Increasing crop rotational diversity can enhance cereal yields

Monique E. Smith; Giulia Vico; Alessio Costa; Timothy Bowles; Amélie C.M. Gaudin; Sara Hallin; Christine A. Watson; Remedios Alarcòn; Antonio Berti; Andrzej Blecharczyk; Francisco J. Calderon; Steve Culman; William Deen; Craig F. Drury; Axel Garcia y. Garcia; Andrés García-Díaz; Eva Hernández Plaza; Krzysztof Jonczyk; Ortrud Jäck; R. Michael Lehman; Francesco Montemurro; Francesco Morari; Andrea Onofri; Shannon L. Osborne; José Luis Tenorio Pasamón; Boël Sandström; Inés Santín-Montanyá; Zuzanna Sawinska; Marty R. Schmer; Jaroslaw Stalenga; Jeffrey Strock; Francesco Tei; Cairistiona F.E. Topp; Domenico Ventrella; Robin L. Walker; Riccardo Bommarco

doi:10.1038/s43247-023-00746-0

Increasing crop rotational diversity can enhance cereal yields

Monique E. Smith, Giulia Vico, Alessio Costa, Timothy Bowles, Amélie C.M. Gaudin, Sara Hallin, Christine A. Watson, Remedios Alarcòn, Antonio Berti, Andrzej Blecharczyk, Francisco J. Calderon, Steve Culman, William Deen, Craig F. Drury, Axel Garcia y. Garcia, Andrés García-Díaz, Eva Hernández Plaza, Krzysztof Jonczyk, Ortrud Jäck, R. Michael LehmanFrancesco Montemurro, Francesco Morari, Andrea Onofri, Shannon L. Osborne, José Luis Tenorio Pasamón, Boël Sandström, Inés Santín-Montanyá, Zuzanna Sawinska, Marty R. Schmer, Jaroslaw Stalenga, Jeffrey Strock, Francesco Tei, Cairistiona F.E. Topp, Domenico Ventrella, Robin L. Walker, Riccardo Bommarco

Southwest Research and Outreach Center

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

14 Scopus citations

Abstract

Diversifying agriculture by rotating a greater number of crop species in sequence is a promising practice to reduce negative impacts of crop production on the environment and maintain yields. However, it is unclear to what extent cereal yields change with crop rotation diversity and external nitrogen fertilization level over time, and which functional groups of crops provide the most yield benefit. Here, using grain yield data of small grain cereals and maize from 32 long-term (10–63 years) experiments across Europe and North America, we show that crop rotational diversity, measured as crop species diversity and functional richness, enhanced grain yields. This yield benefit increased over time. Only the yields of winter-sown small grain cereals showed a decline at the highest level of species diversity. Diversification was beneficial to all cereals with a low external nitrogen input, particularly maize, enabling a lower dependence on nitrogen fertilisers and ultimately reducing greenhouse gas emissions and nitrogen pollution. The results suggest that increasing crop functional richness rather than species diversity can be a strategy for supporting grain yields across many environments.

Original language	English (US)
Article number	89
Journal	Communications Earth and Environment
Volume	4
Issue number	1
DOIs	https://doi.org/10.1038/s43247-023-00746-0
State	Published - Dec 2023

Bibliographical note

Funding Information:
G.V., R.B. and S.H. acknowledge FORMAS grants 2018-02872 and 2018-02321. TMB acknowledges USDA AFRI grant 2017-67013-26254. LTEs managed by SRUC were supported by the Scottish Government RESAS Strategic Research Programme under project D3-, Healthy Soils for a Green Recovery. Swedish LTEs were funded by the Swedish University of Agricultural Sciences (SLU). We thank the Lawes Agricultural Trust and Rothamsted Research for data from the e-RA database. The Rothamsted Long-term Experiments National Capability (LTE-NC) was supported by the UK BBSRC (Biotechnology and Biological Sciences Research Council, BBS/E/C/000J0300) and the Lawes Agricultural Trust. The Woodslee site was supported by the Agro-Ecosystem Resilience Program (Agriculture & Agri-Food Canada) and field management provided by field crews over 6 decades is appreciated. La Canaleja LTE (Spain) was supported by RTA2017-00006-C03-01 project (Ministry of Science and Innovation. El Encín LTEs were supported by Spanish Ministry of Economy and Competitiveness funds (projects AGL2002-04186-C03-01.03, AGL2007-65698-C03-01.03, AGL2012-39929-C03-01 of which L. Navarrete was the P.I). R.A., A.G.D. and E.H.P. are also grateful to all members of the Weed Science Group from El Encín Experimental Station for their technical assistance in managing the experiments. The Brody/Poznan University of Life Sciences long-term experiments were funded by the Polish Ministry of Education and Science. We acknowledge the E-Obs dataset from the EU-FP6 project UERRA (http://www.uerra.eu) and the Copernicus Climate Change Service, and the data providers in the ECA&D project (https://www.ecad.eu/).

