Abstract: In one aspect, a system (5) for use in providing an approximation or estimation of a characteristic (for example, a bulk density value) of a deposit subject to a drilling operation is disclosed. In one form, the system (5) comprises a processor module (25) arranged in operable association with a network of sensors (30) operable for measuring one or more parameters relating to the operation of the drilling assembly (10). The processor module (25) is configured operable for receiving data/information derived from the network of sensors (30), and processing the data/information so as to provide a representation of the incursion (eg. depth of penetration into the relevant deposit) achieved by way of the drilling assembly (10).

Abstract: A method of determining a multi-dimensional distribution function of fluid types in a sample comprising: (i) applying a sequence of radio frequency pulses to the sample, each pulse having a predetermined phase, the sequence including: a diffusion encoding portion followed by a series of 180-degree refocusing pulses, wherein the diffusion encoding portion comprises repeating blocks of pulses, where the pulses in each block are separated by an interval time of 6, and the blocks themselves by a time delay; (ii) measuring a stimulated echo signal from the sample; (iii) repeating steps (i) to (ii) one or more times with constant 6 to obtain a phase-cycled data set of stimulated echo signal measurements, wherein for each repetition the phase of at least one of the RF pulses is shifted by a predetermined offset; (iv) repeating steps (i) to (iii) one of more times with different 6 values to obtain a series of phase-cycled data sets; and (v) analysing the series of phase-cycled data sets to provide a multi-dimensional

Abstract: Methods and systems are provided for tools having non-resonant circuits for analyzing a formation and/or a sample. For example, nuclear magnetic resonance and resistivity tools can make use of a non-resonant excitation coil and/or a detection coil. These coils can achieve desired frequencies by the use of switches, thereby removing the requirement of tuning circuits that are typical in conventional tools.

Abstract: Systems and methods are provided for investigating a downhole formation using a nuclear magnetic resonance (NMR) tool having two or more radio frequency receiving coils. While the tool is moving through the borehole, the formation is magnetized and resulting signals are obtained. In accordance with the present approach, the acquired signals can be resolved azimuthally and can be reconstructed to obtain an indication of a parameter of the formation at multiple locations along the length of the borehole.

Abstract: Adsorbed gas in a formation may be estimated. Nuclear magnetic resonance (NMR) data for a subsurface geological formation is obtained, and at least a portion of the NMR data is corrected to produce corrected NMR data. A NMR-based estimate of formation porosity is determined using the corrected NMR data. Dielectric permittivity data for the subsurface geological formation is obtained, and a dielectric permittivity-based estimate of the formation water-filled porosity is determined using the dielectric permittivity data. A gas volume is determined using the determined NMR-based estimate of the formation porosity and the determined dielectric permittivity-based estimate of the formation water-filled porosity. The gas volume may be determined by subtracting the determined dielectric permittivity-based estimate of the formation water-filled porosity from the determined NMR-based estimate of the formation porosity. The gas volume per unit volume of the formation may be determined using an equation of state.

Abstract: Methods and systems are provided for tools having non-resonant circuits for analyzing a formation and/or a sample. For example, nuclear magnetic resonance and resistivity tools can make use of a non-resonant excitation coil and/or a detection coil. These coils can achieve desired frequencies by the use of switches, thereby removing the requirement of tuning circuits that are typical in conventional tools.

Abstract: Systems and methods are provided for investigating a downhole formation using a nuclear magnetic resonance (NMR) tool having two or more radio frequency receiving coils. While the tool is moving through the borehole, the formation is magnetized and resulting signals are obtained. In accordance with the present approach, the acquired signals can be resolved azimuthally and can be reconstructed to obtain an indication of a parameter of the formation at multiple locations along the length of the borehole.

Abstract: A downhole logging tool, in an illustrative embodiment, includes an NMR measurement system with surface NMR microcoils located on an outer surface of the downhole logging tool. Each surface NMR microcoil has a central axis and is distributed around the outer surface of the logging tool with the surface NMR microcoil central axis perpendicular to the longitudinal axis of the logging tool. The NMR measurement system may have a central flow line in fluid communication with the drilling fluid. Additional surface NMR microcoils or a flow line microcoil may be disposed circumferentially around the central flow line with the surface NMR microcoil central axis and the flow line NMR microcoil central axis, respectively, perpendicular and parallel to the central flow line longitudinal axis. The NMR measurement system may include a bypass flow line in fluid communication with fluid in the wellbore annulus and/or the drill pipe.

Abstract: Adsorbed gas in a formation may be estimated. Nuclear magnetic resonance (NMR) data for a subsurface geological formation is obtained, and at least a portion of the NMR data is corrected to produce corrected NMR data. A NMR-based estimate of formation porosity is determined using the corrected NMR data. Dielectric permittivity data for the subsurface geological formation is obtained, and a dielectric permittivity-based estimate of the formation water-filled porosity is determined using the dielectric permittivity data. A gas volume is determined using the determined NMR-based estimate of the formation porosity and the determined dielectric permittivity-based estimate of the formation water-filled porosity. The gas volume may be determined by subtracting the determined dielectric permittivity-based estimate of the formation water-filled porosity from the determined NMR-based estimate of the formation porosity. The gas volume per unit volume of the formation may be determined using an equation of state.