Impact of root hairs on microscale soil physical properties in the field

Paul Hallett; Maria Marin; Debbie S. Feeney; L .K. Brown; Muhammad Naveed; Nicolai Koebernick; C.S. Ruiz; Anthony G Bengough; T. Roose; T.S.  George

doi:10.1007/s11104-022-05530-1

Impact of root hairs on microscale soil physical properties in the field

Paul Hallett^* (Corresponding Author), Maria Marin, Debbie S. Feeney, L .K. Brown, Muhammad Naveed, Nicolai Koebernick, C.S. Ruiz, Anthony G Bengough, T. Roose, T.S. George

^*Corresponding author for this work

Aberdeen Centre For Environmental Sustainability

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

3 Downloads (Pure)

Abstract

Aims: Recent laboratory studies revealed that root hairs may alter soil physical behaviour, influencing soil porosity and water retention on the small scale. However, the results are not consistent, and it is not known if structural changes at the small-scale have impacts at larger scales. Therefore, we evaluated the potential effects of root hairs on soil hydro-mechanical properties in the field using rhizosphere-scale physical measurements. Methods: Changes in soil water retention properties as well as mechanical and hydraulic characteristics were monitored in both silt loam and sandy loam soils. Measurements were taken from plant establishment to harvesting in field trials, comparing three barley genotypes representing distinct phenotypic categories in relation to root hair length. Soil hardness and elasticity were measured using a 3-mm-diameter spherical indenter, while water sorptivity and repellency were measured using a miniaturized infiltrometer with a 0.4-mm tip radius. Results: Over the growing season, plants induced changes in the soil water retention properties, with the plant available water increasing by 21%. Both soil hardness (P = 0.031) and elasticity (P = 0.048) decreased significantly in the presence of root hairs in silt loam soil, by 50% and 36%, respectively. Root hairs also led to significantly smaller water repellency (P = 0.007) in sandy loam soil vegetated with the hairy genotype (-49%) compared to the hairless mutant. Conclusions: Breeding of cash crops for improved soil conditions could be achieved by selecting root phenotypes that ameliorate soil physical properties and therefore contribute to increased soil health.

Original language	English
Pages (from-to)	491-509
Number of pages	19
Journal	Plant and Soil
Volume	476
Early online date	11 Jun 2022
DOIs	https://doi.org/10.1007/s11104-022-05530-1
Publication status	Published - 1 Jul 2022

Bibliographical note

Aberdeen University and James Hutton staff were funded by BBSRC BB/J00868/1 and Dundee University staff by BBSRC BB/L025825/1. Contributions by Southampton university were funded by BBSRC SARISA BB/L025620/1 and ERCDMR-646809. The James Hutton Institute receives financial support from the Rural & Environment Science & Analytical Services Division of the Scottish Government. We are thankful to Mr Richard Keith, Mr Christopher Warden and the field staff of The James Hutton Institute for setting up, managing and maintaining the field trials.

Data Availability Statement

Supplementary Information
The online version contains supplementary material available at https://doi.org/10.1007/s11104-022-05530-1.

Keywords

Barley
Root hairs
Soil health
Soil hydromechanical properties
Soil structure
Soil water retention

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Cite this

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title = "Impact of root hairs on microscale soil physical properties in the field",

abstract = "Aims: Recent laboratory studies revealed that root hairs may alter soil physical behaviour, influencing soil porosity and water retention on the small scale. However, the results are not consistent, and it is not known if structural changes at the small-scale have impacts at larger scales. Therefore, we evaluated the potential effects of root hairs on soil hydro-mechanical properties in the field using rhizosphere-scale physical measurements. Methods: Changes in soil water retention properties as well as mechanical and hydraulic characteristics were monitored in both silt loam and sandy loam soils. Measurements were taken from plant establishment to harvesting in field trials, comparing three barley genotypes representing distinct phenotypic categories in relation to root hair length. Soil hardness and elasticity were measured using a 3-mm-diameter spherical indenter, while water sorptivity and repellency were measured using a miniaturized infiltrometer with a 0.4-mm tip radius. Results: Over the growing season, plants induced changes in the soil water retention properties, with the plant available water increasing by 21%. Both soil hardness (P = 0.031) and elasticity (P = 0.048) decreased significantly in the presence of root hairs in silt loam soil, by 50% and 36%, respectively. Root hairs also led to significantly smaller water repellency (P = 0.007) in sandy loam soil vegetated with the hairy genotype (-49%) compared to the hairless mutant. Conclusions: Breeding of cash crops for improved soil conditions could be achieved by selecting root phenotypes that ameliorate soil physical properties and therefore contribute to increased soil health.",

keywords = "Barley, Root hairs, Soil health, Soil hydromechanical properties, Soil structure, Soil water retention",

author = "Paul Hallett and Maria Marin and Feeney, {Debbie S.} and Brown, {L .K.} and Muhammad Naveed and Nicolai Koebernick and C.S. Ruiz and Bengough, {Anthony G} and T. Roose and T.S. George",

note = "Aberdeen University and James Hutton staff were funded by BBSRC BB/J00868/1 and Dundee University staff by BBSRC BB/L025825/1. Contributions by Southampton university were funded by BBSRC SARISA BB/L025620/1 and ERCDMR-646809. The James Hutton Institute receives financial support from the Rural & Environment Science & Analytical Services Division of the Scottish Government. We are thankful to Mr Richard Keith, Mr Christopher Warden and the field staff of The James Hutton Institute for setting up, managing and maintaining the field trials.",

