Outdoor mesoscale fabricated ecosystems: Rationale, design, and application to evapotranspiration

L. Peruzzo, C. Chou, S. S. Hubbard, E. Brodie, S. Uhlemann, B. Dafflon, S. Wielandt, B. Mary, G. Cassiani, A. Morales, Y. Wu

Research output: Contribution to journalArticlepeer-review

Abstract

The disparity in scale, complexity, and control level between laboratory experiments and field observational studies has shaped both the methodologies employed and the nature of the research questions pursued in ecology and hydrology. While lysimeters and fabricated ecosystems suitably fit in this gap, their use as mesoscale experimental facilities has not been fully explored because of the limited manipulating capabilities and integration with imaging and monitoring methods, particularly for soil functioning. The proposed fabricated ecosystem (4.7 L × 1.2 W × 1.2 H m) focuses on the spatiotemporal integration of point sensors and imaging methods along the soil-plant-atmosphere continuum. Because energy and water fluxes are key environmental drivers, the designed setup was first applied to a multi-approach evapotranspiration investigation. Below the ground, electrical resistivity tomography (ERT) was combined with soil water sensors and a distributed temperature profiling system. Together, they provided the 3D monitoring of water and temperature changes, and thus an estimation of the evapotranspiration, as well as the interpretation of its below-ground controlling processes. Above-ground sensors supported a classical energy balance investigation that was compared with the lysimeter load changes and the ERT-based ET estimation. Our results provide first experimental evidence of water and temperature spatiotemporal variability at the lysimeter scale, and thus explain the discrepancies among the three estimated evapotranspiration time series and their seasonality. Beyond evapotranspiration, the multi-approach investigation of water and energy fluxes emphasizes how mesoscale setups can further support the development and upscaling of methods and models, as well as their integration and application under expected climate disturbances.

Original languageEnglish
Article number177565
JournalScience of the Total Environment
Volume957
DOIs
StatePublished - Dec 20 2024

Funding

We acknowledge the support of the Advanced Research Projects Agency - Energy, Rhizosphere Observations Optimizing Terrestrial Sequestration (ARPA-E ROOTS). We also acknowledge the Watershed Function Scientific Focus Area funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under award number DE-AC02-05CH11231. Luca Peruzzo and Giorgio Cassiani acknowledge the financial support of the RETURN (multi-risk science for resilient communities under changing climate) project of the Italian PNRR (Piano Nazionale Ripresa e Resilienza). We are very thankful to Paul Cook and Todd J. Wood for their technical support. Luca Peruzzo thanks Irene Tonelato for illustrating the graphical abstract. We thank the three anonymous reviewers and the Associate Editor Professor Zhaozhong Feng.

FundersFunder number
Piano Nazionale Ripresa e Resilienza
Advanced Research Projects Agency - Energy
U.S. Department of Energy
Office of Science
Rhizosphere Observations Optimizing Terrestrial Sequestration
Biological and Environmental ResearchDE-AC02-05CH11231
Biological and Environmental Research

    Keywords

    • Electrical resistivity tomography
    • Evapotranspiration
    • Fabricated ecosystems
    • Lysimeter
    • Soil water content
    • Temperature

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