Diversifying crop rotations enhances agroecosystem services and resilience

Chang Liu; Daniel Plaza-Bonilla; Jeffrey A. Coulter; H. Randy Kutcher; Hugh J. Beckie; Li Wang; Jean Baptiste Floc'h; Chantal Hamel; Kadambot H.M. Siddique; Lingling Li; Yantai Gan

doi:10.1016/bs.agron.2022.02.007

Diversifying crop rotations enhances agroecosystem services and resilience

Chang Liu, Daniel Plaza-Bonilla, Jeffrey A. Coulter, H. Randy Kutcher, Hugh J. Beckie, Li Wang, Jean Baptiste Floc'h, Chantal Hamel, Kadambot H.M. Siddique, Lingling Li, Yantai Gan

Agronomy and Plant Genetics

Research output: Chapter in Book/Report/Conference proceeding › Chapter

86 Scopus citations

Abstract

A significant challenge in our time is to produce sufficient agricultural products on limited farmable land to meet the needs for food, feed, fiber, and industrial uses in the face of a changing climate. Conventional cropping systems mostly rely on inputs, such as fertilizers and pesticides, to boost crop yields. However, excessive inputs increase production costs and entail more direct and indirect emissions of greenhouse gases to the atmosphere that negatively impact the environment. Finding sustainable ways to increase crop productivity with little or no impact on the environment is the primary goal of modern agriculture. This review reveals that temporal-spatial diversification of crop rotations is critically needed to advance toward this goal sustainably. We find that (i) intensified crop rotations enhance carbon conversion from atmospheric CO₂ into plant biomass and thus sequester more carbon into soil; (ii) diversified crop mixtures improve system resilience, i.e., increased resistance to pest/disease incidence and weed infestation, and faster recovery after removal of the abiotic or biotic stress; (iii) diversifying crop rotations increases crop yields at the system level with improved water and fertilizer use efficiencies; (iv) legume-based crop rotations reduce the need for synthetic nitrogen fertilizers thus lowering N₂O and CO₂ emissions to the atmosphere; (v) crop diversity leads to soil microbiome diversity that optimizes soil microenvironment, improving soil health. We believe that developing and adopting of diversified cropping systems are key factors for agricultural policy setting and a top priority for on-farm decision-making to increase crop productivity and enhance soil health, while reducing negative environmental impacts.

Original language	English (US)
Title of host publication	Advances in Agronomy
Editors	Donald L. Sparks
Publisher	Academic Press Inc.
Pages	299-335
Number of pages	37
ISBN (Print)	9780323989558
DOIs	https://doi.org/10.1016/bs.agron.2022.02.007
State	Published - Jan 2022

Publication series

Name	Advances in Agronomy
Volume	173
ISSN (Print)	0065-2113

Bibliographical note

Funding Information:
The study was mainly supported by the National Natural Science Foundation of China (project #31801320 and #31761143004), the Fostering Foundation for Excellent Ph.D. Dissertations of Gansu Agricultural University (YB2018002), and in-kind contributions from Agriculture and Agri-Food Canada, the University of Western Australia, the University of Saskatchewan, and the University of Minnesota. DPB's work was through Ramón y Cajal Fellow (RYC-2018-024536-I) jointly funded by AEI-MICIU and European Social Fund.

Funding Information:
The authors thank the following experts who critically reviewed the manuscript: Dr. Ken Flower ([email protected]), Farming Systems Associate Professor, The University of Western Australia; Dr. Cameron M. Pittelkow ([email protected]), Professor in Farming Systems, UC-Davis, USA; Dr. Andrew Fletcher ([email protected]), Farming Systems Scientist, CSIRO, Australia; Professor Dr. Olaf Christen ([email protected]), Agronomy Scientist, Martin-Luther-University, Germany. The study was mainly supported by the National Natural Science Foundation of China (project #31801320 and #31761143004), the Fostering Foundation for Excellent Ph.D. Dissertations of Gansu Agricultural University (YB2018002), and in-kind contributions from Agriculture and Agri-Food Canada, the University of Western Australia, the University of Saskatchewan, and the University of Minnesota. DPB's work was through Ram?n y Cajal Fellow (RYC-2018-024536-I) jointly funded by AEI-MICIU and European Social Fund. C.L. and Y.G. designed the project and prepared the manuscript; D.P.B. J.A.C. H.R.K. H.J.B. L.W. J.B.F. and C.H. each contributed some subsections; L.L. and L.W. completed the citation crosscheck; Y.G. and K.H.M.S. finalized the paper. All authors declare no conflict of interest.

Publisher Copyright:
© 2022 Elsevier Inc.