Funding Information:
G.V., R.B. and S.H. acknowledge FORMAS grants 2018-02872 and 2018-02321. TMB acknowledges USDA AFRI grant 2017-67013-26254. LTEs managed by SRUC were supported by the Scottish Government RESAS Strategic Research Programme under project D3-, Healthy Soils for a Green Recovery. Swedish LTEs were funded by the Swedish University of Agricultural Sciences (SLU). We thank the Lawes Agricultural Trust and Rothamsted Research for data from the e-RA database. The Rothamsted Long-term Experiments National Capability (LTE-NC) was supported by the UK BBSRC (Biotechnology and Biological Sciences Research Council, BBS/E/C/000J0300) and the Lawes Agricultural Trust. The Woodslee site was supported by the Agro-Ecosystem Resilience Program (Agriculture & Agri-Food Canada) and field management provided by field crews over 6 decades is appreciated. La Canaleja LTE (Spain) was supported by RTA2017-00006-C03-01 project (Ministry of Science and Innovation. El Encín LTEs were supported by Spanish Ministry of Economy and Competitiveness funds (projects AGL2002-04186-C03-01.03, AGL2007-65698-C03-01.03, AGL2012-39929-C03-01 of which L. Navarrete was the P.I). R.A., A.G.D. and E.H.P. are also grateful to all members of the Weed Science Group from El Encín Experimental Station for their technical assistance in managing the experiments. The Brody/Poznan University of Life Sciences long-term experiments were funded by the Polish Ministry of Education and Science. We acknowledge the E-Obs dataset from the EU-FP6 project UERRA ( http://www.uerra.eu ) and the Copernicus Climate Change Service, and the data providers in the ECA&D project ( https://www.ecad.eu/ ).

Publisher Copyright:
© 2023, The Author(s).

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Smith, M. E., Vico, G., Costa, A., Bowles, T., Gaudin, A. C. M., Hallin, S., Watson, C. A., Alarcòn, R., Berti, A., Blecharczyk, A., Calderon, F. J., Culman, S., Deen, W., Drury, C. F., Garcia, A. G. Y., García-Díaz, A., Plaza, E. H., Jonczyk, K., Jäck, O., ... Bommarco, R. (2023). Increasing crop rotational diversity can enhance cereal yields. Communications Earth and Environment, 4(1), Article 89. https://doi.org/10.1038/s43247-023-00746-0

Smith, ME, Vico, G, Costa, A, Bowles, T, Gaudin, ACM, Hallin, S, Watson, CA, Alarcòn, R, Berti, A, Blecharczyk, A, Calderon, FJ, Culman, S, Deen, W, Drury, CF, Garcia, AGY, García-Díaz, A, Plaza, EH, Jonczyk, K, Jäck, O, Lehman, RM, Montemurro, F, Morari, F, Onofri, A, Osborne, SL, Pasamón, JLT, Sandström, B, Santín-Montanyá, I, Sawinska, Z, Schmer, MR, Stalenga, J, Strock, J, Tei, F, Topp, CFE, Ventrella, D, Walker, RL & Bommarco, R 2023, 'Increasing crop rotational diversity can enhance cereal yields', Communications Earth and Environment, vol. 4, no. 1, 89. https://doi.org/10.1038/s43247-023-00746-0

