Hostname: page-component-89b8bd64d-mmrw7 Total loading time: 0 Render date: 2026-05-07T03:04:42.698Z Has data issue: false hasContentIssue false
  • English
  • Français

Modelling sugarcane root elongation in response to mechanical stress as an indicator of soil physical quality

Published online by Cambridge University Press:  20 February 2025

Luiz Henrique Quecine Grande Open the ORCID record for Luiz Henrique Quecine Grande [Opens in a new window] ,
John Kennedy dos Santos Open the ORCID record for John Kennedy dos Santos [Opens in a new window] ,
Matheus Batista Néri Pereira Open the ORCID record for Matheus Batista Néri Pereira [Opens in a new window] ,
Lucas Henrique Amaro da Silva Open the ORCID record for Lucas Henrique Amaro da Silva [Opens in a new window] ,
Larissa Fernanda Muniz Open the ORCID record for Larissa Fernanda Muniz [Opens in a new window] ,
Denizart Bolonhezi Open the ORCID record for Denizart Bolonhezi [Opens in a new window] ,
Renan Caldas Umburanas Open the ORCID record for Renan Caldas Umburanas [Opens in a new window]  and
Moacir Tuzzin de Moraes Open the ORCID record for Moacir Tuzzin de Moraes [Opens in a new window]
Luiz Henrique Quecine Grande*
Affiliation:
University of São Paulo, Luiz de Queiroz College of Agriculture (ESALQ/USP), Piracicaba, SP, Brazil University of São Paulo, Center for Carbon Research in Tropical Agriculture (CCARBON/USP), Piracicaba, SP, Brazil
John Kennedy dos Santos
Affiliation:
University of São Paulo, Luiz de Queiroz College of Agriculture (ESALQ/USP), Piracicaba, SP, Brazil
Matheus Batista Néri Pereira
Affiliation:
University of São Paulo, Luiz de Queiroz College of Agriculture (ESALQ/USP), Piracicaba, SP, Brazil
Lucas Henrique Amaro da Silva
Affiliation:
University of São Paulo, Luiz de Queiroz College of Agriculture (ESALQ/USP), Piracicaba, SP, Brazil
Larissa Fernanda Muniz
Affiliation:
University of São Paulo, Luiz de Queiroz College of Agriculture (ESALQ/USP), Piracicaba, SP, Brazil
Denizart Bolonhezi
Affiliation:
Sugarcane Research Center, Agronomic Institute of Campinas (IAC), Ribeirão Preto, SP, Brazil
Renan Caldas Umburanas
Affiliation:
University of São Paulo, Luiz de Queiroz College of Agriculture (ESALQ/USP), Piracicaba, SP, Brazil
Moacir Tuzzin de Moraes*
Affiliation:
University of São Paulo, Luiz de Queiroz College of Agriculture (ESALQ/USP), Piracicaba, SP, Brazil University of São Paulo, Center for Carbon Research in Tropical Agriculture (CCARBON/USP), Piracicaba, SP, Brazil
*
Corresponding authors: Moacir Tuzzin de Moraes and Luiz Henrique Quecine Grande; Emails: luizquecine@usp.br; moacir.tuzzin@usp.br
Corresponding authors: Moacir Tuzzin de Moraes and Luiz Henrique Quecine Grande; Emails: luizquecine@usp.br; moacir.tuzzin@usp.br
Rights & Permissions [Opens in a new window]

Summary

The root elongation rate represents a biophysical process that can be directly affected by mechanical, water, thermal, and gaseous stresses in the soil to be used as a soil physical quality indicator. The objective of this study was to determine sugarcane root growth parameters under soil physical stress for different root diameter classes in an Oxisol from the Southeast of Brazil. The experimental design was entirely randomized in a factorial scheme 5 × 2 (mechanical × water stress) with three replications. The factor mechanical stress was composed of five compaction levels (1.04; 1.12; 1.19; 1.28; 1.36 Mg m3). The factor water stress was composed of two matric potentials (–6 kPa and –33 kPa). Soil samples were collected from the 0.0–0.2 m layer of an Oxisol with a clayey texture. Pre-sprouted sugarcane seedlings were transplanted and conditioned in a growth chamber. Root length, volume, surface area, and diameter were quantified to generate root growth models as a function of physical stresses in the soil. Soil penetration resistance increases from 1.4 to 5 MPa reduced root elongation rate from 3.5 to 1.35 cm day–1 (–59%) and the average number of roots from 11 to 6 segments (–45%), respectively. The root volume, surface area, and length were reduced because of the increase in the compaction level. Coarse root diameter (1–2 mm) was weakly impacted by mechanical stress, whereas fine root diameter (0.5–1 mm) was more growth limited in compacted soils. The root elongation rate of sugarcane was modelled as a function of mechanical and water stress. Mechanical stress mainly affects the growth of sugarcane roots with small diameter.

Keywords

Saccharum sp.soil penetration resistanceroot growthbiophysical parameterization

Information

Type
Research Article
Information
Experimental Agriculture , Volume 61 , 2025 , e3
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press

Introduction

The soil compaction as a result of bulk density increases impairs soil structure and changes the pore spaces (Oliveira et al. Reference Oliveira, Souza, Bolonhezi and Oliveira2022), water dynamics (Rossetti & Centurion Reference Rossetti and Centurion2013), gas dynamics (Pandey & Bennett Reference Pandey and Bennett2024), and mechanical conditions for root growth (Pandey et al. Reference Pandey, Huang, Bhosale and Bennett2021) and, consequently, impairs sugarcane productivity (Esteban et al. Reference Esteban, de Souza, Tormena and de Paula Ribeiro2019). The main physical factors that affect root growth, disregarding chemical and biological components, are thermal, gaseous, water, and mechanical stresses (Letey Reference Letey and Stewart1985; Moraes & Gusmão Reference Moraes and Gusmão2021). Combined in a domain of time and space, these soil physical stresses determine the establishment and development of roots, which affect water and nutrients availability for plants (Cherubin et al. Reference Cherubin, Karlen, Franco and Cerri2016).