Keywords

Biological -fixation
Carbon sequestration
GHG emissions
NUE
Rhizosphere
Soil health
WUE

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/bs.agron.2022.02.007

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Liu, C., Plaza-Bonilla, D., Coulter, J. A., Kutcher, H. R., Beckie, H. J., Wang, L., Floc'h, J. B., Hamel, C., Siddique, K. H. M., Li, L., & Gan, Y. (2022). Diversifying crop rotations enhances agroecosystem services and resilience. In D. L. Sparks (Ed.), Advances in Agronomy (pp. 299-335). (Advances in Agronomy; Vol. 173). Academic Press Inc.. https://doi.org/10.1016/bs.agron.2022.02.007

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title = "Diversifying crop rotations enhances agroecosystem services and resilience",

abstract = "A significant challenge in our time is to produce sufficient agricultural products on limited farmable land to meet the needs for food, feed, fiber, and industrial uses in the face of a changing climate. Conventional cropping systems mostly rely on inputs, such as fertilizers and pesticides, to boost crop yields. However, excessive inputs increase production costs and entail more direct and indirect emissions of greenhouse gases to the atmosphere that negatively impact the environment. Finding sustainable ways to increase crop productivity with little or no impact on the environment is the primary goal of modern agriculture. This review reveals that temporal-spatial diversification of crop rotations is critically needed to advance toward this goal sustainably. We find that (i) intensified crop rotations enhance carbon conversion from atmospheric CO2 into plant biomass and thus sequester more carbon into soil; (ii) diversified crop mixtures improve system resilience, i.e., increased resistance to pest/disease incidence and weed infestation, and faster recovery after removal of the abiotic or biotic stress; (iii) diversifying crop rotations increases crop yields at the system level with improved water and fertilizer use efficiencies; (iv) legume-based crop rotations reduce the need for synthetic nitrogen fertilizers thus lowering N2O and CO2 emissions to the atmosphere; (v) crop diversity leads to soil microbiome diversity that optimizes soil microenvironment, improving soil health. We believe that developing and adopting of diversified cropping systems are key factors for agricultural policy setting and a top priority for on-farm decision-making to increase crop productivity and enhance soil health, while reducing negative environmental impacts.",

keywords = "Biological -fixation, Carbon sequestration, GHG emissions, NUE, Rhizosphere, Soil health, WUE",

author = "Chang Liu and Daniel Plaza-Bonilla and Coulter, {Jeffrey A.} and Kutcher, {H. Randy} and Beckie, {Hugh J.} and Li Wang and Floc'h, {Jean Baptiste} and Chantal Hamel and Siddique, {Kadambot H.M.} and Lingling Li and Yantai Gan",

note = "Funding Information: The study was mainly supported by the National Natural Science Foundation of China (project #31801320 and #31761143004), the Fostering Foundation for Excellent Ph.D. Dissertations of Gansu Agricultural University (YB2018002), and in-kind contributions from Agriculture and Agri-Food Canada, the University of Western Australia, the University of Saskatchewan, and the University of Minnesota. DPB's work was through Ram{\'o}n y Cajal Fellow (RYC-2018-024536-I) jointly funded by AEI-MICIU and European Social Fund. Funding Information: The authors thank the following experts who critically reviewed the manuscript: Dr. Ken Flower ([email protected]), Farming Systems Associate Professor, The University of Western Australia; Dr. Cameron M. Pittelkow ([email protected]), Professor in Farming Systems, UC-Davis, USA; Dr. Andrew Fletcher ([email protected]), Farming Systems Scientist, CSIRO, Australia; Professor Dr. Olaf Christen ([email protected]), Agronomy Scientist, Martin-Luther-University, Germany. The study was mainly supported by the National Natural Science Foundation of China (project #31801320 and #31761143004), the Fostering Foundation for Excellent Ph.D. Dissertations of Gansu Agricultural University (YB2018002), and in-kind contributions from Agriculture and Agri-Food Canada, the University of Western Australia, the University of Saskatchewan, and the University of Minnesota. DPB's work was through Ram?n y Cajal Fellow (RYC-2018-024536-I) jointly funded by AEI-MICIU and European Social Fund. C.L. and Y.G. designed the project and prepared the manuscript; D.P.B. J.A.C. H.R.K. H.J.B. L.W. J.B.F. and C.H. each contributed some subsections; L.L. and L.W. completed the citation crosscheck; Y.G. and K.H.M.S. finalized the paper. All authors declare no conflict of interest. Publisher Copyright: {\textcopyright} 2022 Elsevier Inc.",

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AU - Beckie, Hugh J.

AU - Wang, Li

AU - Floc'h, Jean Baptiste

AU - Hamel, Chantal

AU - Siddique, Kadambot H.M.

