Farming systems profit and risk over time: exploring the N legacy impacts on profit in different farming systems.

Farming systems profit and risk over time: exploring the N legacy impacts on profit in different farming systems.

Take home message

  • A range of different systems were profitable and had similar average annual gross margin over 6 years, but differed significantly in variability and return on investment (ROI)
  • Despite being the most profitable at only two of the four sites, Diverse systems involving grain legumes with a low N strategy had consistently higher ROI than Baseline cereal-canola systems
  • Reduced N inputs to legumes and to cereal and canola crops following legumes were more important economically than yield benefits following the legumes, which were rare
  • Fababean was more profitable than lupin and had a greater legacy on subsequent crops
  • Issues related to nitrogen supply (costs and response) underpin most of the productivity and profitability differences observed between the systems.

The Southern Farming Systems Project – a brief description

The southern NSW farming systems project was established in 2017 after 12-month consultation period and extensive literature review demonstrated a significant gap in profitability and rainfall efficiency ($/ha/mm) of current cropping systems (i.e. actual vs potential) despite good agronomy of individual crops.  The average annual gross margin of the best 3-4-year sequences was often ~$400/ha higher than the worst, and $150 to $250/ha higher than the common ’baseline’ sequences.   Research sites and simulation studies were established to investigate strategies to increase the conversion of rainfall to profit across a crop sequence while managing weeds, diseases, soil fertility and risk.

Four sites covered soil and climate variability across southern NSW at Greenethorpe, Wagga Wagga and Condobolin (high, medium and low rainfall sites on red acidic loam soils), and a 4th site on a sodic clay vertosol at Urana.  At each site, the ‘Baseline’ system (sequence of canola-wheat-wheat or canola-wheat-barley; timely sown in late April-early May; and with a conservative decile 2 N strategy) was compared with a range of other systems that varied in (i) crop diversity (inclusion of legumes), (ii) sowing time (early and timely) and (iii) N strategy (conservative decile 2 and optimistic decile 7) (Table 1).  Management protocols for all other input and management decisions (e.g. tillage and stubble management; variety choice; herbicide, fungicide and pesticide applications) were agreed by the project team using a consensus approach of best practice that was continually reviewed.

Table 1. Selected systems common to most   sites including different crop sequence, time of sowing and N strategies. Early-sown (March) treatments included winter grazed crops at Wagga and Greenethorpe.  Diverse systems including a legume are shown in grey.

System

Crop sequence

Sowing time1

N strategy (Decile 2 or 7)

Grazing

Baseline

Barley-canola-wheat

Timely

2, 7

No

Intense Baseline

Canola-wheat

Early, Timely

2, 7

Yes

Diverse low value

(Faba/lupin)-canola-wheat

Timely

2, 7

No

Diverse high value

(Lentil/chickpea)-canola-wheat

Early, Timely

2

No

Diverse mix

Vetch-canola-wheat

Timely

2

No

Continuous wheat

Wheat-wheat-wheat

Timely

2, 7

No

Fallow

Fallow-canola-wheat

Early, Timely

7

No

1 Early sowing= from March 1 if grazed, April 1 if un grazed; Timely sowing = late April to mid-May

The N strategies (decile 2 or decile 7) apply top-dressed N each year in July to cereals and canola assuming the season will finish as either decile 2 (lower yield and less N) or decile 7 (higher yield so more N).  N requirement is adjusted in each treatment to account for soil N measured pre-sowing, so carry-over ‘legacy N’ from previous seasons (fertiliser or legume N) means less N will be required for the current crop and so the value of legacy N from fertiliser or legumes is captured in the lower input costs.

Seasonal conditions at the sites during the 2018-2023 seasons

The 2018 and 2019 seasons were dry (decile 1-2), the 2020 to 2022 were wet (decile 7-10) while the 2023 season was closer to long-term average (decile 5-6), except at Urana (decile 8) (Table 2).

Table 2. Rainfall (+irrigation) at the experiment sites from 2018 to 2022 and the long-term median (LTM) rainfall and the decile for that season (brackets).

