By IANS,
Washington : Trapping carbon dioxide at the source like coal burning power plants and then injecting them underground could be one of the options to cut emissions levels. MIT engineers have come up with a new software tool to determine how much can be sequestered safely in a geological formation.
However, injecting too much carbon dioxide (CO2) could create or enlarge underground faults that may become conduits for CO2 to travel back up to the atmosphere, said Ruben Juanes, assistant professor of civil and environmental engineering (CEE) and a co-author of the work. Until now the technique has never been tested in an industrial operation.
“Our model is a simple, effective way to calculate how much CO2 a basin can store safely. It is the first to look at large scales and take into account the effects of flow dynamics on the stored CO2,” he said.
Already Juanes and co-author CEE graduate student Michael L. Szulczewski have applied their model to the Fox Hills Sandstone in the Powder River basin straddling Montana and Wyoming.
They found that the formation would hold around five gigatons of CO2 – more than half of all the CO2 emitted by the US every year, said an MIT release.
A geological basin is a large underground bowl between 100 and 1,000 km wide and 5,000 km deep that has filled over millennia with layers of sand, fine-grained clays, and other sediments that are eventually consolidated into porous rock.
Some of the layers contain brine and are called deep saline aquifers. CO2 would be injected into the aquifers through wells.
The MIT model predicts how much a plume of CO2 will migrate from its injection well and the path it is likely to take due to underground slopes and groundwater flow.
“A lot of people have done studies at small scales,” Szulczewski said. “If we’re going to offset emissions, however, we’re going to inject a lot of CO2 into the subsurface. This requires thinking at the basin scale.”
“Despite the fact that our model applies at the basin scale, it is very simple. Using only pen and paper, you take geological parameters such as porosity, temperature and pressure to calculate storage capacity,” Szulczewski said. “Other methods suffer from major shortcomings of accuracy, complexity or scale.”
Juanes studies a phenomenon called capillary trapping, through which CO2, liquefied by the pressure of the earth, is trapped as small blobs in the briny water (picture bubbles of oil in vinegar).
The CO2 dispersed throughout the basin’s structural pores eventually dissolves and reacts with reservoir rocks to precipitate out into harmless carbonate minerals.
CO2 has been sequestered in small pilot projects in Norway, Algeria and elsewhere. In 2004, 1,600 tonnes of CO2 were injected 1,500 metres into high-permeability brine-bearing sandstone of the Frio formation beneath the Gulf coast of Texas.
Current proposals call for injecting billions of tonnes within the continental United States.
The work was presented Tuesday at the ninth International Conference on Greenhouse Gas Control Technologies (GHGT-9) in Washington.