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doi = "10.1007/s11104-022-05530-1",

language = "English",

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T1 - Impact of root hairs on microscale soil physical properties in the field

AU - Hallett, Paul

AU - Marin, Maria

AU - Feeney, Debbie S.

AU - Brown, L .K.

AU - Naveed, Muhammad

AU - Koebernick, Nicolai

AU - Ruiz, C.S.

AU - Bengough, Anthony G

AU - Roose, T.

AU - George, T.S.

N1 - Aberdeen University and James Hutton staff were funded by BBSRC BB/J00868/1 and Dundee University staff by BBSRC BB/L025825/1. Contributions by Southampton university were funded by BBSRC SARISA BB/L025620/1 and ERCDMR-646809. The James Hutton Institute receives financial support from the Rural & Environment Science & Analytical Services Division of the Scottish Government. We are thankful to Mr Richard Keith, Mr Christopher Warden and the field staff of The James Hutton Institute for setting up, managing and maintaining the field trials.

PY - 2022/7/1

Y1 - 2022/7/1

N2 - Aims: Recent laboratory studies revealed that root hairs may alter soil physical behaviour, influencing soil porosity and water retention on the small scale. However, the results are not consistent, and it is not known if structural changes at the small-scale have impacts at larger scales. Therefore, we evaluated the potential effects of root hairs on soil hydro-mechanical properties in the field using rhizosphere-scale physical measurements. Methods: Changes in soil water retention properties as well as mechanical and hydraulic characteristics were monitored in both silt loam and sandy loam soils. Measurements were taken from plant establishment to harvesting in field trials, comparing three barley genotypes representing distinct phenotypic categories in relation to root hair length. Soil hardness and elasticity were measured using a 3-mm-diameter spherical indenter, while water sorptivity and repellency were measured using a miniaturized infiltrometer with a 0.4-mm tip radius. Results: Over the growing season, plants induced changes in the soil water retention properties, with the plant available water increasing by 21%. Both soil hardness (P = 0.031) and elasticity (P = 0.048) decreased significantly in the presence of root hairs in silt loam soil, by 50% and 36%, respectively. Root hairs also led to significantly smaller water repellency (P = 0.007) in sandy loam soil vegetated with the hairy genotype (-49%) compared to the hairless mutant. Conclusions: Breeding of cash crops for improved soil conditions could be achieved by selecting root phenotypes that ameliorate soil physical properties and therefore contribute to increased soil health.

AB - Aims: Recent laboratory studies revealed that root hairs may alter soil physical behaviour, influencing soil porosity and water retention on the small scale. However, the results are not consistent, and it is not known if structural changes at the small-scale have impacts at larger scales. Therefore, we evaluated the potential effects of root hairs on soil hydro-mechanical properties in the field using rhizosphere-scale physical measurements. Methods: Changes in soil water retention properties as well as mechanical and hydraulic characteristics were monitored in both silt loam and sandy loam soils. Measurements were taken from plant establishment to harvesting in field trials, comparing three barley genotypes representing distinct phenotypic categories in relation to root hair length. Soil hardness and elasticity were measured using a 3-mm-diameter spherical indenter, while water sorptivity and repellency were measured using a miniaturized infiltrometer with a 0.4-mm tip radius. Results: Over the growing season, plants induced changes in the soil water retention properties, with the plant available water increasing by 21%. Both soil hardness (P = 0.031) and elasticity (P = 0.048) decreased significantly in the presence of root hairs in silt loam soil, by 50% and 36%, respectively. Root hairs also led to significantly smaller water repellency (P = 0.007) in sandy loam soil vegetated with the hairy genotype (-49%) compared to the hairless mutant. Conclusions: Breeding of cash crops for improved soil conditions could be achieved by selecting root phenotypes that ameliorate soil physical properties and therefore contribute to increased soil health.

KW - Barley

KW - Root hairs

KW - Soil health

KW - Soil hydromechanical properties

KW - Soil structure

KW - Soil water retention

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SN - 0032-079X

VL - 476

SP - 491

EP - 509

JO - Plant and Soil

JF - Plant and Soil

ER -

Impact of root hairs on microscale soil physical properties in the field

Abstract

Bibliographical note

Data Availability Statement

Keywords

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