Sensing the electrical properties of roots: A review

Ehosioke, Solomon; Nguyen, Frédéric; Rao, Sathyanarayan; Kremer, Thomas; Placencia‐Gomez, Edmundo; Huisman, Johan Alexander; Kemna, Andreas; Javaux, Mathieu; Garré, Sarah

doi:10.1002/vzj2.20082

Cited by 40 publications

(35 citation statements)

References 171 publications

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“…In a synthetic study, Rao et al (2019) evaluated how geometrical anisotropy of root networks impact the effective conductivity of the rhizosphere (the zone near the root). As petrophysical model uncertainty can be influenced by the presence of a root system, a better knowledge of root electrical properties would help define the formulation of a mixed root soil ER in order to refine the petrophysical relationships (Ehosioke et al, 2020).…”

Section: Formulating a Soil/root Electrical Conductivity Model And The Petrophysical Relationshipmentioning

confidence: 99%

Combining Models of Root-Zone Hydrology and Geoelectrical Measurements: Recent Advances and Future Prospects

et al. 2021

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Recent advances in measuring and modeling root water uptake along with refined electrical petrophysical models may help fill the existing gap in hydrological root model parametrization. In this paper, we discuss the choices to be made to combine root-zone hydrology and geoelectrical data with the aim of characterizing the active root zone. For each model and observation type we discuss sources of uncertainty and how they are commonly addressed in a stochastic inversion framework. We point out different degrees of integration in the existing hydrogeophysical approaches to parametrize models of root-zone hydrology. This paper aims at giving emphasis to stochastic approaches, in particular to Data Assimilation (DA) schemes, that are generally identified as the best way to combine geoelectrical data with Root Water Uptake (RWU) models. In addition, the study points out a more suitable objective function taken from the optimal transport theory that better captures complex geometry of root systems. Another pathway for improvement of geoelectrical data integration into RWU models using DA relies on the use of stem based methods as a leverage to introduce more extensive root knowledge into RWU macroscopic hydrological models.

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Section: Formulating a Soil/root Electrical Conductivity Model And The Petrophysical Relationshipmentioning

confidence: 99%

Combining Models of Root-Zone Hydrology and Geoelectrical Measurements: Recent Advances and Future Prospects

et al. 2021

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“…In contrast, progressive root cutting and root immersion experiments in hydroponically grown plants supported that C R is highly influenced by the roots located in the media [11]. There is a consensus that the current pathway inside the plant organs is influenced by tissue properties, e.g., suberization [4,6,12,13]. Therefore, one advantage of the capacitance method is that C R is a reflection of root size and physiological status, i.e., water content, membrane integrity and permeability, and endodermal maturation, driven by ontogenic changes and environmental (stress) factors [13].…”

Section: Introductionmentioning

confidence: 98%

“…Owing to methodological difficulties in assessing the growth and activity of intact root systems in the soil [1,2], the application and development of indirect, non-destructive techniques, including electrical methods, have received increasing attention in recent years [3,4].…”

Section: Introductionmentioning

confidence: 99%

Electrical Capacitance versus Minirhizotron Technique: A Study of Root Dynamics in Wheat–Pea Intercrops

Cseresnyés

Kelemen

Takács

et al. 2021

Plants

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This study evaluated the concurrent application and the results of the root electrical capacitance (CR) and minirhizotron (MR) methods in the same plant populations. The container experiment involved three winter wheat cultivars, grown as sole crops or intercropped with winter pea under well-watered or drought-stressed conditions. The wheat root activity (characterized by CR) and the MR-based root length (RL) and root surface area (RSA) were monitored during the vegetation period, the flag leaf chlorophyll content was measured at flowering, and the wheat shoot dry mass (SDM) and grain yield (GY) were determined at maturity. CR, RL and RSA exhibited similar seasonal patterns with peaks around the flowering. The presence of pea reduced the maximum CR, RL and RSA. Drought significantly decreased CR, but increased the MR-based root size. Both intercropping and drought reduced wheat chlorophyll content, SDM and GY. The relative decrease caused by pea or drought in the maximum CR was proportional to the rate of change in SDM or GY. Significant linear correlations (R2: 0.77–0.97) were found between CR and RSA, with significantly smaller specific root capacitance (per unit RSA) for the drought-stress treatments. CR measurements tend to predict root function and the accompanying effect on above-ground production and grain yield. The parallel application of the two in situ methods improves the evaluation of root dynamics and plant responses.

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“…Non-invasive geophysical techniques to study the root system and soil profile have substantially advanced in recent years (Ehosioke et al 2020). Only a few techniques can actually retrieve direct information on the root system architecture (e.g.…”

Section: Introductionmentioning

confidence: 99%