Root elongation is the biophysical mechanism that represents the soil–root interaction (Pagès et al. Reference Pagès, Serra, Draye, Doussan and Pierret2010), which can be used to root growth modelling (Moraes et al. Reference Moraes, Bengough, Debiasi and Leitner2018). Despite the biophysical process of root elongation (Frene et al. Reference Frene, Pandey and Castrillo2024; Pandey & Bennett Reference Pandey and Bennett2024) being at the frontier of knowledge (Tomobe et al. Reference Tomobe, Tsugawa, Yoshida and Sawa2023; Yu et al. Reference Yu, Li, Li and Hochholdinger2024b), only a few old studies have measured the root elongation responses to mechanical stress, for example, in soybean (Kaspar et al. Reference Kaspar, Taylor and Shibles1984; Manavalan et al. Reference Manavalan, Guttikonda, Nguyen, Shannon and Nguyen2010; Materechera et al. Reference Materechera, Dexter and Alston1991), maize (Iijima & Kato Reference Iijima and Kato2007; Mirreh & Ketcheson Reference Mirreh and Ketcheson1973; Veen & Boone Reference Veen and Boone1990), pea (Bengough et al. Reference Bengough, Mackenzie and Elangwe1994; Iijima & Kato Reference Iijima and Kato2007), peanuts (Taylor & Ratliff Reference Taylor and Ratliff1969), cotton (Iijima & Kato Reference Iijima and Kato2007; Taylor & Ratliff Reference Taylor and Ratliff1969), and rice (Iijima & Kato Reference Iijima and Kato2007). However, there is no data about the responses of sugarcane roots to soil physical (mechanical, water, air or heat stress) stress, which could be used in the mechanistic root growth models such as Rootbox, CrootBox (Schnepf et al. Reference Schnepf, Leitner, Landl and Vereecken2018b, Reference Schnepf, Huber, Landl, Meunier, Petrich and Schmidt2018a), or CPlantBox (Giraud et al. Reference Giraud, Gall, Harings and Schnepf2023; Zhou et al. Reference Zhou, Schnepf, Vanderborght and Lobet2020). In addition, the responses of root systems to compacted soil in the field are reproducible under controlled conditions (Colombi & Walter Reference Colombi and Walter2016; Giuliani et al. Reference Giuliani, Hallett and Loades2024), usually applied to the mechanistic models of root growth (Schnepf et al. Reference Schnepf, Carminati, Ahmed and Vetterlein2022), whose measure and parameterization of root data are scarce in the literature (Moraes et al. Reference Moraes, Debiasi, Franchini and Leitner2019; Reference Moraes, Debiasi, Franchini and Schnepf2020) and still are reason of call for collaboration in global context (Schnepf et al. Reference Schnepf, Black, Couvreur and Weber2020).

The root elongation rate is reduced by mechanical impedance (Colombi et al. Reference Colombi, Torres, Walter and Keller2018), which is accentuated when combined with water and gaseous stress (Moraes & Gusmão Reference Moraes and Gusmão2021). This root elongation process indicates the interaction between the soil and roots (Bengough Reference Bengough2012), which can be described by a process-based model that can be used to predict root system growth (Moraes et al. Reference Moraes, Bengough, Debiasi and Leitner2018). The process-based models, based on quantitative descriptions for understanding the relationships that govern soil–root biophysical interaction, are innovative (Moraes et al. Reference Moraes, Bengough, Debiasi and Leitner2018; Mulazzani et al. Reference Mulazzani, Gubiani, Zanon, Drescher, Schenato and Girardello2022) and still underexplored for modelling the root growth of sugarcane (Lovera et al. Reference Lovera, de Souza, Esteban and Panosso2021). The important step to create a biophysical root growth model is the parameterization, especially the water and mechanical stress on the root elongation rate. To this end, process-based models help identify which measurements need to be carried out in laboratory experiments with both preserved (Chapman et al. Reference Chapman, Miller, Lindsey and Whalley2012) and packed (Bai et al. Reference Bai, Ge, Ashton and Bartsch2019) soil structures for root growth modelling. The actual knowledge gap for sugarcane root growth modelling is due to the absence of data on root growth responses in the function of soil physical stresses.

Most field studies on the effect of soil physical restrictions on sugarcane root system (Saccharum spp.) have only quantified the total root length density (Lovera et al. Reference Lovera, de Souza, Esteban and Panosso2021) and root biomass in the soil profile (Esteban et al. Reference Esteban, de Souza, Tormena and de Paula Ribeiro2019 ; Cury et al. Reference Cury, De Maria and Bolonhezi2014), overlooking the processes and mechanisms of soil–root biophysical interaction during root elongation. Studies carried out in the laboratory using samples with reconstructed soil structure under a controlled environment (Bai et al. Reference Bai, Ge, Ashton and Bartsch2019) have contributed important information on the impact of mechanical stress on root growth (Huang et al. Reference Huang, Kilic, Karady and Pandey2022), especially for the understanding of the process (Kong et al. Reference Kong, Yu, Xiong and Huang2024) and mechanisms (Tomobe et al. Reference Tomobe, Tsugawa, Yoshida and Sawa2023; Pandey & Bennett Reference Pandey and Bennett2024) involved in the soil–root interaction. Most studies commonly disregard the effect of mechanical and water stress on root diameter classes (Giuliani et al. Reference Giuliani, Hallett and Loades2024; Kumi et al. Reference Kumi, Obour, Arthur and Adu2023), which can be distinguished by sensitivity to physical stresses in the soil (Materechera et al. Reference Materechera, Alston, Kirby and Dexter1992). Thus, the advances in root growth modelling depend on measurements of the root response as a function of mechanical and water stress, as these factors have been neglected in most agricultural crops (Seidel et al. Reference Seidel, Gaiser, Srivastava and Ewert2022). Furthermore, parameterizations based on the relationship between soil mechanical impedance, water stress, and sugarcane root elongation allow for the establishment of mechanistic models (Moraes et al. Reference Moraes, Bengough, Debiasi and Leitner2018) to predict root growth in field conditions using the architectural root growth models (Schnepf et al. Reference Schnepf, Leitner, Landl and Vereecken2018b). The aim was to determine sugarcane root growth parameters under soil physical stress for different root diameter classes in an Oxisol from the Southeast of Brazil.

Material and methods

Experimental design

The experiment design was based on a completely randomized design with a 5 × 2 factorial scheme (mechanical stress × water stress) and three replications. Pre-sprouted sugarcane seedlings were used, which were grown for 92 h in a growth chamber. The mechanical factor consisted of five compaction levels, quantified by the soil penetration resistance (MPa), and expressed by five bulk densities (1.04; 1.12; 1.19; 1.28; 1.36 Mg m–3). The water factor was expressed by two soil water matric potentials (–6 and –33 kPa), by means of hydrostatic equilibrium in Richards pressure chambers (Jacob et al. Reference Jacob, Dane and Clarke2017). The soil structure was reconstructed using PVC cylinders with a height of 15 cm and an internal diameter of 5 cm.

Soil unpreserved samples were collected at 0.0–0.2 m depth (Figure 1a) from an Oxisol (Soil Survey Staff 2022) with a clayey texture (510 g kg–1 clay, 330 g kg–1 sand, and 160 g kg–1 silt), located in Piracicaba, SP, Brazil (22°42’7.61”S, 47°37’54.60”W, 546 m a.s.l.). The soil samples were sieved with a mesh size of 2 mm, to ensure a homogeneous structure, and then stored in plastic bags (Figure 1b). To compress the soil in the PVC cylinders, soil water content was adjusted by adding water uniformly until it reached a friable consistency and corresponded to the optimum moisture for compaction (i.e. 0.32 kg–1), estimated by the pedotransfer function of Proctor test (Marcolin & Klein Reference Marcolin and Klein2011). Afterwards, the plastic bags containing the soil samples were sealed to redistribute the water and maintain the water content throughout the soil mass.

The cylinders with different compaction levels were prepared by determining the equivalent of soil drymass as a function of the bulk density (i.e., 1.04; 1.12; 1.19; 1.28; 1.36 Mg m–3) and cylinders volume (294.5 cm3), according to the steps and procedures illustrated in Figure 1c. In order to ensure structural uniformity of the soil throughout the cylinder body, compression was carried out in three soil layers, with the surface of each layer being slit to avoid discontinuity between them.

Figure 1.

Experimental procedures for quantifying the impact of soil mechanical and water stress on sugarcane root elongation rate, including soil sampling (a), sieving (b), reconstruction into compaction levels (c), hydrostatic equilibrium in Richards chambers (d), transplanting and incubation of sugarcane seedlings in growth chambers (e), and analysis of root attributes using WinRHIZO software (f).

