Non-native species change the tune of tundra soils : novel access to soundscapes of the Arctic earthworm invasion

Over the last decade, an increasing number of studies have used soundscapes to address diverse ecological questions. Sound represents one of the few sources of information capable of providing in situ insights into processes occurring within opaque soil matrices. To date, the use of soundscapes for...

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Bibliographic Details
Published in:Science of The Total Environment
Main Authors: Keen, Sara C., Wackett, Adrian A., Willenbring, Jane K., Yoo, Kyungsoo, Jonsson, Hanna, Clow, Travis, Klaminder, Jonatan
Format: Article in Journal/Newspaper
Language:English
Published: Umeå universitet, Institutionen för ekologi, miljö och geovetenskap 2022
Subjects:
Acoustic monitoring
Arctic
Earthworm invasion
Ecosystem disturbance
Ecosystem engineer
Soil fauna
Soil organic carbon
Soil structure
Soundscapes
Ecology
Ekologi
Soil Science
Markvetenskap
Northern Sweden
Tundra
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-196820
https://doi.org/10.1016/j.scitotenv.2022.155976
Description
Summary:Over the last decade, an increasing number of studies have used soundscapes to address diverse ecological questions. Sound represents one of the few sources of information capable of providing in situ insights into processes occurring within opaque soil matrices. To date, the use of soundscapes for soil macrofauna monitoring has been experimentally tested only in controlled laboratory environments. Here we assess the validity of laboratory predictions and explore the use of soil soundscape proxies for monitoring soil macrofauna (i.e., earthworm) activities in an outdoor context. In a common garden experiment in northern Sweden, we constructed outdoor mesocosm plots (N = 36) containing two different Arctic vegetation types (meadow and heath) and introduced earthworms to half of these plots. Earthworms substantially altered the ambient soil soundscape under both vegetation types, as measured by both traditional soundscape indices and frequency band power levels, although their acoustic impacts were expressed differently in heath versus meadow soils. While these findings support the as-of-yet untapped promise of using belowground soundscape analyses to monitor soil ecosystem health, direct acoustic emissions from earthworm activities appear to be an unlikely proxy for tracking worm activities at daily timescales. Instead, earthworms indirectly altered the soil soundscape by ‘re-engineering’ the soil matrix: an effect that was dependent on vegetation type. Our findings suggest that long-term (i.e., seasonal) earthworm activities in natural soil settings can likely be monitored indirectly via their impacts on soundscape measures and acoustic indices. Analyzing soil soundscapes may enable larger-scale monitoring of high-latitude soils and is directly applicable to the specific case of earthworm invasions within Arctic soils, which has recently been identified as a potential threat to the resilience of high-latitude ecosystems. Soil soundscapes could also offer a novel means to monitor soils and soil-plant-faunal ...

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