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title = "Increasing crop rotational diversity can enhance cereal yields",

abstract = "Diversifying agriculture by rotating a greater number of crop species in sequence is a promising practice to reduce negative impacts of crop production on the environment and maintain yields. However, it is unclear to what extent cereal yields change with crop rotation diversity and external nitrogen fertilization level over time, and which functional groups of crops provide the most yield benefit. Here, using grain yield data of small grain cereals and maize from 32 long-term (10–63 years) experiments across Europe and North America, we show that crop rotational diversity, measured as crop species diversity and functional richness, enhanced grain yields. This yield benefit increased over time. Only the yields of winter-sown small grain cereals showed a decline at the highest level of species diversity. Diversification was beneficial to all cereals with a low external nitrogen input, particularly maize, enabling a lower dependence on nitrogen fertilisers and ultimately reducing greenhouse gas emissions and nitrogen pollution. The results suggest that increasing crop functional richness rather than species diversity can be a strategy for supporting grain yields across many environments.",

author = "Smith, {Monique E.} and Giulia Vico and Alessio Costa and Timothy Bowles and Gaudin, {Am{\'e}lie C.M.} and Sara Hallin and Watson, {Christine A.} and Remedios Alarc{\`o}n and Antonio Berti and Andrzej Blecharczyk and Calderon, {Francisco J.} and Steve Culman and William Deen and Drury, {Craig F.} and Garcia, {Axel Garcia y.} and Andr{\'e}s Garc{\'i}a-D{\'i}az and Plaza, {Eva Hern{\'a}ndez} and Krzysztof Jonczyk and Ortrud J{\"a}ck and Lehman, {R. Michael} and Francesco Montemurro and Francesco Morari and Andrea Onofri and Osborne, {Shannon L.} and Pasam{\'o}n, {Jos{\'e} Luis Tenorio} and Bo{\"e}l Sandstr{\"o}m and In{\'e}s Sant{\'i}n-Montany{\'a} and Zuzanna Sawinska and Schmer, {Marty R.} and Jaroslaw Stalenga and Jeffrey Strock and Francesco Tei and Topp, {Cairistiona F.E.} and Domenico Ventrella and Walker, {Robin L.} and Riccardo Bommarco",

note = "Funding Information: G.V., R.B. and S.H. acknowledge FORMAS grants 2018-02872 and 2018-02321. TMB acknowledges USDA AFRI grant 2017-67013-26254. LTEs managed by SRUC were supported by the Scottish Government RESAS Strategic Research Programme under project D3-, Healthy Soils for a Green Recovery. Swedish LTEs were funded by the Swedish University of Agricultural Sciences (SLU). We thank the Lawes Agricultural Trust and Rothamsted Research for data from the e-RA database. The Rothamsted Long-term Experiments National Capability (LTE-NC) was supported by the UK BBSRC (Biotechnology and Biological Sciences Research Council, BBS/E/C/000J0300) and the Lawes Agricultural Trust. The Woodslee site was supported by the Agro-Ecosystem Resilience Program (Agriculture & Agri-Food Canada) and field management provided by field crews over 6 decades is appreciated. La Canaleja LTE (Spain) was supported by RTA2017-00006-C03-01 project (Ministry of Science and Innovation. El Enc{\'i}n LTEs were supported by Spanish Ministry of Economy and Competitiveness funds (projects AGL2002-04186-C03-01.03, AGL2007-65698-C03-01.03, AGL2012-39929-C03-01 of which L. Navarrete was the P.I). R.A., A.G.D. and E.H.P. are also grateful to all members of the Weed Science Group from El Enc{\'i}n Experimental Station for their technical assistance in managing the experiments. The Brody/Poznan University of Life Sciences long-term experiments were funded by the Polish Ministry of Education and Science. We acknowledge the E-Obs dataset from the EU-FP6 project UERRA (http://www.uerra.eu) and the Copernicus Climate Change Service, and the data providers in the ECA&D project (https://www.ecad.eu/). Funding Information: G.V., R.B. and S.H. acknowledge FORMAS grants 2018-02872 and 2018-02321. TMB acknowledges USDA AFRI grant 2017-67013-26254. LTEs managed by SRUC were supported by the Scottish Government RESAS Strategic Research Programme under project D3-, Healthy Soils for a Green Recovery. Swedish LTEs were funded by the Swedish University of Agricultural Sciences (SLU). We thank the Lawes Agricultural Trust and Rothamsted Research for data from the e-RA database. The Rothamsted Long-term Experiments National Capability (LTE-NC) was supported by the UK BBSRC (Biotechnology and Biological Sciences Research Council, BBS/E/C/000J0300) and the Lawes Agricultural Trust. The Woodslee site was supported by the Agro-Ecosystem Resilience Program (Agriculture & Agri-Food Canada) and field management provided by field crews over 6 decades is appreciated. La Canaleja LTE (Spain) was supported by RTA2017-00006-C03-01 project (Ministry of Science and Innovation. El Enc{\'i}n LTEs were supported by Spanish Ministry of Economy and Competitiveness funds (projects AGL2002-04186-C03-01.03, AGL2007-65698-C03-01.03, AGL2012-39929-C03-01 of which L. Navarrete was the P.I). R.A., A.G.D. and E.H.P. are also grateful to all members of the Weed Science Group from El Enc{\'i}n Experimental Station for their technical assistance in managing the experiments. The Brody/Poznan University of Life Sciences long-term experiments were funded by the Polish Ministry of Education and Science. We acknowledge the E-Obs dataset from the EU-FP6 project UERRA ( http://www.uerra.eu ) and the Copernicus Climate Change Service, and the data providers in the ECA&D project ( https://www.ecad.eu/ ). Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = dec,