Soil physical analysis

Physical characterizations of the soil pore volume (i.e. macroporosity, microporosity, and total porosity) were made based on the hydrostatic equilibrium of the samples in Richards chambers (Figure 1d). The samples, previously saturated by capillarity with water, had their mass determined and were subjected to a soil water matric potentialof –6 kPa (group I), corresponding to the lower energy state of the water in the macropores (pore diameter >50 µm), according to the Laplace equation (de Jong van Lier Reference de Jong van Lier and de Jong van Lier2020), and half of the soil samples (15) were subsequently submitted to the soil water matric potential of –33 kPa (group II). After the equilibrium at each soil water matric potential, the soil samples groups (–6 kPa and –33 kPa) were used for sugarcane root growth measurement. The volume of micropores was quantified by the volume of pores ≤50 µm (at –6 kPa). Total porosity was determined by the sum of macroporosity and microporosity.

Sugarcane root growth

Pre-sprouted sugarcane seedlings, 50 days old, from tillers were used to measure the root elongation rate. The developed roots were cutted, immersed in a 0.525% sodium hypochlorite (NaOCl) solution for 60 seconds, and washed in deionized water to disinfect the material (Beyerle et al. Reference Beyerle, Hensey, Brandley, Schwartz and Hilton1994). For emition of new nodular roots, the pre-sprounted sugarcane seedlings were placed on a double-layered filter paper (Cunha et al. Reference Cunha, Lopes, Monte, Ferreira and Oliveira2021) and conditioned in growth chambers (B.O.D) for 91 h, with controlled temperature of 28 ºC, relative humidity of ~70%, and photoperiod of 12 h (Melloni et al. Reference Melloni, Melloni, Scarpari, Garcia, Landell and Pinto2015; Yadav et al. Reference Yadav, Nagaraja, Lohithaswa and Shivakumar2020), with a view to the emission of new basal roots to adapt the initial root growth to the evaluation of the cylinder.

Once the new roots had sprouted (<5 mm), transplanting was carried out by inserting each root segment into holes created in the soil 5–10 mm deep using a 3 mm diameter spiral drill (Bengough et al. Reference Bengough, Loades and McKenzie2016). The initial root length was measured before transplanting. After transplanting the pre-sprounted sugarcane seedlings, a 10 cm cylinder with the same diameter was positioned at the top end of the samples to deposit a soil cover with the same gravimetric water content as each sample to provide physical support for the sugarcane seedling.

The cylinders with the plants were conditioned in a growth chamber (B.O.D) for 92 h at same conditions of temperature, relative humidity, and photoperiod that initial emition of roots (Melloni et al. Reference Melloni, Melloni, Scarpari, Garcia, Landell and Pinto2015; Yadav et al. Reference Yadav, Nagaraja, Lohithaswa and Shivakumar2020). Into the growth chamber the cilinders and pre-sprounted seedlings were placed for root growing (~92 hours) without additional irrigation or control of water content and matric potential of the soil. After removing the cylinders from the growth chamber, the soil penetration resistance was assessed until 60 mm depth, using a bench penetrometer (model CT3TM texture analyser, Brookfield Amatek®, cone 3 mm diameter, 30º angle, and penetration rate of 20 mm min–1) (Moraes et al. Reference Moraes, Silva, Zwirtes and Carlesso2014b). In the same time, soil wet mass were quantified. The soil was extracted in such a way as to preserve the roots, which were separated and washed. For each cylinder a soil sample (~30g) was dried in a oven at 105°C to quantity the soil water content.

The roots, after being washed and separated from the soil, were digitalized using a flatbed scanner. The number and length of basal roots developed from each pre-sprounted sugarcane seedlingswere measured. The roots were preserved in a ethanolsolution 70%. The root elongation rate corresponded to the quotient of the averange root length by the established growth period (92 h). The root system extracted from each sample was digitalized and analysed using WinRHIZO to determine the total root length, surface area, volume, and average diameter of the roots. In addition, the root system was segmented into root diameter classes of ≤0.5 mm, 0.5–1.0 mm, and 1.0–2.0 mm (Bieluczyk et al. Reference Bieluczyk, Piccolo, Pereira and Cherubin2023), and the same growth attributes were evaluated for each class. The relative length Eq. (1) per root diameter class was determined to assess the effect of stress levels on the relative proportion of classes and is defined as follows:

(1) $$REL=\left ({{RLi}\over{TRL}} \right )\times100$$

where REL is the relative length in percentage (%), RLi is the root length for each diameter class (i) in cm, and TRL is the total root length in cm, and 100 is the conversion factor from decimal to percentage.

Statistical analysis of soil and root data

The parameterization consisted of the relationship between root elongation rate, other root growth attributes (i.e. total length, surface area, total volume, and average root diameter), and soil penetration resistance by means of non-linear regressions. Porous volume was related to compaction levels, expressed by bulk density. Analyses of variance were carried out to verify the independent and integrated effect of mechanical and water stress in the soil on the response variables. The means of each variable were compared (Scott-Knott test, p < 0.05) according to the soil physical stress levels. Regression analyses were developed to adjust the equations expressing the behaviour of the response variables as a function of the main factors.

Results

Changes in the pore volume and soil strength

The increase in bulk density, corresponding to the compaction levels established, reduced the soil pore space (Table 1). The increase in bulk density from 1.04 to 1.36 Mg m–3 reduced total porosity from 0.67 to 0.55 m3 m–3 (–18%), and the same behaviour was observed for soil macroporosity (diameter > 50 µm), which decreased from 0.38 to 0.18 m3 m–3 (–53%), respectively (Figure 2). The volume of soil micropores (diameter ≤ 50 µm) increased from 0.29 to 0.38 m3 m–3 (+31%), with an increase in bulk density from 1.04 to 1.36 Mg m–3. Therefore, changing the compaction level of the soil samples alters the volume of macropores and micropores.

Table 1.

Soil physical characterization (bulk density, soil penetration resistance, and soil pore space) of packed soil samples from an Oxisol.

* Average of soil penetration resistance measured at –6 and –33 kPa. Averages in the same column with the same letters do not differ by the Scott-Knott test (5% significance level).

Figure 2.

Relationships between soil bulk density (BD) and soil penetration resistance (SPR) (a) and total porosity (Pt), macroporosity (MaP), and microporosity (MiP) (b) of packed soil samples of an Oxisol.

As a reflection of the rearrangement of the pore space, soil penetration resistance showed an exponential and positive relationship with the soil compaction level, represented by soil bulk density, although there was no effect from the matric potentials of water in the soil (–6 and –33 kPa). Soil penetration resistance varied from 1.35 to 4.11 MPa (+204.4%) for densities of 1.04 and 1.36 Mg m–3, respectively.

Impact of soil physical stress on root growth

The changes in the levels of mechanical impediment, related to soil penetration resistance and caused by the increase in bulk density, reduced the root elongation rate of the sugarcane (Table 2). The values for length, volume, and root surface area were reduced by the higher soil mechanical impediment, in both matric potentials of –6 and –33 kPa (Figure 3). The increase in soil penetration resistance from 1.35 MPa to 4.11 MPa reduced, on average for both matric potentials, total root length from 105.9 to 24.8 cm (–76.6%) (Figure 3a), and total surface area and root volume from 28.65 to 7.0 cm2 (–75.56%) and 0.62 to 0.16 cm³ (–74.19%) (Figure 3b), respectively. Meanwhile, the average root diameter had no difference under mechanical stress but was altered by water stress (Table 2). The average root diameter was 0–13% greater under the matric potential of –33 kPa compared to –6 kPa.

