Crop yield gap and stability in organic and conventional farming systems

Crop yield gap and stability in organic and conventional farming systems

•We used data from a 13-year old farming systems comparison in the Netherlands.•The yield gap between organic and conventional farming diminished over time.•This coincided with higher nutrient use efficiency and spatial stability in the organic system.•Transition from conventional to organic results...

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Bibliographic Details
Published in:Agriculture, ecosystems & environment ecosystems & environment, 2018-03, Vol.256, p.123-130
Main Authors: Schrama, M., de Haan, J.J., Kroonen, M., Verstegen, H., Van der Putten, W.H.
Format: Article
Language:eng
Subjects:
Agricultural production
Biodiversity
Biodiversity loss
Biota
Coefficient of variation
Control stability
Crop yield
Ecological intensification
Farming
Farming systems
Food chains
Food webs
Greenhouse effect
Greenhouse gases
Groundwater
Leaching
Mineralization
Nematodes
Nutrient availability
Nutrient leaching
Nutrient loss
Nutrients
Organic farming
Organic matter
Organic soils
Outbreaks
Potatoes
Predators
Provisioning
Soil communities
Soil conditions
Soil dynamics
Soil improvement
Soil properties
Soil stability
Soil stabilization
Soil structure
Spatial stability
Studies
Sustainability
Sustainable agriculture
Sustainable intensification
Systems stability
Variability
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Summary:•We used data from a 13-year old farming systems comparison in the Netherlands.•The yield gap between organic and conventional farming diminished over time.•This coincided with higher nutrient use efficiency and spatial stability in the organic system.•Transition from conventional to organic results in fundamental changes in soil properties. A key challenge for sustainable intensification of agriculture is to produce increasing amounts of food and feed with minimal biodiversity loss, nutrient leaching, and greenhouse gas emissions. Organic farming is considered more sustainable, however, less productive than conventional farming. We analysed results from an experiment started under identical soil conditions comparing one organic and two conventional farming systems. Initially, yields in the organic farming system were lower, but approached those of both conventional systems after 10–13 years, while requiring lower nitrogen inputs. Unexpectedly, organic farming resulted in lower coefficient of variation, indicating enhanced spatial stability, of pH, nutrient mineralization, nutrient availability, and abundance of soil biota. Organic farming also resulted in improved soil structure with higher organic matter concentrations and higher soil aggregation, a profound reduction in groundwater nitrate concentrations, and fewer plant-parasitic nematodes. Temporal stability between the three farming systems was similar, but when excluding years of Phytophthora outbreaks in potato, temporal stability was higher in the organic farming system. There are two non-mutually exclusive mechanistic explanations for these results. First, the enhanced spatial stability in the organic farming system could result from changes in resource-based (i.e. bottom-up) processes, which coincides with the observed higher nutrient provisioning throughout the season in soils with more organic matter. Second, enhanced resource inputs may also affect stability via increased predator-based (i.e. top-down) control. According to this explanation, predators stabilize population dynamics of soil organisms, which is supported by the observed higher soil food web biomass in the organic farming system.We conclude that closure of the yield gap between organic and conventional farming can be a matter of time and that organic farming may result in greater spatial stability of soil biotic and abiotic properties and soil processes. This is likely due to the time required to fundamentally alter soil properti
ISSN:0167-8809
1873-2305