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GC Passive Seismic Techniques*
By
Bob Hardage1
Search and Discovery Article #40319 (2008)
Posted August 1, 2008
*Adapted from the Geophysical Corner column, prepared by the author, in AAPG Explorer, July, 2008, and entitled “Is the Future of Seismic Passive?”. Editor of Geophysical Corner is Bob A. Hardage. Managing Editor of AAPG Explorer is Vern Stefanic; Larry Nation is Communications Director.
1 Bureau of Economic Geology, The University of Texas at Austin ([email protected])
Passive-seismic technology encompasses any procedure by which seismic data are recorded without the use of an active seismic source. When passive-seismic data are acquired, there is no vibrator vehicle, no shothole explosive, no impact source, and no air gun. Instead, seismic wavefields are generated by natural phenomena such as wind, microseisms, ocean waves, or by human-made noises such as moving vehicles, passing aircraft, or mechanical vibrations of operating machinery.
One passive-seismic application that is gaining attention is the acquisition and 
analysis
of low-frequency natural seismic wavefields that seem to indicate the presence of subsurface oil and gas accumulations. In this application, data are acquired using high-sensitivity three component geophones deployed across the earth’s surface. Data are recorded for time periods of many minutes to days in order to have data that are appropriate for analysis.
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An example of this low-frequency, passive-seismic application is shown as Figure 1, in which responses of vertical geophones at sites 1 and 2 along a profile are displayed. Site 1 is atop a hydrocarbon producing area; site 2 is not. Data
Restricting data
Ocean-wave energy is ubiquitous and can be observed in the interior of continents far from coastlines. The amount of anthropogenic energy varies from site to site, depending on the nature of human culture from area to area.
To emphasize a hydrocarbon response in this narrow, low-frequency band, one data- Although the data behaviors illustrated in these figures seem to imply the presence of hydrocarbons, the data do not provide information about depth to the hydrocarbon accumulation or about the size of the reservoir. These shortcomings are now being addressed by reverse time modeling of passive-seismic data, a process in which seismic events are extrapolated back to their points of origin. An example of one such reverse-time model is displayed as Figure 3. When shown in this format, passive-seismic data can be compared with other hydrocarbon-sensitive data and, more importantly, can be subjected to a rotary lie-detector test (the drill bit).
What is the source of the hydrocarbon signal? The big question is why are hydrocarbon reservoirs associated with these natural-source, low-frequency responses? This is an active area of research at ETH Zurich, where both meso-scale scattering and pore-scale rock physics mechanisms are being considered. What is known is that empirical evidence is accumulating from the Middle East, North Africa, Europe, Brazil, and North America that implies a relationship between low-frequency passive-seismic responses and the presence of subsurface hydrocarbons.
There is nothing wrong with utilizing empirical rules in hydrocarbon exploitation. Empirical relationships between seismic attributes and reservoir properties are used daily by explorationists to interpret hydrocarbon systems. Maybe we now have another empirically based
At present, I have no experience in using passive-seismic data in the manner described here. However, my responsibility is to alert readers to new techniques that warrant consideration for energy-resource exploitation. If you desire more information about the applications of natural-source passive-seismic technology, contact the author for references to contractors who provide passive-seismic data-acquisition and data-
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