Using CO2 extends range of EOR applications for GoM operators

In June, the National Energy Technology Laboratory (NETL), a division of the US Department of Energy, released "CO₂-EOR Offshore Resource Assessment." The report, authored by Taylor Malone and Vello Kuuskraa of Advanced Resources International Inc., and Phil DiPietro of NETL, analyzes the economic and technical factors relating to the use of CO₂-EOR offshore in the Gulf of Mexico.

The report found the economic viability of CO₂-EOR in the GoM depends greatly on three factors: the price of oil, the cost of CO₂, and the efficiency of CO₂-EOR technology. As it now stands, the price of oil is the constraining factor. Assuming a price recovery in the near to medium term, this study provides a variety of sensitivity analyses that examine how these three factors affect the results of the GoM CO₂-EOR resource assessment.

This assessment of GoM outer continental shelf (OCS) oil fields also considers: when in the life of the oil field the CO₂ flood is initiated; how well developed and drilled is the oil field at the time of CO₂-EOR implementation; what are the water and reservoir depths; and how much oil remains after primary/secondary oil recovery. In general, shallow-water oil fields have high (40% to 60%) oil recovery efficiencies. In contrast, deepwater oil fields have much lower recovery efficiencies and thus have considerably larger remaining oil volumes as the target for CO₂-EOR.

This analysis incorporates considerations of oil field maturity and development status, water and reservoir depth, and oil recovery efficiency into a GoM offshore oil field/reservoir database and into the calculations of expected CO₂-EOR performance and development costs. The assessment evaluated 60 deepwater GoM oil fields as well as the clusters of "anchor fields" (oil fields with more than 1 Bbbl of original oil in-place) that would be the destination of potential CO₂ pipelines.

Resource assessment

The CO₂-EOR assessment for the GoM OCS starts with a base case that assumes: (1) an oil price of $90/bbl; (2) CO₂ costs of $50/metric ton (mt), delivered to the oil field at pressure (CO₂ purchase price of $30/mt (at plant gate), and $20/mt for offshore transportation); and (3) current CO₂-EOR technology. The study then examines how use of "next generation" CO₂-EOR technology would impact the offshore GoM resource assessment.

Current technology

In the base case, the GoM OCS offers relatively modest oil recovery and CO₂ storage opportunities from the application of CO₂-EOR – 810 MMbbl of incremental oil and 310 million metric tons (MMmt) of CO₂ demand and storage. However, lower CO₂ costs and higher oil prices would improve the results while lower oil prices and higher CO₂ costs would worsen results.

One important consideration exists when assessing GoM OCS CO₂-EOR; is there enough CO₂ available in the Gulf Coast area for large-scale implementation of CO₂-EOR? The available natural (geologic) CO₂ supplies along the Gulf Coast are limited and already committed to onshore CO₂-EOR projects. As such, the use of CO₂-EOR offshore in the GoM would need to rely on CO₂ captured from power and other industrial plants.

Analysis by the US DOE/National Energy Technology Laboratory shows that 94 MMmt/yr of CO₂ is currently vented from large (more than 3 MMmt/yr) power and industrial plants along the Gulf Coast. With an EOR demand (under current CO₂-EOR technology) for CO₂ of 310 MMmt over a 30-year time period, about 10 MMmt/yr (0.5 bcf/d) would be required. This represents only a fraction of the annual CO₂ emissions from large point sources in the Gulf Coast area, primarily petroleum refineries (45 MMmt/yr), fossil fuel power plants (41 MMmt/yr), and other industrial facilities (8 MMmt/yr).

Displaying 1/2 Page 1,2Next>
View Article as Single page