Cover crops reduce soil resistance to penetration by preserving soil surface water content

•Reduction of soil strength by cover crops was not consistent within the year.•On an annual base cover crops affected soil strength by modifying soil water content.•Barley mulch increased water content, thus reducing soil strength before maize sowing.•The grass barley cover crop reduced soil strengt...

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Vydáno v:	Geoderma Ročník 386; s. 114911
Hlavní autoři:	Gabriel, José Luis, García-González, Irene, Quemada, Miguel, Martin-Lammerding, Diana, Alonso-Ayuso, María, Hontoria, Chiquinquirá
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Elsevier B.V 15.03.2021
Témata:	aeration Arid irrigated agrosystems barley Conservation agriculture cover crops fallow field experimentation germination Hordeum vulgare mulches penetrometers reduced tillage Residue mulch resistance to penetration Soil crust soil strength soil water soil water content sowing Spain surface water Vicia water content Spain CC Conservation agriculture Residue mulch BF Arid irrigated agrosystems Soil crust RP SWC
ISSN:	0016-7061, 1872-6259
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Abstract	•Reduction of soil strength by cover crops was not consistent within the year.•On an annual base cover crops affected soil strength by modifying soil water content.•Barley mulch increased water content, thus reducing soil strength before maize sowing.•The grass barley cover crop reduced soil strength more than legume vetch.•A combination of cover crops and reduced tillage diminished the risk of soil crusting. Replacement of bare fallow in rotations by cover crops is a promising tool to reduce crusting, although the interactions with the soil moisture and the effect of the cover crop species are still not well understood. The objective of this work was to determine how cover crops modify the soil surface response to penetration and their relation with the soil water content. Two winter cover crops, barley (Hordeum vulgare L.) and vetch (Vicia sp. L.), were compared with a bare fallow treatment in a 10-year field experiment in central Spain. Soil resistance to penetration and soil water content were intensively measured (76 sampling dates) at two surface depths, using two types of surface penetrometers. Under the barley cover crop, the number of very dry events was reduced by around 20%, compared to the bare fallow. The soil resistance to penetration was closely related to the surface soil water content (R2 = 0.65) and cover crops affected it through soil moisture modification. In this line, the greater mulch provided by barley cover crop respect to vetch, increased the soil water content prior to main crop seeding, resulting in less resistance to penetration during this critical period. The good performance of barley resulted in a reduction of more than 60% of the soil resistance to penetration between the 3rd and 8th year of the experiment (7.2–2.9 kg cm−2, respectively). Even under bare fallow, soil strength was decreased after ten years with reduced tillage. Therefore, the maintenance of cover crop residues over surface soil together with reduced tillage enhanced the soil surface conditions and steadily reduced the risk of crust formation. Expected enhancement of main-crop germination, water infiltration, soil aeration and erosion mitigation may be attained by cover-cropping in degraded soils.
AbstractList	•Reduction of soil strength by cover crops was not consistent within the year.•On an annual base cover crops affected soil strength by modifying soil water content.•Barley mulch increased water content, thus reducing soil strength before maize sowing.•The grass barley cover crop reduced soil strength more than legume vetch.•A combination of cover crops and reduced tillage diminished the risk of soil crusting. Replacement of bare fallow in rotations by cover crops is a promising tool to reduce crusting, although the interactions with the soil moisture and the effect of the cover crop species are still not well understood. The objective of this work was to determine how cover crops modify the soil surface response to penetration and their relation with the soil water content. Two winter cover crops, barley (Hordeum vulgare L.) and vetch (Vicia sp. L.), were compared with a bare fallow treatment in a 10-year field experiment in central Spain. Soil resistance to penetration and soil water content were intensively measured (76 sampling dates) at two surface depths, using two types of surface penetrometers. Under the barley cover crop, the number of very dry events was reduced by around 20%, compared to the bare fallow. The soil resistance to penetration was closely related to the surface soil water content (R2 = 0.65) and cover crops affected it through soil moisture modification. In this line, the greater mulch provided by barley cover crop respect to vetch, increased the soil water content prior to main crop seeding, resulting in