Bill Hammond, Professor

Nevada Geodetic Laboratory Nevada Bureau of Mines and Geology College of Science University of Nevada, Reno Reno, Nevada 89557, USA Office location: Scrugham Engineering Mines, Room 315 ORC ID#: 0000-0001-7367-9489 Office Phone: 1 (775) 784-6436 Fax: 1 (775) 784-1709 Email Bill Some of Bill's Interests: Tectonic geodesy GPS and InSAR measurement of crustal deformation Seismic cycle and hazard Dynamics of the lithosphere Vertical land motion Active uplift of mountain belts Loading of Earth's surface Fault mechanics Mantle flow Seismic anisotropy and tomography
Courses GPH 411/611/701(i) Geophysical Geodesy GPH 455/655 Global Geophysics and Geodynamics GEOL 701(i) GPS and InSAR data processing GEOL 701(i) Western US Tectonic Framework Also Cool Research Splotlight on Global Vertical Land Motion. 1-hour research talk at the Basin and Range Earthquake Hazard Summit (BRES) Research Splotlight on our work on the uplift of the Western Transverse Ranges in Eos. Walker Lane articles in: Nevada Today and Wired Magazine NSF 2016-2017 EarthScope Speaker Series. Spotlight on P085 and Bill: Basin and Range Geodesy Photos from July 8, 2021 Antelope Valley M 6.0 earthquake repspone
Research Profiles and Publication Lists Bill's Curriculum Vitae Google Scholar ResearchGate Twitter

Research Statement

The mountains of the Basin and Range were created in response to slow distributed province-wide tectonic extension that broke the Earth's crust along fault lines. Cumulative displacement along these faults over long periods of time built, and is still building, topographic relief, i.e. the valleys and ranges of the Province. Earthquakes associated with the infrequent slip on these faults generate the seismicity felt by people who live in the Great Basin and Sierra Nevada.

In my research I precisely measure this active crustal deformation using geodetic techniques such as the Global Positioning System (GPS) and Interferometric Synthetic Aperture Radar (InSAR). From these measurements I infer the style and distribution of Earth surface deformation that is a direct consequence of continent-scale tectonic processes. My main interest is in relating these motions to the organization of seismogenic faulting, and inferring the source of stresses in the lithosphere. With geodesy we can better understand the processes that control gradual deformation of the western U.S. continental interior, and hence better understand the physics of Earth deformation and the source of potentially damaging earthquakes.

Photos from MAGNET GPS fieldwork and other adventures (loads a little slow).