Table 2.

Sugarcane root growth attributes as a function of soil bulk density and soil water matric potential.

* Average of soil penetration resistance measured at –6 and –33 kPa. ns: not significant at the 5% confidence level using the Scott-Knott test. Averages in the same column with the same letters do not differ by the Scott-Knott test (5% significance level).

Figure 3.

Impact of mechanical stress, expressed by soil penetration resistance (SPR), on root growth attributes in pre-sprouted sugarcane seedlings: (a) total root length (TRL); (b) total root volume (TRV) and total root surface area (TRA); (c) number of seminal roots (NR); and (d) root elongation rate (ER).

The root elongation rate was negatively affected by the mechanical stress but was insensitive to the matric potential of the water in the soil (Figure 3d). The root elongation rate decreased by 53.4% due to the increase in soil penetration resistance from 1.35 to 4.11 MPa (Figure 3d). The number of seminal roots decreased exponentially from 11 to 5 roots (–54.5%) as a function of the variation in mechanical stress, regardless of the matric potential (Figure 3c).

Effect of soil physical stress on root diameter classes

Mechanical and water stress impacted the length and volume of roots (Figure 4) over diameter classes of sugarcane. In regard to root length, the diameter class of ≤0.5 mm was affected by the soil mechanical impediment and water stress (Figure 4a). The smaller-diameter roots (diameter of ≤0.5 mm) length responses to soil mechanical stress of 1.35 and 4.11 MPa under a soil water matric potential of –6 kPa were 1.2 to 1.9-fold greater than in the soil water matric potential of –33 kPa, which indicates the high sensitivity of this root class. In the root diameter class of 0.5–1 mm, length was reduced solely because of mechanical impediment, with a linear decrease of approximately 68.0% from 1.35 to 4.11 MPa (Figure 4b). Roots with an average diameter of 1–2 mm showed no response to either mechanical or water stress levels, with a negligible decrease in length at higher penetration resistance values. In contrast, root volume with an average diameter of ≤0.5 mm and 0.5–1 mm was reduced by 28.6 and 80.65%, respectively, due to mechanical stress in the soil (Figure 4d). The 1–2 mm classes did not differ between levels of physical stress in the soil.

Figure 4.

Impact of physical stresses in the soil on the different classes of root diameter in pre-sprouted sugarcane seedlings: (a) absolute length (RL) of roots with a diameter ≤0.5 mm as a function of matric potential and mechanical impedance; (b) absolute length (RL) of roots with a diameter of 0.5–1 mm and 1–2 mm; (c) relative length (REL) of roots with a diameter ≤0.5, 0.5–1 and 1–2 mm as a function of soil penetration resistance (SPR); and (d) absolute volume (REL) of roots with a diameter of ≤0.5, 0.5–1 mm and 1–2 mm.

Changes were observed in the relative proportion of the root diameter classes as a function of the total physical stresses (Figure 4c). Roots with an average diameter of ≤0.5 mm increased their relative length (proportion of total root length) as only a function of mechanical impediment. This class of root showed a linear increase in relative length from approximately 15.7 to 25.4% (+61.2%) as a function of the variation in soil penetration resistance from 1.35 to 4.11 MPa. Meanwhile, the relative length of roots with an average diameter of 0.5–1 mm decreased from approximately 53.7–36.51% (–32.0%) at the same mechanical stress variation. In contrast, the relative root length of roots with a diameter of 1–2 mm was not altered by the levels of physical stress in the soil.

Discussion

Changes in soil pore space and mechanical impediment

Soil structure is expressed by the arrangement of the solid fraction and especially the architecture of its pore space (Rabot et al. Reference Rabot, Wiesmeier, Schlüter and Vogel2018). This means that changes in soil bulk density of natural occurrence, such as densification or caused by compression during agricultural operations (i.e. compaction) (Bareta Junior et al. Reference Bareta Junior, Genú, Rampim, Umburanas and Pott2022), affect the volume of pores in the soil. Our experimental model indicated that increasing compaction level, as expressed by bulk density, resulted in an exponential 19% reduction in total soil porosity in the 1.04–1.36 Mg m–3 range., in a test with packed soil structure under three soil bulk densities using volumetric cylinders, reported a decrease of 18 and 70% in total porosity and macroporosity, respectively, which also corroborates the high reduction (53%) in macropores volume observed in our study.

The volume of macropores showed greater sensitivity to increasing soil compaction levels, as observed by Martínez et al. (Reference Martínez, Stettler, Lorenz and Keller2024) when studying the immediate impact of soil compression due to machine traffic in agricultural areas. Larger diameter pores are attributed to important gas diffusion processes (Jin et al. Reference Jin, Lei, Chen and Pan2023), crucial participation in water movement (Jarvis et al. Reference Jarvis, Coucheney, Lewan and Larsbo2024), and providing important pathways for root growth, notably under greater mechanical stress (Xiong et al. Reference Xiong, Zhang, Guo and Peng2022). Therefore, a reduction in the volume of macropores alters the properties such as permeability (i.e. water infiltration rate) (Neto et al. Reference Neto, Umburanas, Outeiro and Pott2023) and physical processes in the soil, especially root growth.

Contrary to larger-diameter pores, the volume of soil occupied by micropores increased. This increase, also observed by Silva et al. (Reference Silva, Calonego, Luperini and Putti2023) in a long-term experiment, can be explained by the rearrangement of particles in response to the pressure applied to the soil. The absolute volume of micropores, as well as macropores, decreased with increasing soil compaction levels, although there was an increase in their relative volume, that is, in proportion to total porosity. Increases in the volume of smaller-diameter pores provide greater available water content for plants in the soil (Viana et al. Reference Viana, de Souza, Auler and da Silva2023) at the same matric potential. However, it can also lead to a decrease in the rate of gas diffusion, particularly under high matric potential, which causes gaseous stress on root growth (Moraes & Gusmão Reference Moraes and Gusmão2021). Thus, in addition to changes in the total pore volume of the soil, it is necessary to assess the effects on different pore-size classes, as these are associated with various soil processes and properties that directly or indirectly affect root development.

Soil penetration resistance increased more than 3-fold, reaching 4.11 MPa in response to the increase in bulk density, with the rearrangement of particles and consequent reduction of pore space. The increase in soil penetration resistance reflects the effect of pressure applied to the soil during intense tillage and machine traffic in areas under conventional sugarcane cultivation (Tweddle et al. Reference Tweddle, Lyne, van Antwerpen and Lagerwall2021), especially when the pressure applied exceeds the soil load-bearing capacity (Toledo et al. Reference Toledo, Rolim, de Lima, Cavalcanti, Ortiz and Cherubin2021).

