Contributors | Affiliation | Role |
---|---|---|
Gaylord, Brian | University of California-Davis (UC Davis) | Principal Investigator |
Ninokawa, Aaron T. | University of California-Davis (UC Davis-BML) | Student, Contact |
Saley, Alisha | University of California-Davis (UC Davis-BML) | Student |
Shalchi, Roya | University of California-Davis (UC Davis-BML) | Student |
Newman, Sawyer | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Experiment details
We conducted additional incubations (n=87, between 3 and 9 per experiment day) without mussels throughout the trials as experimental blanks to determine background changes in alkalinity. We excluded from our analysis any experimental days where background alkalinity changes exceeded 5 µmol kg-1.
The mean of the absolute values of alkalinity change during the incubations of these experimental blanks was 1.3 ± 1.2 µmol kg-1 (n = 72).
We performed all computations with R statistical software, version 4.1.0. We performed carbonate system calculations using the package seacarb, using equilibrium constants from Lueker et al. We computed linear mixed models using the lmer function in in the lmertest package in R and focused on assessing likely candidate parameters as fixed factors, and mussel collection date as a random intercept to account for natural seasonal differences between cohorts. Conditional R2 was calculated with the package MuMIn. We determined parameters for non-linear fits employed to model dissolution rates by minimizing the sum of squares of model residuals using the optim function.
Colors for plots were chosen from color palettes in the cmocean package in R.
- Removed special characters (e.g., periods) from column names and replaced with underscores
- Replaced NAs with "" (blanks) to indicate no data values
- Changed the presentation of species values from "mytilus_californianus" to "Mytilus californianus" and added AphiaID and LSID to the data file
- All numeric float fields rounded to 2 degrees of precision
- A column was added to the data file to represent the incubation start time in UTC, this new column is called ISO_start_DateTime_UTC
File |
---|
925714_v1_control_incubation_data_during_calcification_experiments.csv (Comma Separated Values (.csv), 15.00 KB) MD5:7dbd28d27f7056792422fd2138f1bacc Primary data file for dataset ID 925714, version 1 |
Parameter | Description | Units |
species | Mussel species used in incubation. | units |
AphiaID | Unique identifier for the listed taxon in the Aphia database. | unitless |
LSID | Life Science Identifier (LSID) for the listed taxon. | unitless |
module | Experimental module corresponding to different mussel collection events. | unitless |
date_local | Incubation date in Pacific Standard Time. | unitless |
start_time_local | Start time of the incubation in Pacific Standard Time. | unitless |
ISO_start_DateTime_UTC | Start time of the incubation in UTC. | unitless |
duration | Duration of incubation in hours. | hours (h) |
salinity | Incubation Salinity. | PSU |
temperature | Incubation Temperature. | degrees Celcius (c) |
TA | Mean alkalinity during incubation. | umol kg-1 |
ph | Mean pH during incubation, total scale. | unitless |
hco3 | Mean bicarbonate ion concentration during incubation. | umol kg-1 |
co3 | Mean carbonate ion concentration during incubation. | umol kg-1 |
omega | Mean aragonite saturation state during incubation, corrected for calcium concentration where calcium was modified. | unitless |
pco2 | Mean partial pressure of carbon dioxide during incubation. | uatm |
dic | Mean dissolved inorganic carbon concentration, [CO2] + [HCO3-] + [CO32-], during the incubation. | umol kg-1 |
do | Mean dissolved oxygen concentration during the incubation. | umol kg-1 |
incubation_water_mass | Mass of seawater in incubation vessel. | kilograms (kg) |
delta_ta | Measured change in alkalinity during incubation. | umol kg-1 |
delta_nh3 | Measured change in ammonia concentration during incubation. | umol kg-1 |
NSF Award Abstract:
This research is exploring the capacity of coastal organisms to cope with alterations in seawater chemistry driven by both freshwater inputs and absorption of carbon dioxide into the world's oceans (ocean acidification). The project focuses on calcification responses and behavioral impairments of shoreline animals under altered seawater chemistry, and forefronts a common mussel species (the California mussel), and a common snail (the black turban snail), each abundant on rocky shores along the west coast of North America. The target species operate as exemplar organisms for characterizing the responses of marine invertebrates more generally. Methods involve experimental decoupling of multiple components of the carbonate system of seawater to isolate drivers that are difficult to separate otherwise. Broader impacts include transfer of scientific information to policy-makers, including legislators, as well as training and skill-set development of future generations of scientists and citizens. One Ph.D. student is supported, as are UC Davis undergraduates conducting mentored research. The project also provides research internships for undergraduates from a local community college (Santa Rosa Junior College), many of whom are from underrepresented groups. The latter project component substantially bolsters an ongoing program at Bodega Marine Laboratory that includes efforts in diversity, equity, and inclusion. Data and interpretations from the project are feeding into an existing educational program that links to local K-12 schools and reaches ~10,000 members of the public each year.
Overall, the research of the project is dissecting drivers of calcification and behavioral disruption in key shoreline invertebrates, across present-day and future carbonate system conditions appropriate to coastal marine environments. Efforts are exploring the extent to which calcification depends on one versus multiple parameters of the seawater carbonate system. In particular, existing conceptual models emphasize the importance of calcium carbonate saturation state (Ω) and/or the ratio of bicarbonate to hydrogen ion concentrations ([HCO3-]/[H+]), and the project is examining these mechanisms as well as the possibility that more than one driver acts simultaneously. It is doing so both in bivalves and in gastropods to test for generality across mollusks. The project is additionally examining whether pH is the only carbonate system factor contributing to known patterns of behavioral impairment in marine invertebrates. Leading explanations for debilitating behaviors induced by ocean acidification involve altered ion channel function, but discussion in the literature continues, and studies that explicitly decouple the carbonate system are necessary.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Funding Source | Award |
---|---|
NSF Division of Ocean Sciences (NSF OCE) |