Patent Number: 052375943
Section: claims

1. A method for characterizing at least one activated element in an earth formation surrounding a borehole, comprising the steps of: (a) displacing in said borehole a sonde comprising a neutron source and at least two gamma ray detectors longitudinally spaced from said source, while irradiating said formation with neutrons of sufficient energy to interact with said element according to the activation reaction;  (b) detecting and counting at each detector the gamma rays resulting from the activation of atoms of said element;  (c) determining, at each depth, the number of gamma ray counts detected during the time period defined by the time instants when respectively said source and said detectors pass that depth, said determination of gamma ray counts being made for each detector at each depth;  (d) establishing a relationship, for each depth, between the counts from the respective detectors for that depth and the corresponding time instants when the corresponding detector passes that depth; and  (e) deriving from said relationship at least one characteristic of said element.  setting one detector as a reference detector;  determining the time when another detector reaches a given depth by adding to the time when said reference detector reaches said depth, an additional time "Delta t" given by: EQU Delta t=d / V  cross-plotting, for each depth, the gamma ray counts versus the corresponding times, one plot corresponding to one depth and including dots which forms a curve representative of said element at that depth; and  deriving from said curve at least one characteristic of said element.  (a) lowering a sonde comprising a neutron source and a gamma ray detector down to the bottom of said borehole or below the zone of earth formation to investigate;  (b) pulling said sonde while irradiating said formation with neutrons of sufficient energy to interact with said element according to the activation reaction;  (c) detecting and counting at each detector the gamma rays resulting from the activation of atoms of said element;  (d) determining, at each depth, the number of gamma ray counts detected during the time period defined by the time instants when respectively said source and said detector pass that depth, said determination of gamma ray counts being made for each detector at each depth;  (e) establishing a relationship, for each depth, between the counts from the respective detectors for that depth and the corresponding time instants when the corresponding detector reaches that depth;  (f) repeating at least once the sequence including steps (a)-(e), said neutron source being turned off; and (g) deriving from said relationship at least one characteristic of said element.  (1) neutron source means for irradiating said earth formation with neutrons of sufficient energy to interact with atoms of said element according to the activation reaction;  (2) means for detecting and counting at least two locations longitudinally spaced from said source, the gamma rays resulting from the activation of atoms of said element;  (3) means for determining, at each depth, the number of gamma ray counts detected during the time period defined by the time instants when respectively said source and said detector pass that depth, said determination being made for each detector at each depth;  (4) means for establishing a relationship, for each depth, between the counts from the respective detectors for that depth and the corresponding time instants when the corresponding detector reaches that depth; and  (5) means for deriving from said relationship at least one characteristic of said element.  means for cross-plotting the gamma ray counts versus time, wherein said relationship shows approximately the form of a straight line; and  means for deriving from the slope of said line the identity of said element.  (a) means for lowering a sonde comprising a neutron source and a gamma ray detector down to the bottom of said borehole or below the zone of earth formation to investigate;  (b) means for pulling said sonde while irradiating said formation with neutrons of sufficient energy to interact with said element according to the activation reaction;  (c) means for determining, at each depth, the number of gamma ray counts detected at each detector during the time period defined by the time instants when respectively said source and said detector pass that depth, said determination being made of gamma ray counts for each detector at each depth;  (d) means for establishing a relationship, or each depth, between the counts from the respective detectors for that depth and the corresponding time instants when the corresponding detector reaches that depth;  (e) means for repeating at least once the sequence including steps a-e, said neutron source being turned off; and  (f) means for deriving from said relationship at least one characteristic of said element.  (a) irradiating said formation with neutrons of sufficient energy to activate atoms of at least one element in the formation;  (b) detecting and counting the gamma rays resulting from the activation of atoms in said formation at at least two time instances;  (c) determining from the counted gamma rays and time intervals the reduction rate of gamma rays; and  (d) deriving from the gamma ray reduction ray the activated element of said formation.  (a) displacing in said borehole a sonde comprising a neutron source and at least two gamma ray detectors longitudinally spaced from said source, while irradiating said formation with neutrons of sufficient energy to activate atoms of at least one element in the formation;  (b) detecting and counting at each detector the gamma rays resulting from the activation of atoms in said formation;  (c) determining the number of gamma ray counts detected during the time period defined by the time instants when respectively said source and each said detector pass through an activated region of said earth formation;  (d) establishing a relationship between the counts from the respective detectors and the corresponding time instants when the detectors pass through the activated region of said formation; and  (e) deriving from said relationship the activated element of said formation.  cross-plotting, for each activation region, the gamma ray counts from said detectors versus the corresponding times, the plot including dots which form a curve representative of said activated element in said activated region; and  deriving from said curve at least one characteristic of said element. 2. The method according to claim 1 further comprising: 3. The method according to claim 1 further comprising: 4. The method according to claim 3 wherein said curve is substantially a straight line the slope of which is representative of the identity of said element. 5. The method according to claim 1 wherein the counts for one detector are representative of the quantity of said element of the radial distance between said borehole and atoms of said element. 6. The method according to claim 1 wherein said sonde comprises four gamma ray detectors. 7. The method according to claim 1 wherein said detectors are disposed on the same side along the longitudinal axis of said sonde with respect to said neutron source. 8. A method for characterizing at least one activated element in an earth formation surrounding a borehole, comprising the steps of: 9. The method according to claim 1 wherein said element comprises aluminum, silicon, magnesium or gold. 10. A logging apparatus for characterizing an element of earth formation surrounding a borehole, comprising a sonde comprising: 11. The apparatus according to claim 10 further comprising means for determining one time instant for a first detector including means for adding to the time instant of a second detector, the time "t" needed for the latter to reach that depth given by: t=d / V, where "d" is the spacing between the first and the second detector and "V" is the speed at which said sonde is displaced in said borehole. 12. The apparatus according to claim 10 further comprising: 13. The apparatus according to claim 10 wherein the counts for one detector are representative of the quantity of said element and of the radial distance between said borehole and atoms of said element. 14. The apparatus according to claim 10 wherein said sonde comprises four gamma ray detecting means. 15. The apparatus according to claim 10 wherein said detecting means are disposed on the same side along the longitudinal axis of said sonde, with respect to said neutron source. 16. The apparatus according to claim 15 wherein said neutron source is disposed above said detecting means. 17. An apparatus for characterizing at least one activated element in an earth formation surrounding a borehole, comprising: 18. The method according to claim 1 wherein the relationship in step (d) is established by cross-plotting for each detector the gamma ray counts versus the corresponding instant of time for that count. 19. A method for characterizing an element of an earth formation surrounding a borehole by activating atoms in said element comprising the steps of: 20. The method according to claim 19 wherein the gamma ray reduction rate is determined by plotting each gamma ray count versus the corresponding instant of time for that count. 21. The method according to claim 20 wherein the activation element is derived by comparing the gamma counts versus time plot to predetermined plots of various elements to determined the closest element match. 22. A method of characterizing an activated element in an earth formation surrounding a borehole by activating atoms in said element comprising the steps of: 23. The method according to claim 22 wherein the relationship of step d is established by plotting for each detector, the gamma ray count for that detector versus the corresponding instant of time that count. 24. The method according to claim 22 wherein one detector is set as a reference detector and further comprising before step c the step of determining the time when another detector reaches the activated region, an additional time "Delta t" given by: EQU Delta t=d/V 25. The method according to claim 22 wherein the counts for one detector are representative of the quantity of said activated element and of the radial distance between said borehole and atoms of said activated element. 26. The method according to claim 40 further comprising: 27. The method according to claim 26 wherein said curve is substantially a straight line, the slope of which is representative of the identity of said activated element.