Abstract: This application relates to systems and methods for stimulating hydrocarbon bearing rock formations using a downhole hybrid tool for discharging a fracturing solution to a wellbore in the formation and for delivering an output laser beams to the rock formation.

Abstract: An example laser tool is configured to operate within a wellbore of a hydrocarbon-bearing rock formation. The laser tool includes one or more optical transmission media. The one or more optical transmission media are part of an optical path originating at a laser generator configured to generate a laser beam having an axis. The one or more optical transmission media are for passing the laser beam. The laser tool includes an optical element that is part of the optical path. The optical element is for receiving the laser beam from the one or more optical transmission media and for output to the hydrocarbon-bearing rock formation. The laser tool includes a color applicator head for discharging one or more coloring agents to a surface in the wellbore in a path of the laser beam.

Abstract: A downhole tool can be advanced downhole a wellbore. The downhole tool can include an electromagnetic source, a directional antenna, and a casing. The casing can either completely or partially consist of ceramic materials. The directional antenna can be oriented to direct electromagnetic radiation generated by the electromagnetic source towards the ceramic materials of the casing. In response to receiving the electromagnetic radiation, the ceramic materials can absorb the electromagnetic radiation, which can cause the ceramic materials to rapidly increase in temperature.

Abstract: This application relates to systems and methods for stimulating hydrocarbon bearing formations using a downhole laser tool. An example laser perforation tool is for perforating a wellbore in a downhole environment within a hydrocarbon bearing formation. The laser perforation tool includes a plurality of perforation units disposed within an elongated body of the laser perforation tool. Each of the plurality of perforation units includes a laser beam redirection tool coupled to a laser head. The beam redirection tool alters a direction of an output laser beam.

Abstract: An example laser tool includes a laser head to output a laser beam and a robotic arm that is articulated and that is connected to the laser head. The robotic arm includes segments that are connected by flexible joints to enable movement of the laser head in six degrees of freedom. A control system is configured to control the robotic arm to direct output of the laser beam.

Abstract: Systems and methods for stimulating hydrocarbon bearing formations include using a downhole laser tool. An example laser perforation tool is for perforating a wellbore in a downhole environment within a hydrocarbon bearing formation. The laser perforation tool includes a plurality of perforation units disposed within an elongated body of the laser perforation tool. Each of the plurality of perforation units includes a laser beam redirection tool coupled to a laser head. The beam redirection tool alters a direction of an output laser beam.

Abstract: An example system includes a laser tool configured for downhole movement. The laser tool includes an optical assembly configured to shape a laser beam for output. The laser beam may have an optical power of at least one kilowatt (1 kW). A housing contains the optical assembly. The housing is configured for movement to direct the output laser beam within a wellbore. The movement includes rotation of the laser tool around a longitudinal axis of the housing and tilting the housing relative to a longitudinal axis of the wellbore. A control system is configured to control at least one of the movement of the housing or an operation of the optical assembly to direct the output laser beam within the wellbore.

Abstract: A method for monitoring hydrate formation in an interior of a tube may include deploying a first hydrate controller device at a first location on an exterior surface of the tube. The method may include deploying a second hydrate controller device at a second location on the exterior surface of the tube. The method may include transmitting, by the first hydrate controller device, first acoustic signals towards the interior of the tube. The first acoustic signals may include a first frequency value and a first amplitude value associated to a transmission power level. The method may include receiving, by the second hydrate controller device, the first acoustic signals. The method may include measuring, by the second hydrate controller device, a reception power level of the first acoustic signals.

Abstract: An example CO2 monitoring systems is configured for monitoring levels of CO2 in a wellbore. A CO2 monitoring system may include one or more laser monitoring tools. A laser monitoring tool may include an optical element to output a laser beam, a detector to receive the laser beam, a first chamber housing the optical element and detector, and a second chamber including an inlet and an outlet receive and release, respectively, wellbore fluid. The first chamber may be in fluid connection with second chamber via a gas permeable membrane. Gas may permeate from second chamber into first chamber. Gas in the first chamber is subjected to a laser beam. Absorption of light by the gas is measured, and content of gas is determined based at least in part on the amount of light absorption by the gas.

