A new Rothamsted long-term field experiment for the twenty-first century: principles and practice

Xiaoxi Li; Jonathan Storkey; Andrew Mead; Ian Shield; Ian Clark; Richard Ostler; Beth Roberts; Achim Dobermann

doi:10.1007/s13593-023-00914-8

A new Rothamsted long-term field experiment for the twenty-first century: principles and practice

Agron Sustain Dev. 2023;43(5):60. doi: 10.1007/s13593-023-00914-8. Epub 2023 Aug 24.

Authors

Xiaoxi Li^{1

2}, Jonathan Storkey¹, Andrew Mead¹, Ian Shield¹, Ian Clark¹, Richard Ostler¹, Beth Roberts¹, Achim Dobermann^{1

3}

Affiliations

¹ Protecting Crops and the Environment, Rothamsted Research, West Common, Harpenden, , AL5 2JQ Hertfordshire UK.
² Present Address: CSIRO Agriculture and Food, Canberra, ACT 2601 Australia.
³ Present Address: International Fertilizer Association, 49 avenue d'Iena, 75116 Paris, France.

Abstract

Agriculture faces potentially competing societal demands to produce food, fiber and fuel while reducing negative environmental impacts and delivering regulating, supporting and cultural ecosystem services. This necessitates a new generation of long-term agricultural field experiments designed to study the behavior of contrasting cropping systems in terms of multiple outcomes. We document the principles and practices of a new long-term experiment of this type at Rothamsted, established at two contrasting sites in 2017 and 2018, and report initial yield data at the crop and system level. The objective of the Large-Scale Rotation Experiment was to establish gradients of system properties and outcomes to improve our fundamental understanding of UK cropping systems. It is composed of four management factors-phased rotations, cultivation (conventional vs reduced tillage), nutrition (additional organic amendment vs standard mineral fertilization) and crop protection (conventional vs smart crop protection). These factors were combined in a balanced design resulting in 24 emergent cropping systems at each site and can be analyzed at the level of the system or component management factors. We observed interactions between management factors and with the environment on crop yields, justifying the systems level, multi-site approach. Reduced tillage resulted in lower wheat yields but the effect varied with rotation, previous-crop and site. Organic amendments significantly increased spring barley yield by 8% on average though the effect again varied with site. The plowed cropping systems tended to produce higher caloric yield overall than systems under reduced tillage. Additional response variables are being monitored to study synergies and trade-offs with outcomes other than yield at the cropping system level. The experiment has been established as a long-term resource for inter-disciplinary research. By documenting the design process, we aim to facilitate the adoption of similar approaches to system-scale agricultural experimentation to inform the transition to more sustainable cropping systems.

Supplementary information: The online version contains supplementary material available at 10.1007/s13593-023-00914-8.

Keywords: Crop protection; Crop rotation; Large-scale rotation experiment; Organic amendment; Tillage.