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Detecting The Radioactive Minerals Using Well Logs Methods

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Detecting The Radioactive Minerals Using Well Logs Methods Asst. Professor Dr. Mahmoud A. AL-Mufarji. Asst. Professor Dr. Jawad R. AL-Assal. Asst. Lecturer Adnan A ... – PowerPoint PPT presentation

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Title: Detecting The Radioactive Minerals Using Well Logs Methods


1
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2
  • Detecting The Radioactive Minerals Using Well
    Logs Methods
  •  
  • Asst. Professor Dr. Mahmoud A. AL-Mufarji
  • Asst. Professor Dr. Jawad R. AL-Assal
  • Asst. Lecturer Adnan A. Abed AL-Jabbory

3
  • Abstract
  •  
  • Radioactivity is accompanied by the emission
    of alpha or beta particles, gamma rays. Gamma
    rays are electromagnetic radiations emitted from
    an atomic nucleus during radioactive decay. The
    clay minerals are primarily responsible for two
    sources of radioactivity, potassium, and thorium,
    associated with most shales.
  • There are two types of GR logs. One, the standard
    GR log, measures only the total radioactivity.
    The other, the NGS (Natural Gamma Ray
    Spectrometry) log, measures the total
    radioactivity and the concentrations of
    potassium, thorium, and uranium producing the
    radioactivity.

4
  • We apply the gamma ray log in some wells in south
    Iraqi field normally reflects the shale content
    of the formations. This is because the
    radioactive elements tend to concentrate in clays
    and shales. Thus, as shale content increases the
    gamma ray log response increases also.
  • When we are correlating density log and gamma ray
    log for two wells in this study and Showing for
    maximum gamma ray reading as a maximum reading in
    density log because The original density tool
    consisted of a high-energy gamma ray emitting
    source coupled with a shielded gamma ray
    detector.

5
  • GAMMA RADIATION
  •  
  • Gamma-radiation may be considered as an
    electromagnetic wave similar to visible light or
    X-rays, or as a particle or photon. Gamma rays
    are electromagnetic radiations emitted from an
    atomic nucleus during radioactive decay. These
    radiations are characterized by wave lengths in
    the range of 1 0 -9 - 1 0 -11 cm, equivalent to
    frequencies ranging from 1019 to 1021 sec -1.

6
  • The energy is expressed in electron-volts (eV).
    The energies of gamma rays are of the order of
    the MeV (l06 eV). Usually, the a, ß and
    ?-emissions are simultaneous, figure (1).
  • ß- and a -particles do not penetrate far enough
    to be detected by logging techniques. The gamma
    rays have a very high power of penetration and
    can be detected and recorded in present-day hole
    conditions. For that reason, they are the basis
    of several important logging techniques.
  •  
  •  

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8
  • Potassium-Bearing Minerals and Rocks
  •  
  • The source minerals of potassium are the
    feldspars and micas plus a large number of
    minerals of minor importance.
  • During alteration, some silicates such as the
    feldspars are completely dissolved the potassium
    is thus liberated in ionic form and transported
    in solution Micas, on the other hand, may lose
    only part of their potassium during alteration,
    the remainder staying in the crystal lattice.

9
  • Uranium-Bearing Minerals and Rocks
  •  
  • The source minerals are in igneous rocks of
    acid origin. Table (1) lists the average content
    (in ppm) of uranium and thorium in several rock
    types. These are averages actual values can vary
    considerably.

10
  • Thorium-Bearing Minerals and Rocks
  •  
  • Thorium originates from igneous rocks of the acid
    and acido-basic types (granites, pegmatites,
    syenites, nepheline syenites).
  • Table (1) lists the average concentrations (in
    ppm) encountered.

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12
  • NATURAL GAMMA RAY LOGS
  •  
  • The natural gamma ray (GR) log is a recording
    of the natural radioactivity of the formation.
    There are two types of GR logs. The standard GR
    log which measure only the total radioactivity.
    and NGS (Natural Gamma Ray Spectrometry) log
    which measure the total radioactivity and the
    concentrations of Potassium, Thorium, and Uranium
    producing the radioactivity.

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14
  • METHODOLOGY AND RESULTS
  • The results are shown in Fig. (4) for some well
    in the xx field, using Petrel program to read the
    maximum value of Gamma ray. As noticed, gamma ray
    reading reached maximum value in six depth
    interval
  • Depth interval 2288.66-2306.5 m and max. GR
    value27 API
  • Depth interval 2310.67-2320.8 m and max.GR
    value25 API
  • Depth interval 2375.88-2421.16m and max.GR
    value23 API
  • Depth interval 2178.2-2183.37m and max. GR
    value26 API
  • Depth interval2221.2-2233.8m and max. GR
    value21 API
  • Depth interval 2330.16-2338.94 m and max.GR
    value51 API
  • From these intervals the gamma ray log normally
    reflects the shale content of the formations.
    This is because the radioactive elements tend to
    concentrate in clays and shales. Thus, as shale
    content increases the gamma ray log response
    increases also.

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  • Fig.(5) showed the correlation between gamma log
    and the density log, it appeared that the maximum
    reading of the gamma ray corresponding to maximum
    reading of the density log at the same depth
    because the original density tool consisted of a
    high-energy gamma ray emitting source coupled
    with a shielded gamma ray detector.

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  • RECCOMEDATION
  • Using the most sophisticated software in
    interpretation in gamma ray reading to detect the
    radioactive minerals
  • Using the natural gamma ray spectral (NGS log)
    rather than standard gamma ray.
  • In oil well drilling it is recommended to examine
    the cutting from radioactivity.

19
  • Thank you
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