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The "Little MonSta" Deep-Sea Benthic, Precision Deployable, Multi-Sensor and Sampling Lander Array.

Andrew J Wheeler1,2,3, Aaron Lim1,4, Felix Butschek1,3

  • 1School of Biological, Earth & Environmental Sciences/Environmental Research Institute, Distillery Fields, North Mall Campus, University College Cork, Cork, Ireland.

Sensors (Basel, Switzerland)
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Summary
This summary is machine-generated.

The Little MonSta lander array monitors ocean changes using ROV-deployable platforms. This system collects crucial data on currents, temperature, and particles in deep-sea habitats.

Keywords:
ADCPbenthic landercold-water coralseabed monitoringsediment trapsubmarine canyon

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Area of Science:

  • Oceanography
  • Benthic Ecology
  • Environmental Monitoring

Background:

  • Cold-water coral habitats are under pressure from climate change.
  • Meso-scale benthic processes require continuous monitoring.
  • Geological archives need calibration with in-situ data.

Purpose of the Study:

  • To introduce the Little MonSta benthic lander array for monitoring oceanographic properties.
  • To assess the system's capability in extreme terrains and heterogeneous environments.
  • To provide data for understanding climate-driven oceanic change and benthic processes.

Main Methods:

  • Deployment of 8 ROV-deployable Little MonSta lander platforms.
  • Equipping landers with ADCPs, sediment traps, settlement plates, and homing beacons.
  • Conducting a proof-of-concept study in the Porcupine Bank Canyon.

Main Results:

  • Collected 868.8 hours of physical and chemical oceanographic data.
  • Acquired 192 particle samples for analysis of POC, sediment, foraminifera, and microplastics.
  • Demonstrated precise deployment in extreme terrains up to 3000 m depth.

Conclusions:

  • The Little MonSta array offers a flexible solution for monitoring marine benthic environments.
  • The system effectively collects data for understanding climate impacts and benthic processes.
  • Potential for upgrades enhances operational capabilities for future research.