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1. An asterism generator for Keck all-sky precision adaptive optics

   https://doi.org/10.1117/12.2628623  

   Lilley, Scott J.; Wizinowich, Peter; Wetherell, Ed; Marin, Eduardo; Chin, Jason; Michaud-Baeyens, Thomas; Landry, Jean-Thomas; Boucher, Marc-André; Brousseau, Denis (August 2022, SPIE Astronomical Telescopes + Instrumentation)

   Schmidt, Dirk; Schreiber, Laura; Vernet, Elise (Ed.)

   As part of the Keck All-sky Precision Adaptive optics (KAPA) project a laser Asterism Generator (AG) is being implemented on the Keck I telescope. The AG provides four Laser Guide Stars (LGS) to the Keck Adaptive Optics (AO) system by splitting a single 22W laser beam into four beams of equal intensity. We present the design and implementation of the AG for KAPA. We discuss the optical design and layout, the details of the mechanical design and fabrication, and the challenges of designing the assembly to fit into the limited available space on the Keck telescope. 

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2. Daytime calibration and testing of the Keck All sky Precision Adaptive optics tomography system

   https://doi.org/10.1117/12.2628264  

   Surendran, Avinash; Delorme, Jacques R.; Correia, Carlos M.; Doyle, Steve; Ragland, Sam; Richards, Paul; Wizinowich, Peter L.; Hinz, Philip M.; Dillon, Daren; Laguna, Cesar; et al (August 2022, SPIE Astronomical Telescopes + Instrumentation)

   Schmidt, Dirk; Schreiber, Laura; Vernet, Elise (Ed.)

   The Keck All-Sky Precision Adaptive Optics (KAPA) system project will upgrade the Keck I AO system to enable laser tomography with a four laser guide star (LGS) asterism. This paper describes the new infrastructure which is being built for daytime calibration and testing of the KAPA tomographic algorithms. 

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3. Modeling the Sevier fault zone, southern Utah: validity testing and 3d analysis

   https://doi.org/10.18277/AKRSG.2023.35.03  

   Jasper, Neath; Surpless, Benjamin (July 2023, Keck Geology Consortium)

   Davidson, Cam; Wirth, Karl (Ed.)

   The Sevier fault zone near Orderville, Utah, represents a segmented normal fault system within the transition zone between the Basin and Range Province and the Colorado Plateau. This fault system consists of three primary segments: the Orderville segment, the Spencer Bench segment, and the Mt. Carmel Segment. The interactions between segments led to the development of complex structural geometries exposed along the fault zone. These geometries influence deformation and create fractures that affect expected permeability and fluid flow within the fault zone. These geometries also impact how slip-related energy is dissipated during earthquake-related slip propagation. Therefore, analysis of these geometries has implications for f luid flow and seismic hazard within segmented fault systems. I used the Move2020 software suite by Petex to develop a 3D model of the complexly-segmented Sevier fault zone near the city of Orderville in southern Utah. Earlier researchers’ subsurface interpretations were based on surface mapping rather than direct documentation of subsurface fault and layer geometries, so 3D model development permits validation of hypothesized subsurface structures. I digitized geologic contacts, faults, and stratigraphic horizons based on published geologic mapping and cross-sections to develop a 3D model of the fault network. I confirmed that the model does represent a well-constrained 3D system of the Sevier fault zone based on demonstrated integrity between the digital elevation model (DEM), and all available structural data. This work should provide future researchers with the data necessary to model evolution of the overall fault system, which will permit accurate determination of fault-related fracture development and the most likely fluid flow paths. Furthermore, development of a fully retro-deformable model of the fault zone will allow strain analysis that may help researchers understand how fault segment geometries impact earthquake slip propagation. This determination can be used to provide a conceptual framework for other researchers to better constrain the evolution of segmented fault zones worldwide. 

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4. Expedition 380 Scientific Prospectus: NanTroSEIZE Stage 3: Frontal Thrust Long-Term Borehole Monitoring System (LTBMS)

   https://doi.org/10.14379/iodp.sp.380.2017  

   Becker, K.; Kinoshita, M.; Toczko, S. (August 2017, Scientific prospectus)

   null (Ed.)