Site

2018

2019

2020

2021

2022

2023

LTM

Greenethorpe

359 (2)

353 (2)

726 (10)

943 (10)

875 (10)

590 (5)

579

Wagga Wagga

403 (3)

320 (2)

557 (8)

757 (10)

886 (10)

559 (6)

526

Urana

276 (1)

222 (1)

488 (6)

564 (9)

968 (10)

552 (8)

449

Condobolin

218+120 (1)

162+118 (1)

685 (9)

806 (10)

958 (10)

474 (6)

434

Brief background to the outcomes so far

Phase 1 (2018-2020)

In Phase 1, the outcomes for the different systems were highly influenced by the two consecutive dry seasons (see Kirkegaard et al., 2021). The key outcome for grain-only systems for phase 1 was that at all sites, the diverse systems that included a legume, and with a decile 2 N strategy were more profitable than the Baseline system, were less risky, had stable or declining weed and disease burdens, and lower average input costs.  Simulation also predicted these results to be robust for a range of seasons modelled over the longer term.  In mixed (grazing crop) systems, the most profitable systems involved early sown grazed crops (wheat-canola) with a higher N fertiliser strategy (decile 7).

Phase 2 (2021-2023)

The effect of the 3 consecutive wet seasons (2020 -2022) on these early results were considered in detail in (Kirkegaard et al., 2022, 2023).  The wet conditions provided opportunities to lift yield and profitability, capitalise on higher N strategies and earlier-sown crops, but also increased the risks of disease, lodging, grain quality reduction and reduced the timeliness of operations.  Grain legumes can suffer significant yield losses to disease and lodging and/or significant costs for multiple fungicide applications.  Consequently, during these wet seasons, the Baseline and Intense Baseline systems with more canola and higher N supply performed well in terms of profit but had lower return on investment, while some systems with legumes (e.g. chickpea) performed poorly.

As a consequence, after 5 years, the diverse systems with grain legumes and decile 2 N strategy remained the most profitable at two sites (Urana and Greenethorpe), while the Baseline and Intense Baseline were more profitable at Wagga and Condobolin, but with greater risk.

Profit and risk after 6 years (2018-2023)

Effect of diversity and N strategy in timely-sown grain-only crops

A summary of outcomes for selected timely-sown grain-only systems across all sites is provided in Table 3, with a focus on the effect of crop diversity, and nitrogen strategy.  The systems are arranged in Table 3 for each site in order of increasing crop diversity (Continuous wheat = 100% cereal, Baseline systems = 66% cereal, Intense Baseline = 50% cereal, Diverse = 33% cereal).  For the diverse systems, the most profitable of the legume sequences was used in each case.

Profitability is represented by average annual $GM (2018-2023), risk by both the variability (standard error) of annual $GM, and the profit/cost ratio (ROI).  The average annual N applied as fertiliser (kg/ha/yr) is also shown in Table 3, as N fertiliser was a significant cost driver.

At the two sites (Wagga and Greenethorpe) where continuous wheat systems were included, they had significantly lower $GM than the Baseline systems although the variability in $GM was also relatively low (Table 3).  The ROI was also relatively low compared to the Baseline at Wagga Wagga but similar at Greenethorpe, perhaps reflecting the lower level of N applied at Greenethorpe. At Wagga, the average $GM of continuous wheat system was responsive to higher N in the decile 7 treatment (extra 56 kg N/ha/yr), but this did not match the profitability or ROI of the more diverse systems with lower N.

Intensifying the Baseline systems by moving to Intense canola-wheat (C-W) systems reduced average $GM at Wagga Wagga and Urana while increasing the $GM at Greenethorpe and Condobolin.  At all sites, the variability in $GM was increased, while ROI was either reduced (Wagga Wagga, Urana) or unchanged.  Average N supply increased at all sites in the Intense Baseline system, most notably at Greenethorpe and Wagga Wagga with minor increases at the other sites.  Increasing N supply to the Intense Baseline systems (average increase 40-60 kg/ha/yr) had most impact on $GM at Urana (+$164), smaller effects at Wagga wagga and Urana (~+$50/ha) and a small reduction at Condobolin.  The additional income barely covered the higher N costs, with ROI declining or remaining relatively unchanged and variability in $GM generally increasing.

