R. R. Greene
Oregon State University
Network
Latest external collaboration on country level. Dive into details by clicking on the dots.
Publication
Featured researches published by R. R. Greene.
Geochemistry Geophysics Geosystems | 2006
John E. Lupton; David A. Butterfield; Marvin D. Lilley; Leigh Evans; Ko-ichi Nakamura; William W. Chadwick; Joseph A. Resing; Robert W. Embley; Eric James Crane Olson; Giora Proskurowski; Edward T. Baker; Cornel E. J. de Ronde; Kevin K. Roe; R. R. Greene; Geoff Lebon; Conrad Young
Although CO2 is generally the most abundant dissolved gas found in submarine hydrothermal fluids, it is rarely found in the form of CO2 liquid. Here we report the discovery of an unusual CO2-rich hydrothermal system at 1600-m depth near the summit of NW Eifuku, a small submarine volcano in the northern Mariana Arc. The site, named Champagne, was found to be discharging two distinct fluids from the same vent field: a 103°C gas-rich hydrothermal fluid and cold (<4°C) droplets composed mainly of liquid CO2. The hot vent fluid contained up to 2.7 moles/kg CO2, the highest ever reported for submarine hydrothermal fluids. The liquid droplets were composed of ∼98% CO2, ∼1% H2S, with only trace amounts of CH4 and H2. Surveys of the overlying water column plumes indicated that the vent fluid and buoyant CO2 droplets ascended <200 m before dispersing into the ocean. Submarine venting of liquid CO2 has been previously observed at only one other locality, in the Okinawa Trough back-arc basin (Sakai et al., 1990a), a geologic setting much different from NW Eifuku, which is a young arc volcano. The discovery of such a high CO2 flux at the Champagne site, estimated to be about 0.1% of the global MOR carbon flux, suggests that submarine arc volcanoes may play a larger role in oceanic carbon cycling than previously realized. The Champagne field may also prove to be a valuable natural laboratory for studying the effects of high CO2 concentrations on marine ecosystems.
Geochemistry Geophysics Geosystems | 2014
Robert W. Embley; Susan G. Merle; Edward T. Baker; Ken H. Rubin; John E. Lupton; Joseph A. Resing; Robert P. Dziak; Marvin D. Lilley; William W. Chadwick; Timothy M. Shank; R. R. Greene; Sharon L. Walker; J. H. Haxel; Eric James Crane Olson; Tamara Baumberger
We present multiple lines of evidence for years to decade-long changes in the location and character of volcanic activity at West Mata seamount in the NE Lau basin over a 16 year period, and a hiatus in summit eruptions from early 2011 to at least September 2012. Boninite lava and pyroclasts were observed erupting from its summit in 2009, and hydroacoustic data from a succession of hydrophones moored nearby show near-continuous eruptive activity from January 2009 to early 2011. Successive differencing of seven multibeam bathymetric surveys of the volcano made in the 1996–2012 period reveals a pattern of extended constructional volcanism on the summit and northwest flank punctuated by eruptions along the volcanos WSW rift zone (WSWRZ). Away from the summit, the volumetrically largest eruption during the observational period occurred between May 2010 and November 2011 at ∼2920 m depth near the base of the WSWRZ. The (nearly) equally long ENE rift zone did not experience any volcanic activity during the 1996–2012 period. The cessation of summit volcanism recorded on the moored hydrophone was accompanied or followed by the formation of a small summit crater and a landslide on the eastern flank. Water column sensors, analysis of gas samples in the overlying hydrothermal plume and dives with a remotely operated vehicle in September 2012 confirmed that the summit eruption had ceased. Based on the historical eruption rates calculated using the bathymetric differencing technique, the volcano could be as young as several thousand years.
Geophysical Research Letters | 2009
John E. Lupton; Richard J. Arculus; R. R. Greene; Leigh Evans; Charlotte Goddard
Geochemistry Geophysics Geosystems | 2007
Gary J. Massoth; Edward T. Baker; Tim J. Worthington; John E. Lupton; Cornel E. J. de Ronde; Richard J. Arculus; Sharon L. Walker; Ko-ichi Nakamura; Jun-ichiro Ishibashi; Peter Stoffers; Joseph A. Resing; R. R. Greene; Geoffrey T. Lebon
Geochemistry Geophysics Geosystems | 2012
John E. Lupton; Richard J. Arculus; Joseph A. Resing; Gary J. Massoth; R. R. Greene; Leigh Evans; Nathan J. Buck
Archive | 2005
Robert W. Embley; Cornel E. J. de Ronde; Gary J. Massoth; Ian C. Wright; D. A. Butterfield; Michael R. Clark; William W. Chadwick; John E. Lupton; Alexander Malahoff; Ashley A. Rowden; Matthew B. Stott; Laura Evans; R. R. Greene; A. D. Opatkiewicz; Kevin K. Roe
Archive | 2009
John E. Lupton; D. A. Butterfield; Marvin D. Lilley; J. A. C. Resing; Robert W. Embley; Richard J. Arculus; Ken H. Rubin; Laura Evans; R. R. Greene
Archive | 2010
Christopher R. German; Timothy M. Shank; Marvin D. Lilley; John E. Lupton; Donna K. Blackman; Kenneth M. Brown; Thomas R. Baumberger; Gretchen L. Früh-Green; R. R. Greene; Mitsuo Saito; Sean P. Sylva; Keikichi G. Nakamura; J. Stanway; Dana R. Yoerger; Leonid A. Levin; Andrew R. Thurber; Javier Sellanes; M. Mella; J. O. Munoz; J. L. Diaz-Naveas
Archive | 2009
Sharon L. Walker; Edward T. Baker; John E. Lupton; J. A. C. Resing; Peter Crowhurst; R. R. Greene; Nathaniel J. Buck
Geochemistry Geophysics Geosystems | 2006
John E. Lupton; David A. Butterfield; Marvin D. Lilley; Leigh Evans; Ko-ichi Nakamura; William W. Chadwick; Joseph A. Resing; Robert W. Embley; Eric James Crane Olson; Giora Proskurowski; Edward T. Baker; Cornel E. J. de Ronde; Kevin K. Roe; R. R. Greene; Geoff Lebon; Conrad Young
Collaboration
Dive into the R. R. Greene's collaboration.
Joint Institute for the Study of the Atmosphere and Ocean
View shared research outputs