IIT Madras researchers find efficient technique to recover oil from India's mature offshore wells

The research, published in Journal of Petroleum Science and Engineering, and Energy and Fuels journal, can help  optimise the technique and develop processes for efficient recovery of oil in India
Image for representational purpose only
Image for representational purpose only
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Researchers at Indian Institute of Technology (IIT) Madras are developing indigenous processes for efficient recovery of oil from mature offshore wells in the country.

Collaborating with research laboratories in Australia, the researchers are studying the efficacy of an emerging enhanced oil recovery method called Low-Salinity Enhanced Oil Recovery (LSEOR).

Domestic crude oil production is currently insufficient to meet India's energy demands, said Jitendra Sangwai, Professor, Department of Ocean Engineering, IIT Madras. He said Oil and Natural Gas Corp (ONGC) has been looking at Enhanced Oil Recovery (EOR) techniques to boost oil and gas output from old and matured fields.

Leveraging on modern techniques such as LSEOR could enable the country to meet the expected output. The research, published in Journal of Petroleum Science and Engineering, and Energy and Fuels journal, can help understand and optimise the technique and develop indigenous processes for efficient recovery of oil from mature offshore wells in India.

"Our research aims to develop indigenous methods for recovery of crude oil from geological reservoirs, which is a complex process," Sangwai said. "There is still much that needs to be understood in the use of LSEOR methods. We do not yet have a clear idea on the mechanism of wettability alteration that can be caused by factors such as oil composition, salt levels in the water, the acidity of the crude oil, mineralogy of the rock and other factors," he said.

There have been many studies since the 1990s all over the world, aimed at improving the wettability of oil-bearing rocks for better recovery through water injection. One way to do this is by reducing the salinity or salt content of seawater that is injected into the rock because the presence of certain divalent cations can change the wettability of the rock.

LSEOR has been gaining interest in recent years for better oil recovery from offshore reservoirs. Oil is extracted from offshore reservoirs through the water injection process, a secondary oil recovery method, in which, seawater is injected into the oil-bearing porous rocks, typically limestone and sandstone under the sea and the water pushes the oil out.

The efficiency of the process depends upon the wettability of the oil-bearing rock, researchers said. Although limestone and sandstone are water wettable rocks by nature, they can become hydrophobic or water repellent due to their oil content.

This results in poor wetting and inefficient oil extraction. The team has investigated the effects of varying the salt concentrations in water to understand the effect of various ions on the wettability of quartz surface as quartz is the most important rock-forming mineral in sandstone reservoirs.

The researchers also added organic acids and bases to model oil to test the effect of acidity and basicity of oil on wettability during LSEOR. In one study, Sangwai and his research student, Abhijit Kakati found that a reduced concentration of divalent cations such as calcium and magnesium in water can make the quartz less oil wettable, while sodium ions seem to have the opposite effect.

Similarly, the presence of acidic and basic substances in the oil also reduced water wettability, especially in the presence of salts. In a parallel study, Sangwai's team, along with his research student Nilesh Jha, also studied the effect of adding surfactants and nanoparticles to low salinity water to alter the wettability of sandstone.

Surfactants can reduce the interfacial tension between the oil and water, and therefore make the rock more water wettable, but the surfactant itself can be absorbed by the rock. This can be prevented by adding nanoparticles, particles that are 80,000 times smaller than the width of human hair.

The nanoparticles, when added in right amounts, are co-absorbed on the rock, thereby reducing the surfactant absorption. The team, in collaboration with researchers from Curtin University and the Edith Cowan University of Australia, found that salts can mediate the absorption of the nanoparticles on the sandstone.

They hypothesised that there is interplay among divalent cationic bridges that form between the rock surface, the nanoparticles and the surfactant, which alters the wettability of the sandstone.

Control of the nanoparticle surfactant ratio in LSEOR can enhance the efficiency of oil recovery, researchers said.

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