The diverse system with low N was the most profitable system at Urana, matched the most profitable at Greenethorpe, but was less profitable than the Baseline   at Wagga and Condobolin.   However, the Diverse systems consistently had the highest ROI at all sites by a significant margin,  This was partly related to the much lower average annual N required (40-50 kg/ha/yr less) in those systems.  The variability in $GM was similar or lower than Baseline at Wagga and Condobolin but higher at Greenethorpe and Urana – possibly reflecting the variable performance of the legumes across the years with respect to yield and price compared to canola, wheat and barley.

Table 3. Average gross margins ($/ha/yr) and variation (standard error) in gross margin for timely-sown, grain-only systems at four experimental sites over 6 years (2018-2023).  Profit/cost ratio ($GM/$Variable costs) are shown as a measure of return on investment and risk.  The average annual N application as fertiliser (kg N/ha/yr) to each system is also shown.  N2 and N7 refer to the decile 2 and decile 7 nitrogen strategies.

System

Crop
sequence

Average annual gross margin (GM) ($/ha/yr)

Variability in gross margin (Std. Err.) ($/ha/yr)

Profit/Cost ratio

(ROI)

Average N applied (kg/ha/yr)

N2

N7

N2

N7

N2

N7

N2

N7

Wagga Wagga

Cont. wheat

W-W-W

652

732

86

129

0.94

0.91

77

133

Baseline

C-W-B

902

944

116

121

1.11

1.06

97

143

Int. Baseline

C-W

767

819

143

143

0.87

0.9

103

144

Diverse

Lu-C-W

802

-

97

-

1.20

-

54

-

Greenethorpe

Cont. wheat

W-W-W

953

-

96

-

1.47

-

47

-

Baseline

C-W-W

1108

1130

131

159

1.42

1.32

77

119

Int. Baseline

C-W

1163

1219

198

222

1.37

1.33

88

135

Diverse

Fa-C-W

1179

-

172

-

1.46

-

40

-

Urana

Baseline

C-W-B

816

-

109

-

1.12

-

72

-

Int. Baseline

C-W

682

847

115

163

0.91

0.98

78

137

Diverse

Fa-C-W

992

-

130

-

1.38

-

29

-

Condobolin

Baseline

C-W-B

781

-

127

-

1.14

-

67

-

Int. Baseline

C-W

826

809

153

158

1.15

1.08

74

116

Diverse

Lu-C-W

730

-

127

-

1.31

-

42

-

In summary, while the most profitable diverse systems have matched the average profit of the Baseline and Intense Baseline systems at some but not all sites, the consistent benefit is the increased ROI of the Diverse systems at all sites, partly related to the reduced requirement for N fertiliser.  Economic responses to increased N fertiliser were relatively small and didn’t cover the increased cost with lower ROI with the exception of the Intense Baseline at Urana.

The Diverse systems involving chickpea/lentil matched the profit of the system involving fababean at Urana, but were less profitable by $145/yr. at Condobolin (cf lupin), $90 at Greenethorpe (cf fababean), and $37/yr at Wagga (cf lupin). The chickpea was especially affected by waterlogging and cold conditions in 2022, and by the need for repeated fungicide sprays for Ascochyta in 2020 and 2021.

Effect of earlier sowing in grain-only crops

Recent research has demonstrated that earlier sown crops selected to flower within the optimum flowering window can have a grain yield and water-use efficiency advantage over timely-sown crops especially when stored subsoil water is available (Flohr et al., 2020).  They also provide grazing opportunities on mixed farms.  However early sown crops may leave a legacy of drier and lower N subsoils which can reduce the growth of following crops in a sequence. Consequently, the effect of earlier sown crops on the profitability of the system was of interest in this project.