Abstract: An example laser tool is configured to operate within a wellbore of a hydrocarbon-bearing rock formation. The laser tool includes one or more optical transmission media as part of an optical path originating at a laser generator configured to generate a laser beam having an axis. The laser tool includes an optical element for receiving the laser beam from the one or more optical transmission media and for output to the hydrocarbon-bearing rock formation. The laser tool includes a purging head for removing dust or vapor from a path of the laser beam. The purging head is for discharging two or more purging gas streams. The purging head may include a coaxial flow assembly and a helical flow assembly. A coaxial purging gas stream may flow in a direction parallel to the axis. A helical purging gas stream may flow in a helical pattern around and substantially along the axis.

Abstract: An example laser system includes one or more optical transmission media that are part of an optical path originating at a laser generator configured to generate an input laser beam. The example laser system includes an analyzer for receiving the input laser beam and for characterizing at least a profile and energy of the input laser beam. The example laser system includes a circulator for receiving the input laser beam from the analyzer and for minimizing or eliminating reflections. The example laser system includes a beam transformer for receiving the input laser beam from the circulator and for altering at least one property of the input laser beam thereby generating an output laser beam. The example laser system includes a writing head for altering at least one optical property of the beam transformer.

Abstract: The present disclosure relates to systems and methods for drilling a hole(s) in a subsurface formation utilizing laser energy that is controlled by an optical manipulation system. Various embodiments of the disclosed systems and methods use a laser with a laser source (generator) located on the surface with the power conveyed via fiber optic cables down the wellbore to a downhole target via a laser tool. The optical manipulation system provides the flexibility to control and manipulate the beams, resulting in an optimized optical design with fewer optical components and less mechanical motion. Different beam shapes can be achieved by the different optical lenses and designs disclosed in this specification. Additionally, a purging system is disclosed that is configured to clear a path of the laser beam, assist in manipulating the tool, or both. The rotating and purging features contribute to creating a clean hole with no melt.

Abstract: An example laser tool configured for downhole laser beam generation is operable within a wellbore. The laser tool includes a generator to generate a laser beam. The generator is configured to fit within the wellbore, to withstand at least some environmental conditions within the wellbore, and to generate the laser beam from within the wellbore. The laser beam has an optical power of at least one kilowatt (1 kW). A control system is configured to control movement of at least part of the laser tool to cause the laser beam to move within the wellbore.

Abstract: A laser tool apparatus includes a tool body; a fiber optic cable disposed in the tool body, the fiber optic cable including a laser head that emits a laser beam; a reshape optic disposed coaxially downstream of the fiber optic, the reshape optic reshaping the laser beam emitted from the laser head; and a flexible cable attached to the reshape optic. The flexible cable flexibly orients the laser beam at a desired angle within a borehole.

Abstract: An example laser tool includes a laser head to output a laser beam and a robotic arm that is articulated and that is connected to the laser head. The robotic arm includes segments that are connected by flexible joints to enable movement of the laser head in six degrees of freedom. A control system is configured to control the robotic arm to direct output of the laser beam.

Abstract: This application relates to systems and methods for stimulating hydrocarbon bearing formations using a downhole laser tool.

Abstract: This application relates to systems and methods for stimulating hydrocarbon bearing formations using a downhole laser tool.

Abstract: This application relates to tools, systems, and methods for stimulating hydrocarbon bearing formations using energy from sonoluminescence.

Abstract: A method of drilling a wellbore that traverses a formation, the method comprising the steps of inserting a one-stage drilling tool into the wellbore, the one-stage drilling tool comprising a laser head configured to produce a drilling beam, a completion sheath configured to line the wellbore, and a centralizer configured to support the completion sheath within the wellbore, operating the laser head to produce the drilling beam, wherein the drilling beam comprises a laser, wherein the drilling beam has a divergent shape comprising a base at a distance from a front end of the laser head and an apex proximate to the front end of the laser head, wherein a diameter of the base of the drilling beam is greater than a diameter of the one-stage drilling tool, and drilling the formation with the drilling beam, wherein the laser of the drilling beam is operable to sublimate the formation.

Abstract: The present disclosure describes methods and systems for downhole well integrity reconstruction in a hydrocarbon reservoir. One method for downhole well integrity reconstruction in a hydrocarbon reservoir includes: positioning, a laser head at a first subterranean location, wherein the laser head is attached to a tubular inside of a wellbore; directing, by the laser head, a laser beam towards a leak on the wellbore; and sealing the leak using the laser beam.