Curt Storlazzi, PhD
My interests span the coastal zone, from seacliff erosional processes to sediment dynamics in the shallow coastal ocean. My research focuses on the quantitative study of hydrodynamics, sediment transport, and geomorphology in coastal and marine environments.
Research Topics
Coral reef morphology, hydrodynamics, and sediment, nutrient, contaminant, and larval transport
The role of coral reefs and other coastal ecosystems in coastal hazard risk reduction
The interplay between geologic structure, climatic fluctuations, and coastal processes
High-resolution oceanographic instrumentation and coastal mapping techniques
The influence of physical processes on coral reef ecosystems
Many tropical coastal environments have been impacted by infrastructure development, nutrient and contaminant delivery, and natural and human-induced sedimentation. The high geomorphic and hydrodynamic complexity both within and between coral reefs, in conjunction with past technical restrictions, has limited our understanding of the nature of flow and the resulting flux of physical, chemical, and biologic material in these ecosystems. Understanding the physical controls on the timing and magnitude of flow and sediment, larvae, nutrient, and contaminant transport, along with their impact on seafloor geomorphology, stability, and sedimentation in these refugia are essential to assessing modern anthropogenic impacts (climate change, etc.) on these ecosystems and help guide how restoration can increase the resiliency of coral reef-lined coastal communities.
See: Coral Reef Project and The Value of U.S. Coral Reefs for Risk Reduction (links below)
The influence of climate change and sea-level rise on coral reef-lined coasts
Observations show that sea level is rising and recent projections indicate sea level will exceed 1.0 m, and may reach 2.0 m, above 2000 levels by the end of the 21st century. The amount of land and water available for human habitation, water and food sources, and ecosystems along coral reef-lined coasts is limited and vulnerable to wave-driven flooding during storms. Rising sea levels will further exacerbate the impacts of storms on coral reef-lined coasts by reducing wave breaking (and thus energy dissipation) over reefs and result in greater wave energy impacting the shoreline, causing increased flooding and changes to the coast such as erosion. Understanding the physical controls on the timing and magnitude of flooding, along with their impact on coastal geomorphology, are essential to assessing impacts on, and the future sustainability of, coastal infrastructure, agriculture, freshwater availability, and ecosystems.
See: Low-lying areas of tropical Pacific islands (links below)
Professional Experience
2002-present: Research Geologist and Oceanographer, USGS Coastal and Marine Hazards and Resources Program
2002-present: Research Associate, University of California at Santa Cruz (UCSC) Institute for Marine Sciences
Education and Certifications
2002-2004: Research Fellow, Partnership for Interdisciplinary Studies of Coastal Oceans Consortium
2000-2002: Post-doctoral Researcher, UCSC Institute for Marine Sciences
2000: Ph.D., UCSC, Earth Sciences Department
1996: B.Sc., University of Delaware, Geology Department
Science and Products
A model for wave control on coral breakage and species distribution in the Hawaiian Islands
Local wind forcing of the Monterey Bay area inner shelf
Flow patterns and current structure at the USS Arizona Memorial: April, 2005
Application of GPS drifters to track Hawaiian coral spawning
Dynamics of the physical environment at the USS Arizona memorial: 2002-2004
Coastal circulation and sediment dynamics along West Maui, Hawaii: Part III: Flow and particulate dynamics during the 2003 summer coral spawning season
Holocene reef accretion: southwest Molokai, Hawaii, U.S.A.
Sediment resuspension and transport patterns on a fringing reef flat, Molokai, Hawaii
Wave- and tidally-driven flow and sediment flux across a fringing coral reef: Southern Molokai, Hawaii
Coastal circulation and sediment dynamics along west Maui, Hawaii: Part II — 2003 Hydrographic Survey Cruises A-3-03-HW and A-4-03-HW report on the spatial structure of currents, temperature, salinity and turbidity along western Maui
Quantitative morphology of a fringing reef tract from high-resolution laser bathymetry: Southern Molokai, Hawaii
Long-term, high-frequency current and temperature measurements along central California: Insights into upwelling/relaxation and internal waves on the inner shelf
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Science and Products
A model for wave control on coral breakage and species distribution in the Hawaiian Islands
Local wind forcing of the Monterey Bay area inner shelf
Flow patterns and current structure at the USS Arizona Memorial: April, 2005
Application of GPS drifters to track Hawaiian coral spawning
Dynamics of the physical environment at the USS Arizona memorial: 2002-2004
Coastal circulation and sediment dynamics along West Maui, Hawaii: Part III: Flow and particulate dynamics during the 2003 summer coral spawning season
Holocene reef accretion: southwest Molokai, Hawaii, U.S.A.
Sediment resuspension and transport patterns on a fringing reef flat, Molokai, Hawaii
Wave- and tidally-driven flow and sediment flux across a fringing coral reef: Southern Molokai, Hawaii
Coastal circulation and sediment dynamics along west Maui, Hawaii: Part II — 2003 Hydrographic Survey Cruises A-3-03-HW and A-4-03-HW report on the spatial structure of currents, temperature, salinity and turbidity along western Maui
Quantitative morphology of a fringing reef tract from high-resolution laser bathymetry: Southern Molokai, Hawaii
Long-term, high-frequency current and temperature measurements along central California: Insights into upwelling/relaxation and internal waves on the inner shelf
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.