AU - Li, Lingling

AU - Gan, Yantai

N1 - Funding Information: The study was mainly supported by the National Natural Science Foundation of China (project #31801320 and #31761143004), the Fostering Foundation for Excellent Ph.D. Dissertations of Gansu Agricultural University (YB2018002), and in-kind contributions from Agriculture and Agri-Food Canada, the University of Western Australia, the University of Saskatchewan, and the University of Minnesota. DPB's work was through Ramón y Cajal Fellow (RYC-2018-024536-I) jointly funded by AEI-MICIU and European Social Fund. Funding Information: The authors thank the following experts who critically reviewed the manuscript: Dr. Ken Flower ([email protected]), Farming Systems Associate Professor, The University of Western Australia; Dr. Cameron M. Pittelkow ([email protected]), Professor in Farming Systems, UC-Davis, USA; Dr. Andrew Fletcher ([email protected]), Farming Systems Scientist, CSIRO, Australia; Professor Dr. Olaf Christen ([email protected]), Agronomy Scientist, Martin-Luther-University, Germany. The study was mainly supported by the National Natural Science Foundation of China (project #31801320 and #31761143004), the Fostering Foundation for Excellent Ph.D. Dissertations of Gansu Agricultural University (YB2018002), and in-kind contributions from Agriculture and Agri-Food Canada, the University of Western Australia, the University of Saskatchewan, and the University of Minnesota. DPB's work was through Ram?n y Cajal Fellow (RYC-2018-024536-I) jointly funded by AEI-MICIU and European Social Fund. C.L. and Y.G. designed the project and prepared the manuscript; D.P.B. J.A.C. H.R.K. H.J.B. L.W. J.B.F. and C.H. each contributed some subsections; L.L. and L.W. completed the citation crosscheck; Y.G. and K.H.M.S. finalized the paper. All authors declare no conflict of interest. Publisher Copyright: © 2022 Elsevier Inc.

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N2 - A significant challenge in our time is to produce sufficient agricultural products on limited farmable land to meet the needs for food, feed, fiber, and industrial uses in the face of a changing climate. Conventional cropping systems mostly rely on inputs, such as fertilizers and pesticides, to boost crop yields. However, excessive inputs increase production costs and entail more direct and indirect emissions of greenhouse gases to the atmosphere that negatively impact the environment. Finding sustainable ways to increase crop productivity with little or no impact on the environment is the primary goal of modern agriculture. This review reveals that temporal-spatial diversification of crop rotations is critically needed to advance toward this goal sustainably. We find that (i) intensified crop rotations enhance carbon conversion from atmospheric CO2 into plant biomass and thus sequester more carbon into soil; (ii) diversified crop mixtures improve system resilience, i.e., increased resistance to pest/disease incidence and weed infestation, and faster recovery after removal of the abiotic or biotic stress; (iii) diversifying crop rotations increases crop yields at the system level with improved water and fertilizer use efficiencies; (iv) legume-based crop rotations reduce the need for synthetic nitrogen fertilizers thus lowering N2O and CO2 emissions to the atmosphere; (v) crop diversity leads to soil microbiome diversity that optimizes soil microenvironment, improving soil health. We believe that developing and adopting of diversified cropping systems are key factors for agricultural policy setting and a top priority for on-farm decision-making to increase crop productivity and enhance soil health, while reducing negative environmental impacts.

AB - A significant challenge in our time is to produce sufficient agricultural products on limited farmable land to meet the needs for food, feed, fiber, and industrial uses in the face of a changing climate. Conventional cropping systems mostly rely on inputs, such as fertilizers and pesticides, to boost crop yields. However, excessive inputs increase production costs and entail more direct and indirect emissions of greenhouse gases to the atmosphere that negatively impact the environment. Finding sustainable ways to increase crop productivity with little or no impact on the environment is the primary goal of modern agriculture. This review reveals that temporal-spatial diversification of crop rotations is critically needed to advance toward this goal sustainably. We find that (i) intensified crop rotations enhance carbon conversion from atmospheric CO2 into plant biomass and thus sequester more carbon into soil; (ii) diversified crop mixtures improve system resilience, i.e., increased resistance to pest/disease incidence and weed infestation, and faster recovery after removal of the abiotic or biotic stress; (iii) diversifying crop rotations increases crop yields at the system level with improved water and fertilizer use efficiencies; (iv) legume-based crop rotations reduce the need for synthetic nitrogen fertilizers thus lowering N2O and CO2 emissions to the atmosphere; (v) crop diversity leads to soil microbiome diversity that optimizes soil microenvironment, improving soil health. We believe that developing and adopting of diversified cropping systems are key factors for agricultural policy setting and a top priority for on-farm decision-making to increase crop productivity and enhance soil health, while reducing negative environmental impacts.

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KW - Carbon sequestration

KW - GHG emissions

KW - NUE

KW - Rhizosphere

KW - Soil health

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BT - Advances in Agronomy

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ER -

Diversifying crop rotations enhances agroecosystem services and resilience

Abstract

Publication series

Bibliographical note

Keywords

UN SDGs

Publisher link

Find It

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Cite this