Soil compaction is a frequent problem in sugarcane crops due to the large biomass involved in the sugarcane harvesting process, which on average exceeds 75 Mg ha–1, in addition to the weight of the machines, normally above 10 Mg. In sugarcane fields, soil penetration resistance from 3.97 to 4.21 MPa was reported after four sugarcane harvests (Esteban et al. Reference Esteban, de Souza, Tormena and de Paula Ribeiro2019) and 3.6 MPa after six harvests (Jimenez et al. Reference Jimenez, Rolim, de Lima, Cavalcanti, Silva and Pedrosa2021). Those differences between studies are due to variations in soil texture, structure, and water content at the time of measurement. Soil penetration resistance, measured with penetrometers, can be used as an indicator of physical limitations for root growth in agricultural crops (Moraes et al. Reference Moraes, Debiasi, Carlesso, Franchini and Silva2014a). Soil penetration resistance values of 2 MPa (conventional system), 3 MPa (minimum tillage system), and 3.5 MPa (no-tillage system) have been reported as limiting values for root growth in grain-producing crops (Moraes et al. Reference Moraes, Debiasi, Carlesso, Franchini and Silva2014a). However, critical soil penetration resistance limits for sugarcane roots are scarce in the literature. In some studies, values of 2 MPa have been suggested (Resende et al. Reference Resende, Cintra, Pacheco, de Amorim, Gomes and da Silva2023), but these have been refuted in other studies (Barbosa et al. Reference Barbosa, Souza, Franco and Carvalho2018), as these values also depend on soil texture and vary from 1.5 MPa to 2.5 MPa. In general, it is known that soil structure and plant species (Bengough et al. Reference Bengough, McKenzie, Hallett and Valentine2011; Pott et al. Reference Pott, Conrado, Rampim and Müller2023) influence the critical limits of soil penetration resistance for root growth. Therefore, calibration of these values is necessary for different edaphoclimatic conditions (Moraes et al. Reference Moraes, Bengough, Debiasi and Leitner2018).

In this study, we observed that sugarcane root growth was highly affected by soil compaction, as measured by soil penetration resistance, indicating that higher compaction levels correspond to environments with greater physical stress on sugarcane root growth. This root–soil interaction may be valid for the proposed model, considering that the soil structure was packed from soil sieved through 2 mm mesh, followed by compression. However, in soils with preserved structure under conservationist tillage systems, the presence of continuous and interconnected macropores (notably biopores) can mitigate the negative impact of mechanical restrictions on root growth (Moraes et al. Reference Moraes, Debiasi, Carlesso, Cezar Franchini, Rodrigues da Silva and Bonini da Luz2016), which highlights the need to investigate the relationship between root growth and pore-related variables (e.g. pore-size distribution, pore continuity and interconnectivity, and the nature of large pores – whether they are biopores or interaggregate pores) (Xiong et al., Reference Xiong, Zhang, Guo and Peng2022).

Impact of soil physical stress on root growth

Our experimental model for parameterizing sugarcane root growth attributes was sensitive to changes in soil physical stress. Except for root diameter and the root length with a diameter class ≤0.5 mm, the other attributes were not affected by the water factor, but the impact of mechanical stress was evident. This is due to the narrow range of soil water potentials, which, combined with a small fraction of pores with diameters corresponding to the –6 and –33 kPa potential range, resulted in little change in soil water content between the two levels.

The length, surface area, and volume of a plant root system are associated with its ability to explore water and nutrients in the soil, but they are negatively affected by physical stresses in the soil, notably mechanical impedance. In areas under sugarcane cultivation with different tillage systems, Oliveira et al. (Reference Oliveira, Souza, Bolonhezi and Oliveira2022) observed a reduction in root surface area in response to increased soil compaction levels. Yu et al. (Reference Yu, Mawodza, Atkinson and Mooney2024a), in a more detailed study on the impacts of compaction on some wheat root growth attributes during its early developmental stage, demonstrated a systemic reduction in root volume, root surface area, and root length as soil bulk density increased. Similarly, sugarcane roots exhibited high sensitivity to mechanical soil impedance, with a reduction in root emission and growth.

The reduction in the root elongation rate, commonly measured in studies of soil–root biophysical interactions (Bengough et al. Reference Bengough, McKenzie, Hallett and Valentine2011; Moraes et al. Reference Moraes, Debiasi, Franchini and Leitner2019a), is explained by the greater growth pressure required to overcome the impedance imposed by the soil (Ogilvie et al. Reference Ogilvie, Ashiq, Vasava and Biswas2021), resulting in a lower rate of cell division and axial expansion of the root system. The maximum root elongation rate occurred under low compaction levels and, consequently, minimal soil penetration resistance, corresponding to a rate close to 3.5 cm d–1. This value is consistent with Glover (Reference Glover1967), who observed an average maximum root elongation rate of 2.8 cm day–1 for roots originating from tillers in clayey soils with low mechanical impedance. Under the maximum mechanical restriction established in the study, that is, at 5 MPa, the root elongation rate decreased to 1.35 cm day–1 (–59%). Materechera et al. (Reference Materechera, Alston, Kirby and Dexter1992), studying root growth of different agronomic species under mechanical impedance, reported a reduction between 88 and 97% in root elongation rate, accompanied by an increase in root diameter. This behaviour was not observed in this study for sugarcane roots, indicating a greater tolerance to higher mechanical stress levels in the soil during growth compared to other crops.

Effect of soil physical stress on root diameter classes

Regarding the different root diameter classes, the impact and intensity of physical soil stresses did not occur uniformly across each class. The effect of the moisture factor on the length of finer roots (≤0.5 mm) may be associated with a decrease in soil water uptake by these roots. This, although on a very small scale, was enough to affect the development of these roots in the soil matrix, especially considering their smaller diameter and, consequently, lower growth pressure (Materechera et al. Reference Materechera, Alston, Kirby and Dexter1992). However, in relative terms, the root length with a diameter ≤0.5 mm increased, whereas a diameter of 0.5–1 mm reduced relative length. This highlights an adaptive strategy to aid the growth of finer roots in soils with higher compaction levels, as observed in soil bulk densities greater than 1.28 Mg m–3, since these finer roots contribute to the exploration of pores with smaller diameters (Clark et al. Reference Clark, Whalley and Barraclough2003).

The greater root radial development in conditions of higher resistance is a physiological and morphological response also reported in other studies with different crops (Colombi et al. Reference Colombi, Torres, Walter and Keller2018; Correa et al. Reference Correa, Postma, Watt and Wojciechowski2019). However, our model was not sufficiently sensitive to identify the effect of soil physical stress on roots with larger diameters (1–2 mm), despite these roots showing a notable increase in relative length under conditions of higher soil penetration resistance. Moreover, the fact that coarser roots (1–2 mm) are not affected by compaction levels is supported by the greater growth pressure they exert on the soil (Materechera et al. Reference Materechera, Alston, Kirby and Dexter1992). Meanwhile, roots with smaller diameters (0.5–1 mm) were the most sensitive, being strongly affected by mechanical stress. This is due to the reduction in pore space, particularly macropores, caused by soil compaction, which leads to an increased impediment to the growth of these roots.

Mechanistic models that explain the biophysical interaction between soil and roots have been studied and proposed, notably for conditions of physical stress on root system growth (Bengough et al. Reference Bengough, Loades and McKenzie2016; Moraes et al. Reference Moraes, Debiasi, Franchini and Leitner2019a; Pandey & Bennett Reference Pandey and Bennett2024), but without greater detail on the behaviour of different root classes, even less for sugarcane. Our experimental model for sugarcane was able to identify changes in growth attributes and their variation among roots with different diameters in response to soil physical stress levels. This contributes to the parameterization of the impacts of these stresses for root growth modelling (Schnepf et al. Reference Schnepf, Black, Couvreur and Weber2020), as well as to a better understanding of biophysical processes and mechanisms of interactions with sugarcane crops.

