Explorer Director’s Corner
By David Curtiss
We all have milestones in our lives – those times that, in retrospect, we recognize as formative or transitionary, in which one chapter of our lives ends and another begins.
American Association of Petroleum Geologists (AAPG)
Added on 01 March, 2017
Explorer Emphasis Article
By Louise Durham
Among the array of not-to-be-missed technical sessions at the upcoming 2017 AAPG Annual Convention and Exhibition (ACE), “Major Deepwater Fields of the Offshore U.S. Gulf of Mexico” is grabbing its share of attention.
American Association of Petroleum Geologists (AAPG)
Added on 01 March, 2017
Explorer Emphasis Article
By Ken Milam
Last year, the extraordinarily high quality of the technical program was the talk of the AAPG Annual Convention and Exhibition in Calgary, and this was at an ACE with plenty of high points to talk about. The technical program for the 2017 ACE in Houston promises to be even better than last year’s.
American Association of Petroleum Geologists (AAPG)
Added on 01 March, 2017
Explorer Emphasis Article
By Barry Friedman
Sidney Powers Memorial Award: Celebrating the career of Larry Meckel.
American Association of Petroleum Geologists (AAPG)
Added on 01 March, 2017
Search and Discovery Article
By Siddarth Misra,Yifu Han
Subsurface electromagnetic (EM) measurements, namely galvanic resistivity, EM induction, EM propagation, and dielectric
dispersion, exhibit frequency dependence due to the interfacial polarization (IP) of clay minerals, clay-sized particles, and
conductive minerals. Existing oil-in-place estimation methods based on subsurface EM measurements do not account for
dielectric permittivity, dielectric dispersion, and dielectric permittivity anisotropy arising from the IP effects. The conventional
interpretation methods generate inaccurate oil-in-place estimates in clay-
and pyrite-bearing shales because they separately
interpret the multi-frequency effective conductivity and permittivity using empirical models.
We introduce a new inversion-based method
for accurate oil-in-place estimation in clay-
and pyrite-bearing shales. The inversion
algorithm is coupled with an electrochemical model that accounts for the frequency dispersion in effective conductivity and
permittivity due to the above-mentioned IP effects. The proposed method jointly processes the multi-frequency effective
conductivity and permittivity values computed from the subsurface EM measurements. The proposed method assumes
negligible invasion, negligible borehole rugosity, and lateral and vert
ical homogeneity effects.
The successful application of the new interpretation method is documented with synthetic cases and field data. Water saturation
estimates in shale formations obtained with the new interpretation method are compared to those obtained with conventional
methods and laboratory measurements. Conventional interpretation of multi-frequency effective conductivity and permittivity
well logs in a clay-
and pyrite-rich shale formation generated water saturation estimates that varied up to 0.
5 saturation units, as
a function of the operating frequency of the EM measurement, at each depth along the formation interval. A joint interpretation
of multifrequency conductivity and permittivity is necessary to compute the oil-in-place estimates in such formations. Estimated
values of water saturation, average grain size, and surface conductance of clays in that formation are in the range of 0.4 to
0.7,
0.5 micro
meter to 5 micrometer, and 5×10
-
7
S to 9×10
-
7
S, respectively. The proposed method is a novel technique to integrate
effective conductivity and permittivity at various frequencies. In doing so, the method generates frequency-independent oil-in-place estimates, prevents under-estimation of hydrocarbon saturation, and identifies by-passed zones in
shales.
American Association of Petroleum Geologists (AAPG)
Added on 17 February, 2017
Search and Discovery Article
By Larry Meckel,Stephen A. Sonnenberg
The driving forces for conventional accumulations (structural or stratigraphic traps) are Forces of Buoyancy which are due to
differences in
densities of hydrocarbons and water. In contrast, the driving forces for unconventional tight accumulations are Forces of Expulsion which are
produced by high pressures. That is an enormous difference and creates unconventional petroleum systems that are characterized by very
different and distinctive characteristics. The Force of Expulsion pressures are created by the
significant increase in volume when any of the
three main kerogen types are converted to hydrocarbons. At those conversion times in the burial history, the rocks are already sufficiently tight
so the large volumes of generated hydrocarbons cannot efficiently escape through the existing tight pore system,
thus creating a permeability
bottleneck that produces an overpressured compartment over a large area corresponding to the proper thermal oil and gas maturities for that
basin. The forces initially created
in these source rocks can only go limited distances into adjacent tight reservoirs (clastics or carbonates)
above or below the source. The exact distance will vary depending on the pressure increase, matrix permeability, and fractures of that specific
tight reservoir system. In general, the distances are small, in the orders of 10s to 100s of feet for oil and larger for more mobile gas systems.
Those exact distance numbers are subject to ongoing investigations.
A plot of the pressure data versus elevation
for a given formation is critical in determining whether an accumulation is conventional or
unconventional. Conventional accumulations will have hydrocarbon columns of 10s to 100s of feet with the pressure in the hydrocarbons and
that in the water equal at the bottom of the accumulation (at the HC-water contact). In contrast, the unconventional accumulations will show
HC column heights of 1000s of feet with the pressure in the hydrocarbon phase and the water phase being the same at the top of the
accumulation (at the updip transition zone). Those significant differences are critical for understanding and differentiating these two play types.
Because the system is a pore throat bottleneck with very little or minimum lateral migration, the type of hydrocarbon
s are closely tied to the
thermal maturity required to generate those hydrocarbons. Thus the play concept begins with two important geochemical considerations: (1)
where are the source rocks and what are the kerogen types and organic richness (TOC), and (2
) where are they mature in the basin for oil,
condensate, and gas in the basin. These parameters will very quickly define the fairway for the play. Then one has to add the
critical
information on the reservoirs themselves: composition (brittleness), thickness, and reservoir quality (matrix porosity and permeability). In
summary, these tight unconventional petroleum systems (1) are dynamic
,
and (2) create a regionally inverted petroleum system with water over
oil over condensate over gas for source rocks wit
h Type I or II kerogen types.
American Association of Petroleum Geologists (AAPG)
Added on 17 February, 2017
Africa Blog
By Delia Kuye
Network, interact and share expertise with fellow petroleum scientists while learning the latest unconventional reservoir techniques and technologies.
American Association of Petroleum Geologists (AAPG)
Added on 13 February, 2017
Explorer Historical Highlights
By Fran Hein
Wildfires might be what come to mind when most people think of northeastern Alberta, owing to recent news coverage of the record evacuation of about 88,000 people from the Fort McMurray area. Current events notwithstanding, however, northeastern Alberta is historically best known for its huge bitumen resources.
American Association of Petroleum Geologists (AAPG)
Added on 01 February, 2017