   The Nankai Trough Seismogenic Zone Experiment (NanTroSEIZE) program is a coordinated, multiexpedition drilling project designed to investigate fault mechanics and seismogenesis along subduction megathrusts through direct sampling, in situ measurements, and long-term monitoring in conjunction with allied laboratory and numerical modeling studies. The fundamental scientific objectives of the NanTroSEIZE drilling project include characterizing the nature of fault slip and strain accumulation, fault and wall rock composition, fault architecture, and state variables throughout the active plate boundary system. International Ocean Discovery Program (IODP) Expedition 380 will deploy a permanent long-term borehole monitoring system (LTBMS) in a new cased hole at Site C0006 above the frontal thrust, where previous expeditions have conducted logging-while-drilling and coring operations. This deployment will be the third borehole observatory deployed as part of the NanTroSEIZE program, and it will extend the existing NanTroSEIZE LTBMS network seaward to include the frontal thrust region of the Nankai accretionary prism. This expedition will cover a period of 40 days, beginning on 12 January 2018 and ending on 24 February. The LTBMS sensors will include seafloor reference and formation pressure sensors, a thermistor string, a broadband seismometer, a tiltmeter, a volumetric strainmeter, geophones, and accelerometers. The casing plan does not include a screened interval for this LTBMS; the monitoring zone will be isolated from the seafloor by a swellable packer (inside the casing) and cement at the casing shoe. This LTBMS will be later linked to the Dense Oceanfloor Network System for Earthquakes and Tsunamis (DONET) submarine network. This Scientific Prospectus outlines the scientific rationale, objectives, and operational plans for Site C0006. A congruent “NanTroSEIZE Investigation at Sea” will convene researchers aboard the D/V Chikyu to use the latest techniques and equipment to reexamine cores, shipboard measurement data (including X-ray computed tomography scans), and logging-while-drilling data collected during NanTroSEIZE Stage 1 in 2007. 

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5. Constraining the slip rate of the Owl Lake Fault by using LiDAR data and fault scarp degradation models

   https://doi.org/10.32469/10355/94111  

   Altuntas, Gozde; Gomez, Francisco (August 2022, University of Missouri)

   The Owl Lake Fault is an active, 19 to 25-km-long, left-lateral strike-slip fault that divaricates NE from the Garlock Fault toward Death Valley in eastern California and transfers regional strain to the fault systems in Death Valley. As an active fault, the Owl Lake Fault is a poorly understood link between the extension of Death Valley and other active faults within Mojave Desert. In addition to the larger tectonic framework, improved understanding of the Owl Lake Fault as a seismogenic structure has direct implication for the assessment of the earthquake hazard in Eastern California. A significant limitation on the understanding of the Owl Lake Fault's role is the wide range of estimates previously reported for its slip rate. These range from 0.5 to 7.8 mm/yr, which implies the Owl Lake Fault may accommodate nearly all of the present-day slip on the Garlock Fault. The project aims to constrain the slip rate and understand kinematics of the Owl Lake Fault. For this project, I have used recent airborne LiDAR data (approximately 4.6 points/m2) to map the fault and precisely measure horizontally offset landforms along the Owl Lake Fault. Subsequent to LiDAR mapping, field work facilitated the ground-truth verification of initial mapping as well as more precise measurements of small fault offsets using kinematic GPS and low-altitude photogrammetry. The detailed, local microtopography permits assessing the smallest offsets (75-100 cm) which are interpreted as reflecting the last coseismic offset. Initial efforts at refining the slip rate use scarp degradation models to infer the ages of alluvial fans and stream terraces that are offset by faulting. The final step for this project involves estimating slip rate, magnitude, and recurrence interval. Neotectonic investigations allowed to constrain the slip rate of the Owl Lake Fault as 1.1 - 1.4 mm/yr. The Owl Lake Fault can produce earthquake with the magnitude M=7.2 with the 1030 -- 1430-yr recurrence interval. This study demonstrates that the Owl Lake Fault is part of the same hazard consideration as the central Garlock Fault in eastern California. 

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