Your search keyword '"Ruhl, Henry"' showing total 4 results

1. Long-term reductions in anthropogenic nutrients link to improvements in Chesapeake Bay habitat

Author

Ruhl, Henry A. and Rybicki, Nancy B.

Subjects

Chesapeake Bay -- Environmental aspects, Ecological restoration -- Methods, Estuarine area conservation -- Methods, Eutrophication -- Research, Science and technology

Abstract

Great effort continues to focus on ecosystem restoration and reduction of nutrient inputs thought to be responsible, in part, for declines in estuary habitats worldwide. The ability of environmental policy to address restoration is limited, in part, by uncertainty in the relationships between costly restoration and benefits. Here, we present results from an 18-y field investigation (1990-2007) of submerged aquatic vegetation (SAV) community dynamics and water quality in the Potomac River, a major tributary of the Chesapeake Bay. River and anthropogenic discharges lower water clarity by introducing nutrients that stimulate phytoplankton and epiphyte growth as well as suspended sediments. Efforts to restore the Chesapeake Bay are often viewed as failing. Overall nutrient reduction and SAV restoration goals have not been met. In the Potomac River, however, reduced in situ nutrients, wastewater-treatment effluent nitrogen, and total suspended solids were significantly correlated to increased SAV abundance and diversity. Species composition and relative abundance also correlated with nutrient and water-quality conditions, indicating declining fitness of exotic species relative to native species during restoration. Our results suggest that environmental policies that reduce anthropogenic nutrient inputs do result in improved habitat quality, with increased diversity and native species abundances. The results also help elucidate why SAY cover has improved only in some areas of the Chesapeake Bay. ecology | eutrophication | restoration | submerged aquatic vegetation doi/ 10.1073/pnas.1003590107

Published

2010

2. Connections between climate, food limitation, and carbon cycling in abyssal sediment communities

Author

Ruhl, Henry A., Ellena, Jacob A., and Smith, Kenneth L., Jr.

Subjects

Biotic communities -- Environmental aspects, Climate -- Research, Carbon cycle (Biogeochemistry) -- Research, Food consumption -- Research, Science and technology

Abstract

Diverse faunal groups inhabit deep-sea sediments over much of Earth's surface, but our understanding of how interannual-scale climate variation alters sediment community components and biogeochemical processes remains limited. The vast majority of deep-sea communities depend on a particulate organic carbon food supply that sinks from photosynthetically active surface waters. Variations in food supply depend, in part, on surface climate conditions. Proposed ocean iron fertilization efforts are also intended to alter surface production and carbon export from surface waters. Understanding the ecology of the abyssal sediment community and constituent metazoan macrofauna is important because they influence carbon and nutrient cycle processes at the seafloor through remineralization, bioturbation, and burial of the sunken material. Results from a 10-year study in the abyssal NE Pacific found that climate-driven variations in food availability were linked to total metazoan macrofauna abundance, phyla composition, rank-abundance distributions, and remineralization over seasonal and interannual scales. The long-term analysis suggests that broad biogeographic patterns in deep-sea macrofauna community structure can change over contemporary timescales with changes in surface ocean conditions and provides significant evidence that sediment community parameters can be estimated from atmospheric and upper-ocean conditions. These apparent links between climate, the upper ocean, and deep-sea biogeochemistry need to be considered in determining the long-term carbon storage capacity of the ocean. biogeochemistry | community structure | deep sea | ecology | macrofauna

Published

2008

3. Episodic organic carbon fluxes from surface ocean to abyssal depths during long-term monitoring in NE Pacific.

Author

Smith Jr., Kenneth L., Huffard, Christine L., Ruhl, Henry A., Messié, Monique, and Kahru, Mati

Subjects

SUBMARINE fans, CARBON compounds, OXYGEN consumption, MARINE sediments, CARBON cycle

Abstract

Growing evidence suggests substantial quantities of particulate organic carbon (POC) produced in surface waters reach abyssal depths within days during episodic flux events. A 29-year record of in situ observations was used to examine episodic peaks in POC fluxes and sediment community oxygen consumption (SCOC) at Station M (NE Pacific, 4,000-m depth). From 1989 to 2017, 19% of POC flux at 3,400 m arrived during high-magnitude episodic events (≥mean + 2 σ), and 43% from 2011 to 2017. From 2011 to 2017, when high-resolution SCOC data were available, time lags between changes in satellite-estimated export flux (EF), POC flux, and SCOC on the sea floor varied between six flux events from 0 to 70 days, suggesting variable remineralization rates and/or particle sinking speeds. Half of POC flux pulse events correlated with prior increases in EF and/or subsequent SCOC increases. Peaks in EF overlying Station M frequently translated to changes in POC flux at abyssal depths. A power-law model (Martin curve) was used to estimate abyssal fluxes from EF and midwater temperature variation. While the background POC flux at 3,400-m depth was described well by the model, the episodic events were significantly underestimated by ~80% and total flux by almost 50%. Quantifying episodic pulses of organic carbon into the deep sea is critical in modeling the depth and intensity of POC sequestration and understanding the global carbon cycle. [ABSTRACT FROM AUTHOR]

Published

2018

4. Deep ocean communities impacted by changing climate over 24 y in the abyssal northeast Pacific Ocean.

Author

Smith Jr., Kenneth L., Ruhl, Henry A., Kahru, Mati, Huffard, Christine L., and Sherman, Alana D.

Subjects

*CLIMATE change, *FOOD supply & the environment, *BENTHIC ecology, *OCEAN bottom, *OCEAN surface topography

Abstract

The deep ocean, covering a vast expanse of the globe, relies almost exclusively on a food supply originating from primary production in surface waters. With well-documented warming of oceanic surface waters and conflicting reports of increasing and decreasing primary production trends, questions persist about how such changes impact deep ocean communities. A 24-y time-series study of sinking particulate organic carbon (food) supply and its utilization by the benthic community was conducted in the abyssal northeast Pacific (~4,000-m depth). Here we show that previous findings of food deficits are now punctuated by large episodic surpluses of particulate organic carbon reaching the sea floor, which meet utilization. Changing surface ocean conditions are translated to the deep ocean, where decadal peaks in supply, remineralization, and sequestration of organic carbon have broad implications for global carbon budget projections. [ABSTRACT FROM AUTHOR]

Published

2013