| Contributors | Affiliation | Role |
|---|---|---|
| Witman, Jon D. | Brown University | Principal Investigator |
| Lamb, Robert | Brown University | Scientist |
| Newman, Sawyer | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
The FID measurements were obtained by the following procedure conducted by an individual diver working at 10-15 m depth. 1) a target fish to measure the proximity that a diver could approach before the fish swam away (flight) was identified. 2) the diver dropped a small weight ion the bottom to mark the start of his approach. 3) the diver swam straight at the target fish noting theĀ bottom features where the fish first started to swim away 4) the diver dropped another weight at this location 5) the distance between the 2 weights was measured as FID with a meter tape. The body size (total length) was estimated of the target fish was recorded.
No sophisticated methods of data processing were noted by the author.
Units removed from column names
Spaces in column names replaced with underscores ("_")
| Parameter | Description | Units |
| Observation_ID | ID number for each observation in dataset | unitless |
| Site | Name of study site in central Galapagos | unitless |
| Date | Date that measurement of Flight Initiation Distance (FID) was made | unitless |
| Species_Name | Name of reef fish species measured for Flight Initiation Distance (FID) | unitless |
| Total_Body_Length | Total body length (cm) of fish measured for Flight Initiation Distance (FID) | centimeters (cm) |
| Distance_diver_was_from_start_point | Distance diver was from start point of the transect | meters (m) |
| Distance_to_fish_at_start_of_flight | Distance along transect when fish began to flee | meters (m) |
| Flight_Initiation_Distance | Distance between start point and start of fish flight | meters (m) |
Large-scale changes in the magnitude of human influence on the biosphere have occurred due to travel restrictions and quarantines to contain the COVID-19 pandemic. The reduction in the number of visits to natural areas is providing an unprecedented opportunity to study the effects of people on wildlife and ecosystems. Previous studies indicate that humans can impact the entire ecosystem by frightening animals and altering their behaviors. The COVID-19 quarantine has created a "natural experiment" in the ocean at scuba-diving destinations worldwide by suspending dive tourism and temporarily eliminating the effects of diver-induced fear in reef fish communities. In the Galapagos Islands, the number of scuba divers dropped from 18,000 divers a year to zero in March 2020 when the government of Ecuador halted dive tourism. This study is measuring the changes reef fish behavior, populations and ecological interactions between species to gain an understanding of how dive activity affects the functioning of this marine ecosystem. The effects of changes in diver disturbance are being determined by comparing reef fish communities during and after the quarantine to those from a long-term pre-COVID-19 baseline study. Broader impacts include training opportunities for undergraduate students through participation in field research and senior thesis projects. Public outreach is focused on presentations to the general public and high school students in the US and in the Galapagos. A YouTube video on the ecological effects of diving activity in the Galapagos Marine Reserve is being produced and made publicly available. Insights from this project is increasing awareness of how humans impact subtidal marine ecosystems, which is aiding marine conservation efforts of marine protected areas in the Galapagos and elsewhere.
The intellectual contribution of the research lies in its ability to test hypotheses about the role of humans in influencing consumptive and non-consumptive interactions in shaping the structure, complexity and functioning of marine ecosystems. While it is known that reef fish react to humans as potential predators, less is known about how the fear of predation, a major type of non-consumptive interaction, affects subtidal marine communities, particularly on large spatial scales relevant to conservation. An integrated, observational - experimental research program is addressing this knowledge gap in the Galapagos Marine Reserve by comparing current conditions with existing pre-COVID-19 data. Four hypotheses or predictions related to pandemic spillover effects are being tested: 1) diver disturbance results in behavioral shifts in reef fishes; 2) divers decrease the abundance and diversity of reef fishes and this effect is currently reduced; 3) emergence or increased abundance of previously wary herbivorous and /or predatory fish results in greater consumption of benthic organisms during and immediately after the COVID-19 period; and 4) decreased diver disturbance associated with the pandemic changes the complexity of behavioral networks (aggressive and positive interactions) among reef fish, sharks and sea lions. The hypotheses are being tested at 14 sites over the course of three research trips using underwater observations and experiments involving fish counts, video camera deployments to record fish behaviors, feeding rates, interactions between species and underwater boat noise from dive tour boats. This project has implications for understanding how fish communities in the Galapagos Marine Reserve ecosystem will respond to future perturbations, while also providing unique insight into the ecological ramifications of a human pandemic.
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) |