At 3 of the 4 sites (not at Greenethorpe), we could make direct comparisons of grain-only systems that differed only in the sowing time of the wheat and canola crops (Table 4).

The benefit of early-sown wheat and canola in the Diverse N2 system was significant at Condobolin where it added $139/yr to the average annual $GM and this was mostly driven by the higher yield of the earlier-sown wheat and canola.  At Wagga, a smaller benefit was achieved by sowing early in the Diverse N2 system, but not in the N7 system, because the additional cost of the increased N applied was not recovered.  At Urana in the Intense Baseline canola-wheat system there was only marginal benefit from sowing earlier in the N2 system and reduced profit at N7, similar to the Wagga observation.

In summary the value of earlier-sown crops is dependent on the site and the system (both crop sequence and N strategy) but can provide a significant boost to the profitability of the system in the medium term.

Table 4. Effect of wheat and canola sowing times in selected systems at three sites on the average annual gross margin from 2018-2023.

Site

System

Average annual gross margin ($/ha/yr)

Timely sown

Early sown

Difference

Condobolin

Diverse N2 (Le/Ch-C-W)

585

724

+139

Wagga

Diverse N2 (Le/Ch-C-W)

765

786

+21

Diverse N7 (Le/Ch-C-W)

748

609

-139

Urana

Int. Baseline N2 (C-W)

682

695

+13

Int. Baseline N7 (C-W)

847

775

-72

N legacy impacts on profit

The effect of N legacies at the experimental sites have been reported at previous Updates by Swan et al., (2022) and Dunn et al., (2023).  In exploring the value of N legacies from legumes on following crops and on the profit and risk of the systems there are several questions that can be considered.

  1. Is there a legacy of higher soil mineral N in the soil after legumes compared to non-legumes?
  2. How much less fertiliser was applied to the system as a result?
  3. Was there a yield increase in following crops?
  4. Did (1)-(3) contribute to increased profit and reduced risk?

In answer to (1) Table 5 summarises the soil mineral N in the soil prior to the canola crops following wheat or barley crops in the Baseline systems and following legumes (lupin or fababean) in the Diverse systems (as previously shown in Table 3).  Except in the flood year at Condobolin (2022), a legacy of higher mineral N following the legumes was observed at all sites and in all seasons, with an additional average pre-sowing mineral N of 26, 98, 48 and 42 kg N/ha at Wagga, Greenethorpe, Urana and Condobolin respectively.  This would have reduced the N applied to reach the target yield in the canola crops within those systems each year.  In addition to the higher N in the soil prior to the canola, there was also higher N in the soil prior to the subsequent wheat crops which averaged +27, +50, +16 kg N/ha at Wagga, Greenethorpe and Urana while there was 10 kg N/ha less prior to wheat at Condobolin (data not shown).  Though it is difficult to attribute this legacy specifically to the legume due to the differences in top-dressed N and N removal by the canola crops, the overall effect was to reduce the average annual application of N fertiliser to the Diverse system by 43, 37, 43, and 25 kg N/ha/yr (as shown previously in Table 3).

Table 5. Mineral N in the soil prior to sowing canola following barley or wheat in the Baseline systems and following fababean or lupin in the Diverse systems at the four sites.  Note all crops in 2018 (Yr 1) followed wheat so no legacy effects exited in that year.

System

Crop sequence

Mineral nitrogen in soil prior to canola (kg N/ha)