Conclusion

Sugarcane root elongation was highly affected by soil physical stress, particularly by mechanical impedance. The sugarcane root class of 0.5–1 mm was the most impacted by the mechanical stress in the Oxisol. The soil physical limitations due to mechanical stress had less impact on the root growth of sugarcane in the 1–2 mm diameter class compared to roots in diameter classes smaller than 1 mm.

Acknowledgements

This study was financed by the Agrisus Foundation (PA 3534/23) and by the National Council for Scientific and Technological Development (CNPq) (process number 409621/2023–4). The authors acknowledge the scholarship from Coordination for the Improvement of Higher Education Personnel (CAPES) – Finance Code 001 (L.H.Q.G) and the São Paulo Research Foundation (FAPESP) for the process number 23/11945-8 (J.K.S.), 23/100427-3 (M.B.N.P.), and 24/05953-0 (L.H.Q.G.).

References

Bai, C., Ge, Y., Ashton, R.W., … Bartsch, M. (2019). The relationships between seedling root screens, root growth in the field and grain yield for wheat. Plant and Soil 440, 311326.CrossRefGoogle Scholar
Barbosa, L.C., Souza, Z.M. de, Franco, H.C.J., … Carvalho, J.L.N. (2018). Soil texture affects root penetration in Oxisols under sugarcane in Brazil. Geoderma Regional 13, 1525.CrossRefGoogle Scholar
Bareta Junior, E., Genú, A.M., Rampim, L., Umburanas, R.C. and Pott, C.A. (2022). Critical limits of soil physical attributes for corn and black oat in a Xanthic Hapludox. Revista Ciencia Agronomica 53, 110.CrossRefGoogle Scholar
Bengough, A.G. (2012). Root elongation is restricted by axial but not by radial pressures: so what happens in field soil? Plant and Soil 360, 1518.CrossRefGoogle Scholar
Bengough, A.G., Mackenzie, C.J. and Elangwe, H.E. (1994). Biophysics of the growth responses of pea roots to changes in penetration resistance. Plant and Soil 167, 135141.CrossRefGoogle Scholar
Bengough, A.G., McKenzie, B.M., Hallett, P.D. and Valentine, T.A. (2011). Root elongation, water stress, and mechanical impedance: a review of limiting stresses and beneficial root tip traits. Journal of Experimental Botany 62, 5968.CrossRefGoogle ScholarPubMed
Bengough, G.A., Loades, K. and McKenzie, B.M. (2016). Root hairs aid soil penetration by anchoring the root surface to pore walls. Journal of Experimental Botany 67, 10711078.CrossRefGoogle ScholarPubMed
Beyerle, M.P., Hensey, D.M., Brandley, D.V., Schwartz, R.S. and Hilton, T.J. (1994). Immersion disinfection of irreversible hydrocolloid impressions with sodium hypochlorite. Part 1: microbiology. The International Journal of Prosthodontics 7, 234239.Google Scholar
Bieluczyk, W., Piccolo, M.C., Pereira, M.G., … Cherubin, M.R. (2023). Fine root dynamics in a tropical integrated crop-livestock-forestry system. Rhizosphere 26, 100695.CrossRefGoogle Scholar
Chapman, N., Miller, A.J., Lindsey, K. and Whalley, W.R. (2012). Roots, water, and nutrient acquisition: let’s get physical. Trends in Plant Science 17, 701710.CrossRefGoogle ScholarPubMed
Cherubin, M.R., Karlen, D.L., Franco, A.L.C., … Cerri, C.C. (2016). Soil physical quality response to sugarcane expansion in Brazil. Geoderma 267, 156168.CrossRefGoogle Scholar
Clark, L.J., Whalley, W.R. and Barraclough, P.B. (2003). How do roots penetrate strong soil? Plant and Soil 255, 93104.CrossRefGoogle Scholar
Colombi, T., Torres, L.C., Walter, A. and Keller, T. (2018). Feedbacks between soil penetration resistance, root architecture and water uptake limit water accessibility and crop growth – a vicious circle. Science of the Total Environment 626, 10261035.CrossRefGoogle ScholarPubMed
Colombi, T. and Walter, A. (2016). Root responses of triticale and soybean to soil compaction in the field are reproducible under controlled conditions. Functional Plant Biology 43, 114128.CrossRefGoogle ScholarPubMed
Correa, J., Postma, J.A., Watt, M. and Wojciechowski, T. (2019). Soil compaction and the architectural plasticity of root systems. Journal of Experimental Botany 70, 60196034.CrossRefGoogle ScholarPubMed
Cunha, M.C.L., Lopes, J.A., Monte, A.A.M., Ferreira, T.C. and Oliveira, M.R.G. (2021). Protocolos de germinação e tetrazólio para a avaliação da qualidade fisiológica de sementes de Aspidosperma pyrifolium Mart. Research, Society and Development 10, e57910918273.CrossRefGoogle Scholar
Cury, T.N., De Maria, I.C. and Bolonhezi, D. (2014). Biomassa radicular da cultura de cana-de-açúcar em sistema convencional e plantio direto com e sem calcário. Revista Brasileira de Ciência Do Solo 38, 19291938.CrossRefGoogle Scholar
de Jong van Lier, Q. (2020). Potenciais da água no solo. In de Jong van Lier, Q. (ed.), Física do Solo Baseada em Processos. São Paulo, SP: Universidade de São Paulo, pp. 41110.Google Scholar
Esteban, D.A.A., de Souza, Z.M., Tormena, C.A., … de Paula Ribeiro, N. (2019). Soil compaction, root system and productivity of sugarcane under different row spacing and controlled traffic at harvest. Soil and Tillage Research 187, 6071.CrossRefGoogle Scholar
Frene, J.P., Pandey, B.K. and Castrillo, G. (2024). Under pressure: elucidating soil compaction and its effect on soil functions. Plant and Soil 502, 267278.Google Scholar
Giraud, M., Gall, S.L., Harings, M., … Schnepf, A. (2023). CPlantBox: a fully coupled modelling platform for the water and carbon fluxes in the soil–plant–atmosphere continuum. In Silico Plants 5, 117.CrossRefGoogle Scholar
Giuliani, L.M., Hallett, P.D. and Loades, K.W. (2024a). Effects of soil structure complexity to root growth of plants with contrasting root architecture. Soil and Tillage Research 238, 106023.CrossRefGoogle Scholar
Glover, J. (1967). The simultaneous growth of sugarcane roots and tops in relation to soil and climate. Proc. S. Afr. Sugar Technol. Assoc 41, 143159.Google Scholar
Huang, G., Kilic, A., Karady, M., … Pandey, B.K. (2022). Ethylene inhibits rice root elongation in compacted soil via ABA-and auxin-mediated mechanisms. Proceedings of the National Academy of Sciences 119, e2201072119.CrossRefGoogle ScholarPubMed
Iijima, M. and Kato, J. (2007). Combined soil physical stress of soil drying, anaerobiosis and mechanical impedance to seedling root growth of four crop species. Plant Production Science 10, 451459.CrossRefGoogle Scholar
Jacob, H., Dane, G. and Clarke, T. (2017). Methods of Soil Analysis: Part 4 Physical Methods. Madison, WI: Soil Science Society of America, Inc.Google Scholar
Jarvis, N., Coucheney, E., Lewan, E., … Larsbo, M. (2024). Interactions between soil structure dynamics, hydrological processes, and organic matter cycling: a new soil-crop model. European Journal of Soil Science 75, 124.CrossRefGoogle Scholar
Jimenez, K.J., Rolim, M.M., de Lima, R.P., Cavalcanti, R.Q., Silva, Ê.F.F. and Pedrosa, E.M.R. (2021). Soil physical indicators of a sugarcane field subjected to successive mechanised harvests. Sugar Tech 23, 811818.CrossRefGoogle Scholar
Jin, C., Lei, H., Chen, J., … Pan, H. (2023). Effect of soil aeration and root morphology on yield under aerated irrigation. Agronomy 13, 369.CrossRefGoogle Scholar
Kaspar, T.C., Taylor, H.M. and Shibles, R.M. (1984). Taproot-elongation rates of soybean cultivars in the glasshouse and their relation to field rooting depth. Crop Science 24, 916920.CrossRefGoogle Scholar
Kong, X., Yu, S., Xiong, Y., … Huang, G. (2024). Root hairs facilitate rice root penetration into compacted layers. Current Biology 34, 20392048.e3.CrossRefGoogle ScholarPubMed
Kumi, F., Obour, P.B., Arthur, E., … Adu, M.O. (2023). Quantifying root-induced soil strength, measured as soil penetration resistance, from different crop plants and soil types. Soil and Tillage Research 233, 105811.CrossRefGoogle Scholar
Letey, J. (1985). Relationship between soil physical properties and crop production. In Stewart, B.A. (ed.), Advances in Soil Science, 1st Edn, Berlin: Springer-Verlag, pp. 277294.Google Scholar
Lovera, L.H., de Souza, Z.M., Esteban, D.A.A., … Panosso, A.R. (2021). Sugarcane root system: variation over three cycles under different soil tillage systems and cover crops. Soil and Tillage Research 208, 104866.CrossRefGoogle Scholar
Manavalan, L.P., Guttikonda, S.K., Nguyen, V.T., Shannon, J.G. and Nguyen, H.T. (2010). Evaluation of diverse soybean germplasm for root growth and architecture. Plant and Soil 330, 503514.CrossRefGoogle Scholar
Marcolin, C. D. and Klein, V. A. (2011). Determination of relative soil density through a pedotransfer function of maximum bulk density. Acta Scientiarum. Agronomy, 33, 349354.Google Scholar
Martínez, I., Stettler, M., Lorenz, M., … Keller, T. (2024). Immediate effects of wheeling with agricultural machinery on topsoil gas transport properties and their anisotropy. Soil and Tillage Research 241, 106126.CrossRefGoogle Scholar