doi = "10.1038/s43247-023-00746-0",

language = "English (US)",

volume = "4",

journal = "Communications Earth and Environment",

issn = "2662-4435",

publisher = "Springer Nature",

number = "1",

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T1 - Increasing crop rotational diversity can enhance cereal yields

AU - Smith, Monique E.

AU - Vico, Giulia

AU - Costa, Alessio

AU - Bowles, Timothy

AU - Gaudin, Amélie C.M.

AU - Hallin, Sara

AU - Watson, Christine A.

AU - Alarcòn, Remedios

AU - Berti, Antonio

AU - Blecharczyk, Andrzej

AU - Calderon, Francisco J.

AU - Culman, Steve

AU - Deen, William

AU - Drury, Craig F.

AU - Garcia, Axel Garcia y.

AU - García-Díaz, Andrés

AU - Plaza, Eva Hernández

AU - Jonczyk, Krzysztof

AU - Jäck, Ortrud

AU - Lehman, R. Michael

AU - Montemurro, Francesco

AU - Morari, Francesco

AU - Onofri, Andrea

AU - Osborne, Shannon L.

AU - Pasamón, José Luis Tenorio

AU - Sandström, Boël

AU - Santín-Montanyá, Inés

AU - Sawinska, Zuzanna

AU - Schmer, Marty R.

AU - Stalenga, Jaroslaw

AU - Strock, Jeffrey

AU - Tei, Francesco

AU - Topp, Cairistiona F.E.

AU - Ventrella, Domenico

AU - Walker, Robin L.

