https://doi.org/10.5061/dryad.8pk0p2nwk

File: File_1-6_in_Uematsu_et_al..zip

Here, you can access all the data used in this study.

To measure the intra- and interspecific competition coefficients of Diacamma cf. indicum in the field, we examined the relationship between the intra-colony demography of Diacamma and the local ant community structure using the following methods.

Intact colonies of Diacamma were collected using the bamboo-traps. After carefully examining their colony composition (number of workers, brood weight, etc.), all workers were individually marked, and the colonies (nested in traps) were released intact at random locations in the study site. After one week, those colonies were recaptured, and any changes in colony composition were examined. In addition, local ant communities within a 5-m radius of the release point (the usual foraging distance of Diacamma workers) were examined by pitfall trapping and visual observation.

The data were collected in Excel files and analyzed with R scripts.

Description of the data and file structure

The data consist of the following six Excel files and one PDF file (for Zenodo).

File 1. Worker survival of Diacamma in relation to the local ant communities.

Each row indicates the data for each individual worker.

Column A indicates the ID of the focal worker.

Column B indicates the colony to which each worker belongs.

Column C: colony size: W1 indicates the number of workers in the focal colony before release into the field.

Columns D and E indicate the year and month of the experiment.

Column F indicates the presence or absence (death) of the focal individual.

Column G indicates the local density of Diacamma colony at the release site of the focal colony.

Columns H to O indicate the local density of each ant species at the release location (within a 5-m radius of the release point) of the focal colony (Each species density is calculated by multiplying the number of individuals of each species collected in pitfall traps by the mean per worker fresh weight of each species. See File 5).

File 2. Colony demographic parameters of Diacamma (brood production, colony growth and etc.) in relation to the local ant communities.

Each row indicates the data for each colony.

Column A indicates the ID of the focal colony.

Column B indicates the month of the experiment.

Column C: W2 indicates the number of marked workers after recapture (workers that emerged after release were not included).

Column D: W3 indicates the total number of workers after recapture (including workers that emerged after release).

Column E: B1 indicates the total brood weight (the sum of fresh weight of eggs and larvae; we excluded cocoons from B1 because they are destined to emerge) before release.

Column F: B2 indicates the total brood weight after recapture (the sum of the fresh weights of eggs, larvae, and cocoons; we included newly pupated cocoons here, because they reflect larval growth).

Column G: B3 indicates the total brood weight before release (the sum of eggs, larvae, and cocoons).

Column H: B4 indicates the total brood weight after recapture (the sum of eggs, larvae, and all cocoons).

Column I indicates the brood production (B2 - B1) of the focal colony.

Column J indicates the absolute colony growth, where M in the formula means the average fresh weight of an individual adult of the focal colony.

Column K indicates the net colony growth per worker.

Column L: colony size: W1 indicates the number of workers in the focal colony before release into the field.

Column M indicates the local density of Diacamma colony at the release location (within a 5-m radius of the release point) of the focal colony.

Columns N to AB indicate the local density of each ant species at the release location of the focal colony (Each species density is calculated by multiplying the number of individuals of each species collected in pitfall traps by the mean per worker fresh weight of each species. See File 5).

File 3. Results of the stable Carbon isotope analysis of seven dominant ants in the study site.

Columns indicate ant species and rows indicate colony-based data in each species. Measurements are reported in delta notation (δ): δ13C = [(Rsample/Rstandard) − 1] ∙ 1000, where R is the ratio of the heavy/light isotope content (13C/12C). Isotope ratios are expressed in per mil (‰) relative to international reference standards VPDB (Vienna PeeDee Belemnite) for carbon.

File 4. Results of the stable Nitrogen isotope analysis of seven dominant ants in the study site.

Columns indicate ant species and rows indicate colony-based data in each species. Measurements are reported in delta notation (δ): δ15N = [(Rsample/Rstandard) − 1] ∙ 1000, where R is the ratio of the heavy/light isotope content (15N/14N). Isotope ratios are expressed in per mil (‰) relative to international reference standards VPDB (Vienna PeeDee Belemnite) for atmospheric nitrogen for nitrogen.

File 5. Mean per worker wet weight of the seven dominant ant species in the study site. 

Column A indicates an ant species.

Column B indicates the average fresh weight for each species. 20 workers per species were collected from two to four colonies. They were weighed to the nearest 0.001 mg, and the average wet weight was calculated.

File 6. The number of individuals of each ant species collected in pitfall traps in each capture-release-recapture trial.

Column A indicates an ant species.

Columns B to Y indicate the number of individuals of each ant species collected in pitfall traps for each experiment (N=24).

File 7. Mathematical model of population dynamics.

We found that the worker mortality of Diacamma cf. indicum ants increased as the local density of conspecific colonies increased. We analyzed the effect of this density-dependent mortality on species coexistence using this Mathematica code (for Zenodo).