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RESEARCH ARTICLE
Contents Vol 67(4)

Canola yield improvement on the Canadian Prairies from 2000 to 2013

M. J. Morrison A C , K. N. Harker A , R. E. Blackshaw A , C. J. Holzapfel B and J. T. O’Donovan A
+ Author Affiliations
- Author Affiliations

A Agriculture and Agri-Food Canada, Canada.

B Indian Head Agricultural Research Foundation.

C Corresponding author. Email: Malcolm.Morrison@AGR.GC.CA

Crop and Pasture Science 67(4) 245-252 https://doi.org/10.1071/CP15348
Submitted: 14 October 2015  Accepted: 21 November 2015   Published: 6 May 2016

Abstract

During the period from 2000 to 2013, average canola yields from Canadian farms increased from 1330 to 2025 kg ha–1, or 54 kg ha–1 year–1. The objective of this review was to propose likely reasons behind this increase by examining genotypic, environmental and agronomic factors. During this period, hybrid canola cultivars with herbicide tolerance (HY-HT) expanded from 80% to >95% of the area sown to canola. Genetic gain from switching from open-pollinated cultivars to HY-HT cultivars was estimated to account for 32 kg ha–1 year–1. When some key environmental factors were examined, there were no significant linear changes in growing season temperature, although the linear increase in April and May precipitation was significant and likely responsible for an increase of 12 kg ha–1 year–1. When coupled with the yield increase from changes in atmospheric CO2 (3 kg ha–1 year–1), the environment was estimated to account for ~15 kg ha–1 year–1. Ignoring all main-factor interactions, changes due to management accounted for the remainder, or 7 kg ha–1 year–1. The expanded use of HY-HT varieties has resulted in better weed control, and an increase in the use of minimum tillage, leading to greater water-use efficiency and higher yield. It is likely that many of the effects of changes in management were hidden in the interaction with genotype and environment main effects. It is difficult to estimate these interactions without designing experiments to do so. The design and implementation of experiments to understand the interaction among main factors should be a priority. Future yield targets of 25 Mt canola by 2025 will require an increase in yield per ha beyond the current rate, or an increase in the land seeded to canola, or a combination of the two factors. Continued progress with canola yield depends on active plant-breeding programs, agronomic research using new varieties, favourable environmental conditions, and high world commodity prices.


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