AU - Bommarco, Riccardo

N1 - Funding Information: G.V., R.B. and S.H. acknowledge FORMAS grants 2018-02872 and 2018-02321. TMB acknowledges USDA AFRI grant 2017-67013-26254. LTEs managed by SRUC were supported by the Scottish Government RESAS Strategic Research Programme under project D3-, Healthy Soils for a Green Recovery. Swedish LTEs were funded by the Swedish University of Agricultural Sciences (SLU). We thank the Lawes Agricultural Trust and Rothamsted Research for data from the e-RA database. The Rothamsted Long-term Experiments National Capability (LTE-NC) was supported by the UK BBSRC (Biotechnology and Biological Sciences Research Council, BBS/E/C/000J0300) and the Lawes Agricultural Trust. The Woodslee site was supported by the Agro-Ecosystem Resilience Program (Agriculture & Agri-Food Canada) and field management provided by field crews over 6 decades is appreciated. La Canaleja LTE (Spain) was supported by RTA2017-00006-C03-01 project (Ministry of Science and Innovation. El Encín LTEs were supported by Spanish Ministry of Economy and Competitiveness funds (projects AGL2002-04186-C03-01.03, AGL2007-65698-C03-01.03, AGL2012-39929-C03-01 of which L. Navarrete was the P.I). R.A., A.G.D. and E.H.P. are also grateful to all members of the Weed Science Group from El Encín Experimental Station for their technical assistance in managing the experiments. The Brody/Poznan University of Life Sciences long-term experiments were funded by the Polish Ministry of Education and Science. We acknowledge the E-Obs dataset from the EU-FP6 project UERRA (http://www.uerra.eu) and the Copernicus Climate Change Service, and the data providers in the ECA&D project (https://www.ecad.eu/). Funding Information: G.V., R.B. and S.H. acknowledge FORMAS grants 2018-02872 and 2018-02321. TMB acknowledges USDA AFRI grant 2017-67013-26254. LTEs managed by SRUC were supported by the Scottish Government RESAS Strategic Research Programme under project D3-, Healthy Soils for a Green Recovery. Swedish LTEs were funded by the Swedish University of Agricultural Sciences (SLU). We thank the Lawes Agricultural Trust and Rothamsted Research for data from the e-RA database. The Rothamsted Long-term Experiments National Capability (LTE-NC) was supported by the UK BBSRC (Biotechnology and Biological Sciences Research Council, BBS/E/C/000J0300) and the Lawes Agricultural Trust. The Woodslee site was supported by the Agro-Ecosystem Resilience Program (Agriculture & Agri-Food Canada) and field management provided by field crews over 6 decades is appreciated. La Canaleja LTE (Spain) was supported by RTA2017-00006-C03-01 project (Ministry of Science and Innovation. El Encín LTEs were supported by Spanish Ministry of Economy and Competitiveness funds (projects AGL2002-04186-C03-01.03, AGL2007-65698-C03-01.03, AGL2012-39929-C03-01 of which L. Navarrete was the P.I). R.A., A.G.D. and E.H.P. are also grateful to all members of the Weed Science Group from El Encín Experimental Station for their technical assistance in managing the experiments. The Brody/Poznan University of Life Sciences long-term experiments were funded by the Polish Ministry of Education and Science. We acknowledge the E-Obs dataset from the EU-FP6 project UERRA ( http://www.uerra.eu ) and the Copernicus Climate Change Service, and the data providers in the ECA&D project ( https://www.ecad.eu/ ). Publisher Copyright: © 2023, The Author(s).

PY - 2023/12

Y1 - 2023/12

N2 - Diversifying agriculture by rotating a greater number of crop species in sequence is a promising practice to reduce negative impacts of crop production on the environment and maintain yields. However, it is unclear to what extent cereal yields change with crop rotation diversity and external nitrogen fertilization level over time, and which functional groups of crops provide the most yield benefit. Here, using grain yield data of small grain cereals and maize from 32 long-term (10–63 years) experiments across Europe and North America, we show that crop rotational diversity, measured as crop species diversity and functional richness, enhanced grain yields. This yield benefit increased over time. Only the yields of winter-sown small grain cereals showed a decline at the highest level of species diversity. Diversification was beneficial to all cereals with a low external nitrogen input, particularly maize, enabling a lower dependence on nitrogen fertilisers and ultimately reducing greenhouse gas emissions and nitrogen pollution. The results suggest that increasing crop functional richness rather than species diversity can be a strategy for supporting grain yields across many environments.

AB - Diversifying agriculture by rotating a greater number of crop species in sequence is a promising practice to reduce negative impacts of crop production on the environment and maintain yields. However, it is unclear to what extent cereal yields change with crop rotation diversity and external nitrogen fertilization level over time, and which functional groups of crops provide the most yield benefit. Here, using grain yield data of small grain cereals and maize from 32 long-term (10–63 years) experiments across Europe and North America, we show that crop rotational diversity, measured as crop species diversity and functional richness, enhanced grain yields. This yield benefit increased over time. Only the yields of winter-sown small grain cereals showed a decline at the highest level of species diversity. Diversification was beneficial to all cereals with a low external nitrogen input, particularly maize, enabling a lower dependence on nitrogen fertilisers and ultimately reducing greenhouse gas emissions and nitrogen pollution. The results suggest that increasing crop functional richness rather than species diversity can be a strategy for supporting grain yields across many environments.

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Increasing crop rotational diversity can enhance cereal yields

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