments

Nunjafush   says 11:33 AM

Yes, as long as the temperature stays low enough and the pressure is high enough, the methane stays locked in the ice. Unfortunately, global warming may allow many of these methane hydrates to release their methane into the atmosphere well before a significant amount has been harvested. Of course, we all know that methane is a much more powerful green house gas than CO2 and it has been estimated that this could push the effective CO2 levels to over 1000 parts per million - well above the 550 PPM level that would trigger a runaway greenhouse heating system. See the Clathrate Gun Hypothesis here: http://en.wikipedia.org/wiki/Clathrate_gun_hypothesis

Post a Comment

Statistics

Locations of visitors to this page

blogspot visitor
Stat Counter

Total Pageviews

Ads

Books

Followers

Blog Archive

Labels

australia (619) global warming (423) solar power (397) peak oil (355) renewable energy (302) electric vehicles (250) wind power (194) ocean energy (165) csp (159) solar thermal power (145) geothermal energy (144) energy storage (142) smart grids (140) oil (139) solar pv (138) tidal power (137) coal seam gas (131) nuclear power (129) china (120) lng (117) iraq (113) geothermal power (112) green buildings (110) natural gas (110) agriculture (91) oil price (80) biofuel (78) wave power (73) smart meters (72) coal (70) uk (69) electricity grid (67) energy efficiency (64) google (58) internet (50) surveillance (50) bicycle (49) big brother (49) shale gas (49) food prices (48) tesla (46) thin film solar (42) biomimicry (40) canada (40) scotland (38) ocean power (37) politics (37) shale oil (37) new zealand (35) air transport (34) algae (34) water (34) arctic ice (33) concentrating solar power (33) saudi arabia (33) queensland (32) california (31) credit crunch (31) bioplastic (30) offshore wind power (30) population (30) cogeneration (28) geoengineering (28) batteries (26) drought (26) resource wars (26) woodside (26) censorship (25) cleantech (25) bruce sterling (24) ctl (23) limits to growth (23) carbon tax (22) economics (22) exxon (22) lithium (22) buckminster fuller (21) distributed manufacturing (21) iraq oil law (21) coal to liquids (20) indonesia (20) origin energy (20) brightsource (19) rail transport (19) ultracapacitor (19) santos (18) ausra (17) collapse (17) electric bikes (17) michael klare (17) atlantis (16) cellulosic ethanol (16) iceland (16) lithium ion batteries (16) mapping (16) ucg (16) bees (15) concentrating solar thermal power (15) ethanol (15) geodynamics (15) psychology (15) al gore (14) brazil (14) bucky fuller (14) carbon emissions (14) fertiliser (14) matthew simmons (14) ambient energy (13) biodiesel (13) investment (13) kenya (13) public transport (13) big oil (12) biochar (12) chile (12) cities (12) desertec (12) internet of things (12) otec (12) texas (12) victoria (12) antarctica (11) cradle to cradle (11) energy policy (11) hybrid car (11) terra preta (11) tinfoil (11) toyota (11) amory lovins (10) fabber (10) gazprom (10) goldman sachs (10) gtl (10) severn estuary (10) volt (10) afghanistan (9) alaska (9) biomass (9) carbon trading (9) distributed generation (9) esolar (9) four day week (9) fuel cells (9) jeremy leggett (9) methane hydrates (9) pge (9) sweden (9) arrow energy (8) bolivia (8) eroei (8) fish (8) floating offshore wind power (8) guerilla gardening (8) linc energy (8) methane (8) nanosolar (8) natural gas pipelines (8) pentland firth (8) saul griffith (8) stirling engine (8) us elections (8) western australia (8) airborne wind turbines (7) bloom energy (7) boeing (7) chp (7) climategate (7) copenhagen (7) scenario planning (7) vinod khosla (7) apocaphilia (6) ceramic fuel cells (6) cigs (6) futurism (6) jatropha (6) nigeria (6) ocean acidification (6) relocalisation (6) somalia (6) t boone pickens (6) local currencies (5) space based solar power (5) varanus island (5) garbage (4) global energy grid (4) kevin kelly (4) low temperature geothermal power (4) oled (4) tim flannery (4) v2g (4) club of rome (3) norman borlaug (2) peak oil portfolio (1)