AI Article Synopsis
- Researchers have been using stable hydrogen (H) and carbon (C) isotopes in bird feathers to track migration patterns, but stable sulfur (S) isotopes are less understood.
- This study analyzed feather S values from 13 bird species in India, including marine, resident, and a single migratory bird, the Bar-headed Goose.
- Marine birds had significantly higher S values compared to terrestrial resident species, with patterns differing notably in the Himalayan region and Gangetic plain, highlighting the potential of S isotopes in studying bird migration.
Article Abstract
Although stable hydrogen (H) and carbon (C) isotopic compositions of bird feathers have been increasingly used to understand the migration of birds through assignment of individuals to established isoscapes, far less is known about the structure of feather isoscapes based on stable sulphur isotope (S) assays. While H isoscapes have been used to investigate the migratory origins of the Globe Skimmer () dragonfly in India, no isotope studies have been applied to avian migration patterns in that region. Here, based on museum collections, we report the feather S values of 13 avian species that included marine birds with expected S enriched feathers, resident birds throughout India and a single migratory species, Bar-headed Goose (). Feathers from the marine birds were the most enriched (20.6 ± 1.2 ‰, = 10; range = 4.4 ‰) in S but terrestrial resident species also showed unexpectedly high S values (11.7 ± 4.8 ‰, = 74; range = 19.9 ‰) throughout most of India but the Himalayan region and Gangetic plain typically showed S values less than 6.4 ‰. Our results show the utility of feather S studies to decipher avian and other animal migration between these two regions.
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| http://dx.doi.org/10.1080/10256016.2022.2113995 | DOI Listing |
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