Biopore-Induced Deep Root Traits of Two Winter Crops

Eusun Han,Ning Huang,Miriam Athmann

doi:10.3390/agriculture10120634

Abstract

Deeper root growth can be induced by increased biopore density. In this study, we aimed to compare deep root traits of two winter crops in field conditions in response to altered biopore density as affected by crop sequence. Two fodder crop species—chicory and tall fescue—were grown for two consecutive years as preceding crops (pre-crops). Root traits of two winter crops—barley and canola, which were grown as subsequent crops (post-crops)—were measured using the profile wall and soil monolith method. While barley and canola differed greatly in deep root traits, they both significantly increased rooting density inside biopores by two-fold at soil depths shallower than 100 cm. A similar increase in rooting density in the bulk soil was observed below 100 cm soil depth. As a result, rooting depth significantly increased (>5 cm) under biopore-rich conditions throughout the season of the winter crops. Morphological root traits revealed species-wise variation in response to altered biopore density, in which only barley increased root size under biopore-rich conditions. We concluded that large-sized biopores induce deeper rooting of winter crops that can increase soil resource acquisition potential, which is considered to be important for agricultural systems with less outsourced farm resources, e.g., Organic Agriculture. Crops with contrasting root systems can respond differently to varying biopore density, especially root morphology, which should be taken into account upon exploiting biopore-rich conditions in arable fields. Our results also indicate the need for further detailed research with a greater number of species, varieties and genotypes for functional classification of root plasticity against the altered subsoil structure.

Highlights

In the face of climate change and the ever-increasing demand for sustainable intensification, more resilient and resource use-efficient crop production is called for [1]
Crops with contrasting root systems can respond differently to varying biopore density, especially root morphology, which should be taken into account upon exploiting biopore-rich conditions in arable fields
It has been reported that the taprooted cover crops such as lucerne and chicory with large root sizes are more capable of forming biopores larger than 2 mm in size compared with fibrous-rooted tall fescue [8]

Summary

Introduction

In the face of climate change and the ever-increasing demand for sustainable intensification, more resilient and resource use-efficient crop production is called for [1]. A neglected strategy is inducing crops’ root traits for deeper and better resource exploitation [2]. Winter crops, with their longer crop phenology, can grow deeper roots than short-season crops [3]. The deeper and longer root occupancy of winter crops can reduce nitrate leaching during the winter time [4], as well as induce better uptake of nutrients and water in following season [5,6]. One well-established strategy to induce further deeper rooting of the long season crops is early sowing, which increases rooting depth and invokes timely uptake of available resources at depth [4,7]. Grown spring crops [9], Agriculture 2020, 10, 634; doi:10.3390/agriculture10120634 www.mdpi.com/journal/agriculture

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