Deep Soil Water-Use Determines the Yield Benefit of Long-Cycle Wheat

Bonnie M Flohr; James R Hunt; John A Kirkegaard; Brad Rheinheimer; Tony Swan; Laura Goward; John R Evans; Melanie Bullock

doi:10.3389/fpls.2020.00548

Deep Soil Water-Use Determines the Yield Benefit of Long-Cycle Wheat

Front Plant Sci. 2020 May 15:11:548. doi: 10.3389/fpls.2020.00548. eCollection 2020.

Authors

Bonnie M Flohr¹, James R Hunt², John A Kirkegaard³, Brad Rheinheimer³, Tony Swan³, Laura Goward³, John R Evans⁴, Melanie Bullock³

Affiliations

¹ The Commonwealth Scientific and Industrial Research Organisation (CSIRO) Agriculture and Food, Adelaide, SA, Australia.
² Department of Animal, Plant and Soil Sciences, La Trobe University, Melbourne, VIC, Australia.
³ The Commonwealth Scientific and Industrial Research Organisation (CSIRO) Agriculture and Food, Canberra, ACT, Australia.
⁴ Research School of Biology, The Australian National University, Canberra, ACT, Australia.

Abstract

Wheat production in southern Australia is reliant on autumn (April-May) rainfall to germinate seeds and allow timely establishment. Reliance on autumn rainfall can be removed by sowing earlier than currently practiced and using late summer and early autumn rainfall to establish crops, but this requires slower developing cultivars to match life-cycle to seasonal conditions. While slow-developing wheat cultivars sown early in the sowing window (long-cycle), have in some cases increased yield in comparison to the more commonly grown fast-developing cultivars sown later (short-cycle), the yield response is variable between environments. In irrigated wheat in the sub-tropics, the variable response has been linked to ability to withstand water stress, but the mechanism behind this is unknown. We compared short- vs. long-cycle cultivars × time of sowing combinations over four seasons (2011, 2012, 2015, and 2016) at Temora, NSW, Australia. Two seasons (2011 and 2012) had above average summer fallow (December-March) rain, and two seasons had below average summer fallow rain (2015 and 2016). Initial plant available water in each season was 104, 91, 28, and 27 mm, respectively. Rainfall in the 30 days prior to flowering (approximating the critical period for yield determination) in each year was 8, 6, 14, and 190 mm, respectively. We only observed a yield benefit in long-cycle treatments in 2011 and 2012 seasons where there was (i) soil water stored at depth (ii) little rain during the critical period. The higher yield of long-cycle treatments could be attributed to greater deep soil water extraction (<1.0 m), dry-matter production and grain number. In 2015, there was little rain during the critical period, no water stored at depth and no difference between treatments. In 2016, high in-crop rainfall filled the soil profile, but high rainfall during the critical period removed crop reliance on deep water, and yields were equivalent. A simulation study extended our findings to demonstrate a median yield benefit in long-cycle treatments when the volume of starting soil water was increased. This work reveals environmental conditions that can be used to quantify the frequency of circumstances where long-cycle wheat will provide a yield advantage over current practice.

Keywords: evaporation; fallow rainfall; harvest index; transpiration efficiency; water use efficiency.