The sound of restored soil: using ecoacoustics to measure soil biodiversity in a temperate forest restoration context

Robinson, Jake M.; Breed, Martin F.; Abrahams, Carlos

doi:10.1111/rec.13934

Cited by 11 publications

(3 citation statements)

References 77 publications

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“…Automated insect bioacoustics models have enabled critical research across broad spatial and temporal scales, including the assessment of temperate forest restoration effects on soil biodiversity (Robinson et al., 2023), community science efforts to detect endangered cicadas by their mating calls (Hill et al., 2018), the early detection of stored grain pests in crop repositories or wood boring pests in urban, wild and cultivated trees (Bedoya et al., 2022; Hagstrum et al., 1996; Rigakis et al., 2021), and effective surveillance of 20 host‐seeking mosquito species based on wingbeat frequencies (Mukundarajan et al., 2017; Sinka et al., 2021), among many others (Table 1).…”

Section: Resultsmentioning

confidence: 99%

From buzzes to bytes: A systematic review of automated bioacoustics models used to detect, classify and monitor insects

Kohlberg,

Myers,

Figueroa

2024

Journal of Applied Ecology

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Insects play vital ecological roles; many provide essential ecosystem services while others are economically devastating pests and disease vectors. Concerns over insect population declines and expansion have generated a pressing need to effectively monitor insects across broad spatial and temporal scales. A promising approach is bioacoustics, which uses sound to study ecological communities. Despite recent increases in machine learning technologies, the status of emerging automated bioacoustics methods for monitoring insects is not well known, limiting potential applications. To address this gap, we systematically review the effectiveness of automated bioacoustics models over the past four decades, analysing 176 studies that met our inclusion criteria. We describe their strengths and limitations compared to traditional methods and propose productive avenues forward. We found automated bioacoustics models for 302 insect species distributed across nine Orders. Studies used intentional calls (e.g. grasshopper stridulation), by‐products of flight (e.g. bee wingbeats) and indirectly produced sounds (e.g. grain movement) for identification. Pests were the most common study focus, driven largely by weevils and borers moving in dried food and wood. All disease vector studies focused on mosquitoes. A quarter of the studies compared multiple insect families. Our review illustrates that machine learning, and deep learning in particular, are becoming the gold standard for bioacoustics automated modelling approaches. We identified models that could classify hundreds of insect species with over 90% accuracy. Bioacoustics models can be useful for reducing lethal sampling, monitoring phenological patterns within and across days and working in locations or conditions where traditional methods are less effective (e.g. shady, shrubby or remote areas). However, it is important to note that not all insect taxa emit easily detectable sounds, and that sound pollution may impede effective recordings in some environmental contexts. Synthesis and applications: Automated bioacoustics methods can be a useful tool for monitoring insects and addressing pressing ecological and societal questions. Successful applications include assessing insect biodiversity, distribution and behaviour, as well as evaluating the effectiveness of restoration and pest control efforts. We recommend collaborations among ecologists and machine learning experts to increase model use by researchers and practitioners.

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Section: Resultsmentioning

confidence: 99%

From buzzes to bytes: A systematic review of automated bioacoustics models used to detect, classify and monitor insects

Kohlberg,

Myers,

Figueroa

2024

Journal of Applied Ecology

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“…Sound is a critical component of ecosystems, and we can detect acoustic properties to monitor the restoration of soil biodiversity (Robinson et al 2023). However, the application of acoustic properties in a targeted way to alter and potentially enhance soil restoration processes remains unexplored.…”

Section: Discussionmentioning

confidence: 99%

“…Ecological acoustic surveys or 'ecoacoustics' have proven successful at monitoring soil biodiversity (Maeder et al 2022), which is a vital but challenging-to-monitor ecosystem component. Recently, Robinson et al (2023) demonstrated that it is possible to record soniferous species below-ground using piezoelectric microphones and audio recording devices in a restoration context. The authors built acoustic indices of audible soil diversity, complexity and normalised differential signals that reflected the recovery of soil biodiversity in a temperate forest context.…”

Section: Introductionmentioning

confidence: 99%

Sonic restoration: Acoustic stimulation enhances soil fungal biomass and activity of plant growth-promoting fungi

Robinson,

Cando-Dumancela,

Breed

2024

Preprint

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Ecosystem restoration interventions often utilise visible elements to restore an ecosystem (e.g., replanting native plant communities and reintroducing lost species). However, using acoustic stimulation to restore ecosystems has received little attention. Our study aimed to (a) investigate the potential effects of acoustic stimulation on fungal biomass and organic matter decomposition, which are both crucial components of ecosystem functioning and (b) assess the effect of acoustic stimulation on the growth rate and sporulation of the plant growth-promoting fungus Trichoderma harzianum. We played 70 dB and 90 dB soundscape treatments (@ 8 kHz) to green and rooibos teabags in compost in experimental mesocosms for 8 hours per day for 14 days to test whether acoustic stimulation affected fungal biomass and organic matter decomposition (a control mesocosm received only ambient sound stimulation <30 dB). We played a monotone soundscape (80 dB @ 8 kHz) over five days to Trichoderma harzianum to assess whether this stimulation affected the growth rate and sporulation of this fungus (control samples received only ambient sound stimulation <30 dB). We show that the acoustic stimulation treatments resulted in increased fungal biomass, greater decomposition, and enhanced T. harzianum conidia (spore) activity compared to controls. These results indicate that acoustic stimulation influences soil fungal growth and potentially facilitates their functioning. A piezoelectric effect and/or fungal mechanoreceptor stimulation are possible mechanisms. Our study highlights the potential of acoustic stimulation to alter important functional soil components, which could, with further development, be harnessed to aid ecosystem restoration.

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An Exploration of Ecoacoustics and its Applications in Conservation Ecology

Farina,

Krause,

Mullet

2024

BioSystems

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The sound of restored soil: using ecoacoustics to measure soil biodiversity in a temperate forest restoration context

Cited by 11 publications

References 77 publications

From buzzes to bytes: A systematic review of automated bioacoustics models used to detect, classify and monitor insects

From buzzes to bytes: A systematic review of automated bioacoustics models used to detect, classify and monitor insects

Sonic restoration: Acoustic stimulation enhances soil fungal biomass and activity of plant growth-promoting fungi

An Exploration of Ecoacoustics and its Applications in Conservation Ecology

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