Abstract: A coiled tubing system includes a coiled tubing string configured to couple to a downhole tool to move the downhole tool along a geothermal well, an injector head configured to control movement of the coiled tubing string and the downhole tool along the geothermal well, one or more sensors configured to capture sensor data indicative of a distance traveled by the coiled tubing string along the geothermal well, and a controller configured to control operation of the injector head to move the coiled tubing string and the downhole tool to a measured depth within the geothermal well that corresponds to an intersection of a feature with the geothermal well based on the sensor data received from the one or more sensors.

Abstract: A radiation particle strike detection system is disclosed. The radiation particle strike detection system includes a radiation particle detector and a controller coupled to the radiation particle detector. The radiation particle detector is overlayed on at least one surface of a payload that is sensitive to interaction with radiation particles. The radiation particle detector is configured to undergo a change in state responsive to a radiation particle strike at a location on the radiation particle detector. The controller is configured to 1) monitor a state of the radiation particle detector; 2) detect a radiation particle strike on the radiation particle detector based on a change in state of the radiation particle detector; and 3) determine a location and time of the radiation particle strike on the radiation particle detector based on the change in state of the particle detector.

Abstract: A radiation particle strike detection system is disclosed. The radiation particle strike detection system includes a radiation particle detector and a controller coupled to the radiation particle detector. The radiation particle detector is overlayed on at least one surface of a payload that is sensitive to interaction with radiation particles. The radiation particle detector is configured to undergo a change in state responsive to a radiation particle strike at a location on the radiation particle detector. The controller is configured to 1) monitor a state of the radiation particle detector; 2) detect a radiation particle strike on the radiation particle detector based on a change in state of the radiation particle detector; and 3) determine a location and time of the radiation particle strike on the radiation particle detector based on the change in state of the particle detector.

Abstract: A compound of formula (I): namely (2S)-2-amino-4-{[2-(ethanimidoylamino)ethyl]thio}butanoic acid, compound with phosphoric acid, or a solvate or physiologically functional derivative thereof, is useful as a relatively non-hygroscopic selective inhibitor of inducible nitric oxide synthase.

Abstract: A compound of formula (I): namely (2S)-2-amino-4-{[2-(etha-nimidoylamino)ethyl]thio}butanoic acid, compound with prosphoric acid, or a solvate or physiologically functional derivative thereof, is useful as a relatively non-hygroscopic selective inhibitor of inducible nitric oxice synthase.