A downhole multi-modality inspection system includes a first imaging device operable to generate first imaging data and a second imaging device operable to generate second imaging data. The first imaging device includes a first source operable to emit energy of a first modality, and a first detector operable to detect returning energy induced by the emitted energy of the first modality. The second imaging device includes a second source operable to emit energy of a second modality, and a second detector operable to detect returning energy induced by the emitted energy of the second modality. The system further includes a processor configured to receive the first imaging data and the second imaging data, and integrate the first imaging data with the second imaging data into an enhanced data stream. The processor correlates the first imaging data and the second imaging data to provide enhanced data for detecting potential wellbore anomalies.

A combining mechanism for borehole logging tool data that uses density data from a logging tool to inform the geometry of an acoustic-based or ultrasound-based data inversion is provided, comprising: at least one mechanism for converting three-dimensional density data into a three-dimensional density model; at least one mechanism for converting three-dimensional density model into a three-dimensional acoustic impedance model; and, at least one mechanism for processing acoustic data using said three-dimensional acoustic impedance model to produce an interpretable data log. A method of using density data from a logging tool to inform the geometry of an acoustic-based or ultrasound-based data inversion is also provided, comprising: converting three-dimensional density data into a three-dimensional density model; converting three-dimensional density model into a three-dimensional acoustic impedance model; and, processing acoustic data using said three-dimensional acoustic impedance model to produce an interpretable data log.

A combining mechanism for borehole logging tool data that uses density data from a logging tool to inform the geometry of an acoustic-based or ultrasound-based data inversion is provided, comprising: at least one mechanism for converting three-dimensional density data into a three-dimensional density model; at least one mechanism for converting three-dimensional density model into a three-dimensional acoustic impedance model; and, at least one mechanism for processing acoustic data using said three-dimensional acoustic impedance model to produce an interpretable data log. A method of using density data from a logging tool to inform the geometry of an acoustic-based or ultrasound-based data inversion is also provided, comprising: converting three-dimensional density data into a three-dimensional density model; converting three-dimensional density model into a three-dimensional acoustic impedance model; and, processing acoustic data using said three-dimensional acoustic impedance model to produce an interpretable data log.

Systems and methods include a computer-implemented method for creating artificial real-time gamma ray (GR) images for well placement. Real-time azimuthal density data is determined from drilling of a well. An azimuthal density data set is generated using the real-time azimuthal density data. The azimuthal density data set is generated with a greater sampling rate than a real-time sampling rate of the real-time azimuthal density data. An azimuthal density curve depth match is performed using the azimuthal density data set. Performing the azimuthal density curve depth match includes creating a depth shift match table. A high-resolution sector near-bit gamma ray (GR) image is generated using the azimuthal density curve depth match and the depth shift match table. The high-resolution sector near-bit GR image is oriented to a top of a wellbore for the well.

Sonic data, ultrasonic data, density data, cased-hole neutron data, and open-hole neutron data of the wellbore are obtained. The sonic and ultrasonic data provides the amplitude, frequency, and phase of the altered sonic and ultrasonic waves. The far counts, near counts, and energy spectrum are obtained from density data, cased-hole (CH) neutron data, and open-hole (OH) neutron data. The amplitude, frequency, and phase provide the interface densities of the first, second, and third interfaces. The hydrogen index (HI) of the formation and the cased wellbore are obtained from the CH and OH neutron data. The widths of the second and third interfaces are obtained from the HI's and the densities of the second and third interfaces.

A method and system for evaluating the cement behind casing and fully inverting acoustic properties of the material, including density and the speed of sound. A density map of the cement sheath is determined using a nuclear logging technique. An acoustic impedance value of the cement sheath is provided, either by measurement using an ultrasonic logging technique or simulated using an acoustic model. The acoustic model may assume a vertical incident plane wave and flat plates for casing and the cement sheath. From the density map and the acoustic impedance value, a map of the speed of sound in the cement sheath, or a gap therein, may be determined.

A method and system for analyzing a core sample from a wellbore, where the analysis takes place in the field and proximate the wellbore. The system includes trailers adjacent one another and on a drilling pad, so that real time analysis of the core sample can occur after being extracted from the wellbore. One of the trailers can include a scanning unit for scanning the core sample and obtaining information within the core sample. Other trailers can include units that further analyze the core sample, such as by grinding, laser induced breakdown spectroscopy, Raman spectroscopy, and scanning the core material nano-structure. The core sample scanning involves a computed tomography (CT) scan, where a length of core sample is analyzed in the scanning unit.

A method and system for analyzing a core sample from a wellbore, where the analysis takes place in the field and proximate the wellbore. The system includes trailers adjacent one another and on a drilling pad, so that real time analysis of the core sample can occur after being extracted from the wellbore. One of the trailers can include a scanning unit for scanning the core sample and obtaining information within the core sample. Other trailers can include units that further analyze the core sample, such as by grinding, laser induced breakdown spectroscopy, Raman spectroscopy, and scanning the core material nano-structure. The core sample scanning involves a computed tomography (CT) scan, where a length of core sample is analyzed in the scanning unit.

A first set of radiation detectors may be disposable on the a drill string, wherein the first set of radiation detectors are capable of detecting gamma radiation and neutron radiation; and a combined chemical source spaced from the first set of radiation detectors, wherein the combined chemical source comprises a gamma radiation emitting material and a neutron radiation emitting material. The first set of radiation detectors and combined chemical source may be used in methods for logging a wellbore.

An apparatus for estimating a property of an earth formation and a borehole fluid includes a carrier configured to be disposed in a borehole, and a pulsed neutron measurement assembly including a pulsed neutron source configured to emit neutrons into the borehole and the earth formation, and a gamma ray detector. The apparatus also includes a fluid density measurement assembly including the gamma ray detector and a gamma ray source configured to irradiate a borehole fluid with gamma rays. The gamma ray detector is positioned relative to the gamma ray source to detect both of: gamma rays resulting from neutron interactions and gamma rays emitted from the borehole fluid in response to irradiation from the gamma ray source. The apparatus further includes a processor configured to differentiate a pulsed neutron gamma ray spectrum associated with the interactions from a density gamma ray spectrum.