Materechera, S.A., Alston, A.M., Kirby, J.M. and Dexter, A.R. (1992). Influence of root diameter on the penetration of seminal roots into a compacted subsoil. Plant and Soil 144, 297303.CrossRefGoogle Scholar
Materechera, S.A., Dexter, A.R. and Alston, A.M. (1991). Penetration of very strong soils by seedling roots of different plant species. Plant and Soil 135, 3141.CrossRefGoogle Scholar
Melloni, M.L.G., Melloni, M.N.G., Scarpari, M.S., Garcia, J.C., Landell, M.G.A. and Pinto, L.R. (2015). Flowering of sugarcane genotypes under different artificial photoperiod conditions. American Journal of Plant Sciences 06, 456463.CrossRefGoogle Scholar
Mirreh, H.F. and Ketcheson, J.W. (1973). Influence of soil water matric potential and resistance to penetration on corn root elongation. Canadian Journal of Soil Science 53, 383388.CrossRefGoogle Scholar
Moraes, M.T., Bengough, A.G., Debiasi, H., … Leitner, D. (2018). Mechanistic framework to link root growth models with weather and soil physical properties, including example applications to soybean growth in Brazil. Plant and Soil 428, 6792.CrossRefGoogle Scholar
Moraes, M.T., Debiasi, H., Carlesso, R., Cezar Franchini, J., Rodrigues da Silva, V. and Bonini da Luz, F. (2016). Soil physical quality on tillage and cropping systems after two decades in the subtropical region of Brazil. Soil and Tillage Research 155, 351362.CrossRefGoogle Scholar
Moraes, M.T., Debiasi, H., Carlesso, R., Franchini, J.C. and Silva, V.R. (2014a). Critical limits of soil penetration resistance in a rhodic Eutrudox. Revista Brasileira de Ciência Do Solo 38, 288298.CrossRefGoogle Scholar
Moraes, M.T., Debiasi, H., Franchini, J.C., … Leitner, D. (2019). Mechanical and hydric stress effects on maize root system development at different soil compaction levels. Frontiers in Plant Science 10, 118.CrossRefGoogle ScholarPubMed
Moraes, M.T., Debiasi, H., Franchini, J.C., … Schnepf, A. (2020). Soil compaction impacts soybean root growth in an Oxisol from subtropical Brazil. Soil and Tillage Research 200, 104611.CrossRefGoogle Scholar
Moraes, M.T. and Gusmão, A.G. (2021). How do water, compaction and heat stresses affect soybean root elongation? A review. Rhizosphere 19, 100403.CrossRefGoogle Scholar
Moraes, M.T., Silva, V.R., Zwirtes, A.L. and Carlesso, R. (2014b). Use of penetrometers in agriculture: a review. Engenharia Agrícola 34, 179193.CrossRefGoogle Scholar
Mulazzani, R.P., Gubiani, P.I., Zanon, A.J., Drescher, M.S., Schenato, R.B. and Girardello, V.C. (2022). Impact of soil compaction on 30-year soybean yield simulated with CROPGRO-DSSAT. Agricultural Systems 203, 103523.CrossRefGoogle Scholar
Neto, E.G., Umburanas, R.C., Outeiro, V.H., … Pott, C.A. (2023). Machinery traffic and cover crop effects on water infiltration rate in a Xanthic Hapludox. Revista Ciencia Agronomica 54, 110.Google Scholar
Ogilvie, C.M., Ashiq, W., Vasava, H.B. and Biswas, A. (2021). Quantifying root-soil interactions in cover crop systems: a review. Agriculture (Switzerland) 11, 218.Google Scholar
Oliveira, I.N. de, Souza, Z.M., Bolonhezi, D., … Oliveira, C.F. (2022). Tillage systems impact on soil physical attributes, sugarcane yield and root system propagated by pre-sprouted seedlings. Soil and Tillage Research 223, 105460.CrossRefGoogle Scholar
Pagès, L., Serra, V., Draye, X., Doussan, C. and Pierret, A. (2010). Estimating root elongation rates from morphological measurements of the root tip. Plant and Soil 328, 3544.CrossRefGoogle Scholar
Pandey, B.K. and Bennett, M.J. (2024). Uncovering root compaction response mechanisms: new insights and opportunities. Journal of Experimental Botany 75, 578583.CrossRefGoogle Scholar
Pandey, B.K., Huang, G., Bhosale, R., … Bennett, M.J. (2021). Plant roots sense soil compaction through restricted ethylene diffusion. Science 371, 276280.CrossRefGoogle ScholarPubMed
Pott, C.A., Conrado, P.M., Rampim, L., … Müller, M.M.L. (2023). Mixture of winter cover crops improves soil physical properties under no-tillage system in a subtropical environment. Soil and Tillage Research 234, 105854.CrossRefGoogle Scholar
Rabot, E., Wiesmeier, M., Schlüter, S. and Vogel, H.J. (2018). Soil structure as an indicator of soil functions: a review. Geoderma 314, 122137.CrossRefGoogle Scholar
Resende, R.S., Cintra, F.L.D., Pacheco, E.P., de Amorim, J.R.A., Gomes, R.S.B. and da Silva, S.M. (2023). Soil penetration resistance and sugarcane rooting under subsuperficial drip irrigation levels. Sugar Tech 25, 99109.CrossRefGoogle Scholar
Rossetti, K.V. and Centurion, J. (2013). Sistemas de manejo e atributos físico-hídricos de um Latossolo Vermelho cultivado com milho. Revista Brasileira de Engenharia Agrícola e Ambiental 17, 472479.CrossRefGoogle Scholar
Schnepf, A., Black, C.K., Couvreur, V., … Weber, M. (2020). Call for participation: collaborative benchmarking of functional-structural root architecture models. The case of root water uptake. Frontiers in Plant Science 11, 316.CrossRefGoogle ScholarPubMed
Schnepf, A., Carminati, A., Ahmed, M.A., … Vetterlein, D. (2022). Linking rhizosphere processes across scales: opinion. Plant and Soil 478, 542.CrossRefGoogle Scholar
Schnepf, A., Huber, K., Landl, M., Meunier, F., Petrich, L. and Schmidt, V. (2018a). Statistical characterization of the root system architecture model CRootBox. Vadose Zone Journal 17, 111.CrossRefGoogle Scholar
Schnepf, A., Leitner, D., Landl, M., … Vereecken, H. (2018b). CRootBox: a structural–functional modelling framework for root systems. Annals of Botany 121, 10331053.CrossRefGoogle ScholarPubMed
Seidel, S.J., Gaiser, T., Srivastava, A.K., … Ewert, F. (2022). Simulating root growth as a function of soil strength and yield with a field- scale crop model coupled with a 3D architectural root model. Frontiers in Plant Science 13, 119.CrossRefGoogle ScholarPubMed
Silva, G.F. da, Calonego, J.C., Luperini, B.C.O., … Putti, F.F. (2023). No-tillage system can improve soybean grain production more than conventional tillage system. Plants 12, 3762.CrossRefGoogle ScholarPubMed
Soil Survey Staff. (2022). Keys to Soil Taxonomy, 13th Edn. Washington, DC: USDA Natural Resources Conservation Service.Google Scholar
Taylor, H.M. and Ratliff, L.F. (1969). Root elongation rates of cotton and peanuts as a function of soil strength and water content. Soil Science 108, 113119.CrossRefGoogle Scholar
Toledo, M.P.S., Rolim, M.M., de Lima, R.P., Cavalcanti, R.Q., Ortiz, P.F.S. and Cherubin, M. R. (2021). Strength, swelling and compressibility of unsaturated sugarcane soils. Soil and Tillage Research 212, 105072.CrossRefGoogle Scholar
Tomobe, H., Tsugawa, S., Yoshida, Y., … Sawa, S. (2023). A mechanical theory of competition between plant root growth and soil pressure reveals a potential mechanism of root penetration. Scientific Reports 13, 7473.CrossRefGoogle ScholarPubMed
Tweddle, P.B., Lyne, P.W.L., van Antwerpen, R. and Lagerwall, G.L. (2021). A review and synthesis of sugarcane losses attributed to infield traffic. Advances in Agronomy 166, 197250.CrossRefGoogle Scholar
Veen, B.W. and Boone, F.R. (1990). The influence of mechanical resistance and soil water on the growth of seminal roots of maize. Soil and Tillage Research 16, 219226.CrossRefGoogle Scholar
Viana, J.L., de Souza, J.L.M., Auler, A.C., … da Silva, W.M. (2023). Water dynamics and hydraulic functions in sandy soils: limitations to sugarcane cultivation in Southern Brazil. Sustainability (Switzerland) 15, 122.Google Scholar
Xiong, P., Zhang, Z., Guo, Z. and Peng, X. (2022). Macropores in a compacted soil impact maize growth at the seedling stage: effects of pore diameter and density. Soil and Tillage Research 220, 105370.CrossRefGoogle Scholar
Yadav, S., Nagaraja, T.E., Lohithaswa, H.C. and Shivakumar, K.V. (2020). Effect of temperature, humidity and light intensity on micropropagated sugarcane (Saccharum species hybrid) genotypes. Sugar Tech 22, 226231.CrossRefGoogle Scholar
Yu, C., Mawodza, T., Atkinson, B.S., … Mooney, S.J. (2024a). The effects of soil compaction on wheat seedling root growth are specific to soil texture and soil moisture status. Rhizosphere 29, 100838.CrossRefGoogle Scholar
Yu, P., Li, C., Li, M., … Hochholdinger, F. (2024b). Seedling root system adaptation to water availability during maize domestication and global expansion. Nature Genetics 56, 12451256.CrossRefGoogle ScholarPubMed
Zhou, X., Schnepf, A., Vanderborght, J., … Lobet, G. (2020). CPlantBox, a whole-plant modelling framework for the simulation of water- and carbon-related processes. In Silico Plants 2, diaa001.CrossRefGoogle Scholar
Figure 0