less resistance to penetration during this critical period. The good performance of barley resulted in a reduction of more than 60% of the soil resistance to penetration between the 3rd and 8th year of the experiment (7.2–2.9 kg cm−2, respectively). Even under bare fallow, soil strength was decreased after ten years with reduced tillage. Therefore, the maintenance of cover crop residues over surface soil together with reduced tillage enhanced the soil surface conditions and steadily reduced the risk of crust formation. Expected enhancement of main-crop germination, water infiltration, soil aeration and erosion mitigation may be attained by cover-cropping in degraded soils. Replacement of bare fallow in rotations by cover crops is a promising tool to reduce crusting, although the interactions with the soil moisture and the effect of the cover crop species are still not well understood. The objective of this work was to determine how cover crops modify the soil surface response to penetration and their relation with the soil water content. Two winter cover crops, barley (Hordeum vulgare L.) and vetch (Vicia sp. L.), were compared with a bare fallow treatment in a 10-year field experiment in central Spain. Soil resistance to penetration and soil water content were intensively measured (76 sampling dates) at two surface depths, using two types of surface penetrometers. Under the barley cover crop, the number of very dry events was reduced by around 20%, compared to the bare fallow. The soil resistance to penetration was closely related to the surface soil water content (R² = 0.65) and cover crops affected it through soil moisture modification. In this line, the greater mulch provided by barley cover crop respect to vetch, increased the soil water content prior to main crop seeding, resulting in less resistance to penetration during this critical period. The good performance of barley resulted in a reduction of more than 60% of the soil resistance to penetration between the 3rd and 8th year of the experiment (7.2–2.9 kg cm⁻², respectively). Even under bare fallow, soil strength was decreased after ten years with reduced tillage. Therefore, the maintenance of cover crop residues over surface soil together with reduced tillage enhanced the soil surface conditions and steadily reduced the risk of crust formation. Expected enhancement of main-crop germination, water infiltration, soil aeration and erosion mitigation may be attained by cover-cropping in degraded soils.
ArticleNumber	114911
Author	Gabriel, José Luis Martin-Lammerding, Diana Hontoria, Chiquinquirá Quemada, Miguel García-González, Irene Alonso-Ayuso, María
Author_xml	– sequence: 1 givenname: José Luis surname: Gabriel fullname: Gabriel, José Luis organization: Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria (INIA-INAGEA), Dpto. Medio Ambiente y Agronomía, Ctra. de la Coruña km 7,5, 28040 Madrid, Spain – sequence: 2 givenname: Irene surname: García-González fullname: García-González, Irene organization: Universidad Politécnica de Madrid, Departamento de Producción Agraria, Avda. Puerta de Hierro 2-4, 28040 Madrid, Spain – sequence: 3 givenname: Miguel surname: Quemada fullname: Quemada, Miguel organization: Centro de Estudios e Investigación para la Gestión de Riesgos Agrarios y Medioambientales, CEIGRAM-UPM, Senda del Rey 13, 28040 Madrid, Spain – sequence: 4 givenname: Diana surname: Martin-Lammerding fullname: Martin-Lammerding, Diana organization: Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria (INIA-INAGEA), Dpto. Medio Ambiente y Agronomía, Ctra. de la Coruña km 7,5, 28040 Madrid, Spain – sequence: 5 givenname: María surname: Alonso-Ayuso fullname: Alonso-Ayuso, María organization: Centro de Estudios e Investigación para la Gestión de Riesgos Agrarios y Medioambientales, CEIGRAM-UPM, Senda del Rey 13, 28040 Madrid, Spain – sequence: 6 givenname: Chiquinquirá surname: Hontoria fullname: Hontoria, Chiquinquirá email: c.hontoria@upm.es organization: Universidad Politécnica de Madrid, Departamento de Producción Agraria, Avda. Puerta de Hierro 2-4, 28040 Madrid, Spain
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Snippet	•Reduction of soil strength by cover crops was not consistent within the year.•On an annual base cover crops affected soil strength by modifying soil water... Replacement of bare fallow in rotations by cover crops is a promising tool to reduce crusting, although the interactions with the soil moisture and the effect...
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SubjectTerms	aeration Arid irrigated agrosystems barley Conservation agriculture cover crops fallow field experimentation germination Hordeum vulgare mulches penetrometers reduced tillage Residue mulch resistance to penetration Soil crust soil strength soil water soil water content sowing Spain surface water Vicia water content
Title	Cover crops reduce soil resistance to penetration by preserving soil surface water content
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