SEMINAR - J. Fred Bair

Development Geology of the Antelope Shale: Section 1Y, Cymric Field, San Joaquin Valley, California

J. Fred Bair
MWSS Asset Development TeamChevron North America Exploration and Production Company

Wednesday, October 1st, 2008

The Antelope Shale reservoir in Section 1Y, Cymric Field, San Joaquin Valley, California is one of Chevron’s key assets. The reservoir is a Miocene Age member of the Monterey Formation composed of Opal A (amorphous), Opal CT (cristobalite, tridimite) and Quartz phase diatomaceous deep water sediments. The Antelope Shale has an anomalously high average porosity of 58%, high initial oil saturations of up to 60%, and low permeabilities of 3 millidarcys. Development geology skills required to process this complex reservoir and involve: obtaining, analyzing, and evaluating open hole well logs; structural mapping and correlation; fracture mapping using development geophysics; and an understanding of the diagenetic process.

SEMINAR - Clive Dorman

Tidal Bore on the Severn River

Clive Dorman
Department of Geological Sciences
San Diego State University

Wednesday, September 24th, 2008

Tides progress up the Severn River in SW England as a tidal bore moving faster than 6 m/s. During spring tides, the leading edge of the bore can be up to 2 m high, taking more than an hour to travel from the lower portion of the river to past Gloucester. This is sufficient to attract surfers from around the world. The North Atlantic amphidromic system interacts with the broad continental shelf around the U.K. to produce a complicated field of large tidal ranges. This forces a twice daily standing wave along the Bristol Channel, that further amplifies the tidal range toward the back of the Channel and the mouth of the Severn River. High tide is effectively a very long wave that moves against the out bound Severn River flow, so the leading edge sharpens, forming a bore. The shape of the leading edge varies between a smooth wave and a breaking wave. The presentation will include two short videos of the bore.

SEMINAR - Norrie Robbins

Utilization of Geological Techniques to Help Solve an Archaeological Puzzle: When Did People Arrive in North America?

Eleanora (Norrie) Robbins
Department of Geological Sciences
San Diego State University

Wednesday, September 17th, 2008

Knut Fladmark hypothesized that as soon as boat technology was developed 40,000 years ago, people probably traveled the oceans. The 40,000-year-ago shoreline is now below 150-160 ft (50 m) of water and an unknown thickness of sediment. So evidence for boat transport by maritime people would be under the today’s oceans. Geological data could provide locations of specific paleoshorelines and general sedimentation rates. Palynological data from cores could provide information about introduction of medicinal and food plants from distant sources. Underwater geophysical techniques such as magnetic mapping, resistivity methods, seismic profiling and ground penetrating radar might be useful too.
An interesting idea about changing shorelines was successfully tested by Thomas Dillehay and Ruth Gruhn at the Monte Verde cave sites in Chile. They suggested searching for onshore caves along narrow continental shelves. Submarine canyons also should be searched because they are often fracture zones. Such places not only might have now-submerged caves but are also subjected to periodic sediment removal. So, submarine canyons might be good places for deep SCUBA divers to search for caves and buried artifacts.
It is easy to envision early maritime people, staying by the paleo-shoreline, taking advantage of abundant marine food sources. Through time, descendents would have followed the rise and fall of sea level. At the time of peak glaciation 21,000 years ago, the entire continental shelf was exposed. Then as sea level rose upon glacial melting, village sites would have moved shoreward accordingly. The 8,000-year-ago shoreline is now below 1.5-6 m (5-20 ft) of water. Indeed, large, heavy artifacts from a submerged village of that age are often seen by divers especially near the La Jolla Beach and Tennis Club. Around 7,000 years ago, an episode of intense erosion occurred, which would have reduced water clarity, affected marine animal distribution, and forced people toward onshore sources of reliable food.
Other evidence for early marine travel might be in the creation songs of today’s coastal indigenous people. Many songs tell of creation from the ocean and mention boats. One even tells of the arrival of the “new people” who hunted big game. The creation songs may help prove that the earliest ancestors arrived here very, very long ago by boat. Geologists are needed to help lead the search.

Dr. Eleanora (Norrie) Robbins is a paleo-palynologist, former student of Paul S. Martin (“Pleistocene Extinctions”), and retired from the U.S. Geological Survey in Reston after 34 years. She is now adjunct faculty in the Dept. of Geological Sciences at SDSU. She mapped for Louis Leakey in 1965 at the Chelles-Acheulian Olorgesailie

Thesis Defense - Fall 2008 - Ben Slotnick

Biotic response of Tethyan bathyal ostracodes through the Eocene-Oligocene Transition from the Massignano Composite Stratotype Section (east central Italy)

Ben Slotnick
M.S. Candidate
Department of Geological Sciences
San Diego State University
Advisor Stephen Schellenberg

Monday, September 8th, 2008

ABSTRACT
The Eocene-Oligocene Transition (EOT) is marked by a double-stepped ~1.3‰ positive excursion in d18O over an ~300 kyr interval (i.e., Oi-1; Miller et al., 1991; Zachos et al., 1996; Coxall et al., 2005) and a deepening of the calcium compensation depth (CCD) interpreted to represent marked Antarctic glaciation and global ocean-atmosphere cooling. A ~0.5 m (~55-70 kyr) resolution ostracode faunal study of the Massicore, drilled adjacent to and up-section from the Italian Massignano quarry stratotype section that contains the Eocene-Oligocene GSSP (i.e., base of the Priabonian stage), revealed two transient increases in Krithe and decreases in faunal evenness, enthalpy, eH, and Simpson’s Index that lag two surface water cooling pulses based on a dinocyst-based sea surface temperature (DSST) proxy (van Mourik et al., in prep). These transient ostracode faunal changes may reflect changing physico-chemical water properties, increased sedimentation rates, variable food availability in the benthos, and/or intensifying thermohaline circulation from the Indian or Atlantic Ocean through the paleotethyan seaway. Ordination and cluster analyses also show minor faunal differences during times of relatively cold and warm surface waters based on the DSST proxy. Comparisons made between these Massicore ostracode data and re-analyzed Massignano Quarry ostracode data from Dall’Antonia et al. (2003) revealed major similarites (i.e., similar relative abundances among common taxa where both studies overlap) making it practical for us to combine both records in order to provide a more complete Tethyan ostracode record through the broader EOT and spanning Oi-1 at the stratotype locality.