Figure 1. Experimental procedures for quantifying the impact of soil mechanical and water stress on sugarcane root elongation rate, including soil sampling (a), sieving (b), reconstruction into compaction levels (c), hydrostatic equilibrium in Richards chambers (d), transplanting and incubation of sugarcane seedlings in growth chambers (e), and analysis of root attributes using WinRHIZO software (f).

Figure 1

Table 1. Soil physical characterization (bulk density, soil penetration resistance, and soil pore space) of packed soil samples from an Oxisol.

Figure 2

Figure 2. Relationships between soil bulk density (BD) and soil penetration resistance (SPR) (a) and total porosity (Pt), macroporosity (MaP), and microporosity (MiP) (b) of packed soil samples of an Oxisol.

Figure 3

Table 2. Sugarcane root growth attributes as a function of soil bulk density and soil water matric potential.

Figure 4

Figure 3. Impact of mechanical stress, expressed by soil penetration resistance (SPR), on root growth attributes in pre-sprouted sugarcane seedlings: (a) total root length (TRL); (b) total root volume (TRV) and total root surface area (TRA); (c) number of seminal roots (NR); and (d) root elongation rate (ER).

Figure 5

Figure 4. Impact of physical stresses in the soil on the different classes of root diameter in pre-sprouted sugarcane seedlings: (a) absolute length (RL) of roots with a diameter ≤0.5 mm as a function of matric potential and mechanical impedance; (b) absolute length (RL) of roots with a diameter of 0.5–1 mm and 1–2 mm; (c) relative length (REL) of roots with a diameter ≤0.5, 0.5–1 and 1–2 mm as a function of soil penetration resistance (SPR); and (d) absolute volume (REL) of roots with a diameter of ≤0.5, 0.5–1 mm and 1–2 mm.