Whole farm planning raises profit despite burgeoning climate crisis

The climate crisis challenges farmer livelihoods as increasingly frequent extreme weather events impact the quantum and consistency of crop production. Here, we develop a novel paradigm to raise whole farm profit by optimising manifold variables that drive the profitability of irrigated grain farms....

Full description

Saved in:
Bibliographic Details
Published in:Scientific reports 2022-10, Vol.12 (1), p.17188-20, Article 17188
Main Authors: Muleke, Albert, Harrison, Matthew Tom, Eisner, Rowan, de Voil, Peter, Yanotti, Maria, Liu, Ke, Yin, Xiaogang, Wang, Weilu, Monjardino, Marta, Zhao, Jin, Zhang, Feng, Fahad, Shah, Zhang, Yunbo
Format: Article
Language:English
Subjects:
631/449
631/449/1736
631/449/2661
631/449/2661/2146
631/449/2661/2663
631/449/2661/2666
631/553
631/553/2709
704/106
704/106/694
704/106/694/2739
704/106/694/2739/2807
704/106/694/2739/2819
704/106/694/2786
704/106/694/682
Agricultural production
Agriculture
Australia
Climate
Climate Change
Climate effects
Crop production
Crops
Drought
Droughts
Economics
Edible Grain
Extreme weather
Farms
Genetic diversity
Grain
Humanities and Social Sciences
Irrigation systems
multidisciplinary
Profits
Rainfall
Science
Science (multidisciplinary)
Water
Water requirements
Water use
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The climate crisis challenges farmer livelihoods as increasingly frequent extreme weather events impact the quantum and consistency of crop production. Here, we develop a novel paradigm to raise whole farm profit by optimising manifold variables that drive the profitability of irrigated grain farms. We build then invoke a new decision support tool— WaterCan Profit —to optimise crop type and areas that collectively maximise farm profit. We showcase four regions across a climate gradient in the Australian cropping zone. The principles developed can be applied to cropping regions or production systems anywhere in the world. We show that the number of profitable crop types fell from 35 to 10 under future climates, reflecting the interplay between commodity price, yield, crop water requirements and variable costs. Effects of climate change on profit were not related to long-term rainfall, with future climates depressing profit by 11–23% relative to historical climates. Impacts of future climates were closely related to crop type and maturity duration; indeed, many crop types that were traditionally profitable under historical climates were no longer profitable in future. We demonstrate that strategic whole farm planning of crop types and areas can yield significant economic benefits. We suggest that future work on drought adaptation consider genetic selection criteria more diverse than phenology and yield alone. Crop types with (1) higher value per unit grain weight, (2) lower water requirements and (3) higher water-use efficiency are more likely to ensure the sustainability and prosperity of irrigated grain production systems under future climates.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-022-20896-z