Bradford Parkinson - US grants

This award is related to study of deformation and seismicity of Kilauea volcano using GPS data. The new, high precision geodetic data will ultimately allow one to distinquish among various models of the deep fault structure beneath Kilauea's

Much of what is known about the dynamics of active volcanos has been learned at Kilauea volcano. Deformation and seismicity data demonstrate that magmatic activity and slip on Kilauea's fault systems are coupled, yet the subsurface geometry of these faults and the deep structure of Kilauea's rift zones are poorly understood. The PI will analyze surface deformation data, including new GPS measurements, to elucidate the geometry of active rift and fault structures on Kilauea. Analysis of these unique data sets has the potential to answer fundamental questions concerning the dynamics of shield volcanos, and lead to an improved understanding of volcanic and earthquake hazards on Hawaii and elsewhere.

This multi-disciplinary research is directed at developing ultra precision machining techniques. Three main tasks are postulated: (1) the development of new and novel optical methods to improve metrology based on Global Positioning System satellite processing techniques, (2) the development of laminar flow hydraulic devices which provide smooth vibration-free actuation and spindle drive with improved machine temperature control, and (3) implementation of the computational technology and approach of artificial intelligence to automate some of the modeling procedures required to attain the ultimate in precision from a given machine. The knowledge gained from these three tasks will be combined in the building of a modest scale but realistic diamond turning machine to advance the technology of precision machining especially as it applies to the fabrication of optics for short wave form lithography.