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Identification of New Seismic
Evidence Regarding Gas Hydrate Occurrence and Gas Migration Pathways Offshore Uruguay*
Juan Tomasini1, Héctor de Santa Ana1, and Arthur H. Johnson2
Search and Discovery Article #80116 (2010)
Posted November 5, 2010
*Adapted from poster presentation at AAPG Convention, New Orleans, Louisiana, April 11-14, 2010
1ANCAP, Montevideo, Uruguay ([email protected])
2Hydrate Energy International, Kenner, LA
Natural gas hydrates are crystalline solids formed by natural gas (mostly methane) and water that are stable at thermobaric conditions of high pressure and low temperatures that are found in nature in areas of permafrost and in offshore basins of continental margins. Besides the various applications related to the study of this subject, international interest in natural gas hydrate has grown in recent years mainly due to the estimations of large amounts of carbon stored in this form and its potential as an energy resource. An increasing number of countries have established research programs regarding hydrates.
In the Uruguayan offshore, seismic
evidence for the occurrence of gas hydrate has been identified based on the presence of BSRs (bottom simulating reflectors) in 2D
seismic
reflection sections. Initial determinations concerning the presence of BSRs indicated an area of 5,000 km2 (de Santa Ana et al., 2004) according to information from
seismic
surveys performed offshore Uruguay between 1970 and 2002, which were available so far in non-digital media (paper and acetate).
In order to reach a better understanding of the extent of gas hydrate-bearing sediments offshore Uruguay, we interpreted more than 10,000 km of regional and semi-detailed 2D reflection seismic
sections from surveys shot in 2007 and 2008, using the Kingdom Suite©
seismic
interpretation software. Special
seismic
processing was also performed on some of these new
seismic
sections using multi-
attribute
and neural networks focused on the identification of gas chimneys.
In this paper we present recent results regarding the identification of BSRs in 2D seismic
data acquired in the years 2007 and 2008, which indicate the presence of BSRs in areas that were not previously identified. The BSRs extend over an area of approximately 22,000 km2 and show that the potential for this non-conventional resource offshore Uruguay is higher than thought.
We also show seismic
evidence suggesting the existence of free gas below the hydrate stability zone (sub-hydrates prospects) through the presence of increased amplitudes below the BSR. Additionally, we present the results of the processing for identifying chimneys, which suggest a thermogenic origin of the gases that reach the hydrate-bearing layers.
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The study area for this work is located in the western South Atlantic on the continental margin of Uruguay. Here we found three sedimentary basins: Punta del Este, Pelotas, and Oriental del Plata (Figure 1). In the Uruguayan territorial sea,
BSRs are frequently used in the indirect diagnosis of gas hydrate accumulations (Sloan, 1998; Pecher and Holbrook, 2000) as geophysical indicators of the base of the GHSZ (gas hydrate stability zone). Because the BSR occurs at a contact between higher acoustic impedance above and lower acoustic impedance below (a negative acoustic impedance contrast), it produces a phase reversal in a reflected acoustic wave compared to the reflection from the seafloor (Max et al., 2006). The base of the GHSZ can have different
Offshore Uruguay, initial determinations concerning the presence of BSRs indicated an area of 5,000 km2 according to information from
We interpreted more than 10,000 km of regional and semi-detailed 2D reflection
From these surveys some lines have been selected for special processing aiming to identify gas chimneys. Gas chimneys are visible in
1) Data analysis and 2) Select representative train locations. 3) Calculate 4) Feed calculated data to neural network and train.
In this work we studied some of the results of the gas chimney identification processing in the surroundings of the BSRs in order to find a link between gas hydrate occurrence and gas chimney presence.
The interpretation of the base of the GHSZ on the 2007 and 2008 surveys show a widespread occurrence of the gas hydrate bearing sediments as showed in the Figure 4. As shown in Figure 4, the BSR is present in water depths greater than 500 m and has high continuity in the northern area (Pelotas Basin), but is more discontinuous at Punta del Este Basin and southern part of Oriental del Plata Basin.
The presence of BSR at the southern part of Offshore Uruguay represents a new discovery regarding gas hydrates in this area since previous
Regarding the gas chimney identification, Figure 6 shows the results for the processing in the surroundings of an interpreted BSR. Here we can observe the presence of enhanced amplitudes below the BSR and high probability of gas chimneys (shown in green colour) associated with a recent fault system. In Figure 7 we present results of gas chimney identification showing possible gas chimneys ending at the BSR. One explanation of this is that the hydrate bearing sediments are acting as a stratigraphic seal. The deep source of the gas chimneys present in this section suggests thermogenic origin.
The BSRs extend over an area of approximately 22,000 km2 and show that the potential for this non-conventional resource offshore Uruguay is higher than thought. We also found
Heggland, R., 2005, Using gas chimneys in seal integrity analysis: A discussion based on case histories, in P. Boult and J. Kaldi (eds.) Evaluating fault and cap rock seals: AAPG Hedberg Series, no. 2, p. 237-245.
Max, M.D., A.H. Johnson, and W.P. Dillon, 2006, Oceanic gas hydrate character, distribution, and potential for concentration in M.D. Max, A.H. Johnson, and W.P. Dillon, (eds.) Economic geology of natural gas hydrate, v. 9, p. 105-130.
Meldahl P., R. Heggland, B. Bril, and P. De Groot, 2001, Identifying Faults and Gas Chimneys Using Multiattributes and Neural Networks: The Leading Edge, v. 20/5, p. 474-482
Pecher, C.K. and W.S. Holbrook, 2000,
de Santa Ana, H., N. Ucha, L. Gutiérrez, and G. Veroslavsky, 2004, Gas hydrates: Estimation of the gas potential from reflection
Shedd, B., P. Godfriaux, M. Frye, R. Boswell, and D. Hutchinson, 2009, Occurrence and Variety in
Sloan, E.D., 1998, Clathrate hydrates of natural gas, 2nd edition: Marcel Dekker, New York, 705 p.
CGG Veritas website, Marine Data Library Offshore Uruguay, http://www.cggveritas.com/default.aspx?cid=1744&lang=1
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