| Contributors | Affiliation | Role |
|---|---|---|
| Carrington, Emily | University of Washington (FHL) | Principal Investigator |
| Nishizaki, Michael T. | University of Guelph | Contact |
| Gegg, Stephen R. | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Barnacle Respiration Model - Model examining mass transfer versus kinetic limitation of respiration in barnacles
A comparison of the relative importance of mass transfer versus reaction kinetics in limiting respiration rates was conducted using the non-dimensional approach described by Sanford and Crawford (2000).
Sanford, L. and Crawford, S. (2000). Mass transfer versus kinetic control of uptake across solid-water boundaries. Limnol. Oceangr. 45, 1180–1186.
Related files and references: Michael T. Nishizaki and Emily Carrington. (in press). The effect of water temperature and flow on respiration in barnacles: patterns of mass transfer versus kinetic limitation J Exp Biol
http://jeb.biologists.org/content/early/2014/03/04/jeb.101030.abstract
BCO-DMO Processing Notes
- Generated from original file "Data_archive_respiration_model.xlsx" contributed by Michael Nishizaki
- Approx Lat/Lon of FHL appended to enable data discovery in MapServer
- Parameter names edited to conform to BCO-DMO naming convention found at Choosing Parameter Name
| File |
|---|
Respiration_Model.csv (Comma Separated Values (.csv), 6.25 KB) MD5:6ff79bf604b9d5bc3e581f2d2230f27c Primary data file for dataset ID 505869 |
| Parameter | Description | Units |
| Lab_Id | Laboratory identifier where experiments were conducted | text |
| Lat | Latitude position of platform (South is negative) | decimal degrees |
| Lon | Longitude position of platform (West is negative) | decimal degrees |
| Water_velocity | Water velocity | cm/s |
| Temperature | Water temperature | degrees C |
| Mass_transfer | Mass transfer | dimensionless |
| Oxygen_saturation | Oxygen saturation | dimensionless |
| Website | |
| Platform | lab UW FHL OAEL |
| Report | |
| Start Date | 2010-09-01 |
| End Date | 2013-08-31 |
| Description | FHL Ocean Acidification Environmental Laboratory (OAEL)
Overview
FHL completed construction of a new 1500 sq. ft. experimental facility for ocean acidification research in summer 2011. The facility was funded by an award from NSF's Field Stations and Marine Laboratories (FSML) program, matching funds from the University of Washington, and private donors. The experimental facility currently includes an analytical chemistry laboratory, indoor mesocosms fed by a custom seawater-CO2 blending system and temperature control, laboratory space, as well as outdoor in-water mesocosms. Led by Dr. Emily Carrington, OAEL Director (ecarring@uw.edu), this state-of-the-art ocean acidification facility offers unique research and instructional opportunities for experimental manipulations with on-site monitoring of carbonate system parameters. FHL's location, facilities, and educational mission combine to make an ideal site for the experimental mesocosm and analytical facility. |
(Extracted from the NSF Award abstract)
Temperature influences organismal physiology, behavior, community interactions, and ecosystem function; yet rarely are the mechanisms understood. Accurately predicting the consequences of temperature for a species requires knowledge of: local climatic conditions, the relationship between climate and organismal body temperature, and the physiological and ecological consequences of body temperature. Few studies to date have explored all three areas concurrently. This project will examine in detail the biophysical, physiological, and ecological effects of temperature on a rocky intertidal community, a marine ecosystem that has emerged as a model system for studying the ecological consequences of temperature. It will focus on three major species, representative of rocky marine shore species worldwide: the barnacle, Balanus glandula, its predator Nucella ostrina, and the rockweed Fucus gardneri, which provides shelter for both species. The research is centered around three major goals: to develop biophysical models to explicitly link local climate to organismal body temperatures; to develop energy budget models to relate organismal body temperature to individual performance; and to identify the effect of temperature on interactions among the three species through a series of laboratory and field experiments. This research will provide a model system for understanding the effects of temperature on both individual performance and species interactions. It represents a significant contribution to understanding basic ecological questions, such as the role of temperature in structuring communities, and will also contribute to a more mechanistic understanding of the ecological consequences of future climate changes.
| Funding Source | Award |
|---|---|
| NSF Division of Ocean Sciences (NSF OCE) |