2019

2020

2021

2022

2023

Mean

Wagga Wagga

Baseline

B-C-W

47

81

91

91

47

71

Diverse

Lu-C-W

78

67

114

128

154

97

Greenethorpe

Baseline

B-C-W

217

180

109

127

58

136

Diverse

Fa-C-W

260

264

339

233

133

234

Urana

Baseline

B-C-W

45

84

66

47

45

57

Diverse

Fa-C-W

101

106

123

112

133

105

Condobolin

Baseline

B-C-W

53

64

15

11

132

52

Diverse

Lu-C-W

133

146

48

2

190

94

With respect to (3), any yield benefit following the legumes in the subsequent canola crop cannot necessarily be attributed to the extra N measured pre-sowing, because the canola crops were top-dressed to a decile 2 yield target according to the N available at sowing.  Indeed, the N applied to the canola crops was reduced on average by 18, 58, 41 and 27 kg N/ha at Wagga, Greenethorpe, Urana and Condobolin respectively following the legumes in the Diverse systems.  This represented a cost saving, but had an equalising effect on N supply, although additional N may have mineralised after sowing following the legumes, to provide an additional N benefit for the following crop.  As the higher soil N legacy persisted to the subsequent wheat crops, there was also around 20 kg N/ha less N applied to the wheat crops on average in the Diverse systems.  These N savings were significant but were small compared to the reductions in N applied to the legume crops themselves (<5 kg N/ha applied) compared to barley or wheat (50 to 100 kg N/ha applied) which were 86, 47, 62 and 50 kg N/ha at Wagga, Greenethorpe, Urana and Condobolin respectively.

There was little overall yield benefit measured in the canola crops following the legumes in the Diverse systems at the 4 sites (+0.3 t/ha at Urana only) or in the subsequent wheat crops (+0.3 t/ha at Greenethorpe only) (data not shown).   Consequently, except for these two cases, little of the economic benefits within the Diverse systems have arisen from higher yields and income in the canola or wheat crops following the legumes in the Diverse systems.

In assessing the impact of legacy N on profit and risk, it is useful to examine the overall performance of the different crops in the sequence across the 6 years in light of the impacts on N inputs (Table 6).  At Wagga, despite the N legacy effects of the lupin reducing the overall N inputs, the lower profitability of the lupin itself (average yield 3.1 t/ha) compared with the barley (average yield 6.0 t/ha) in the system was the major driver of the lower $GM of the Diverse system (Table 6).  A somewhat similar outcome occurred at Condobolin, although the boost in canola $GM offset the lower profitability of the lupin compared with the barley.  The fababean in the Diverse system at Greenethorpe (average yield 4.4 t/ha) and Urana (average yield 4.7 t/ha) were as profitable or significantly more profitable than the wheat (average yield 5.4 t/ha) or barley (average yield 6.2 t/ha) in the Baseline systems at those sites, and there were also higher $GM in the following canola and wheat crops following the fababean.

In summary, the reduced N fertiliser input costs in the Diverse systems due to low N applied to the legume crops and reduced N applied to subsequent canola and wheat crops due to legacy N has contributed to the $GM of the Diverse systems much more than increased yield of subsequent crops following the legumes.  The exception was at Urana where the canola following fababean had an increase in $GM of $257.  However the lower profitability of lupin compared to barley has eroded that economic advantage at Wagga and Condobolin, while the higher profitability of fababean has added to the economic advantage at Greenethorpe, and especially at Urana.

Table 6. Average annual 6-yr gross margins for individual crops in the grain-only Baseline N2 (barley-canola-wheat) and Diverse N2 (legume-canola-wheat) systems from 2018 to 2023.

System

Crop sequence

Average annual $GM ($/ha/yr) 2018-2023

Cereal/Legume

Canola

Wheat

Mean

Wagga Wagga

Baseline

B-C-W

1103

838

764

901

Diverse

Lu-C-W

800

812

794

802

Greenethorpe

Baseline

W-C-W

1094

1034

1195

1107

Diverse

Fa-C-W

1058

1228

1252

1179

Urana

Baseline

B-C-W

1089

475

884

816

Diverse

Fa-C-W

1301

732

942

992

Condobolin

Baseline

B-C-W

818

771

752

780

Diverse

Lu-C-W

604

834

752

730

Do legacies occur with higher fertiliser strategies?

At two sites (Wagga and Greenethorpe) Baseline systems were included with both decile 2 and decile 7 strategies (see Table 3).  The question arises as to whether there is evidence that the higher N applied each season to the N7 treatment that is not used by the crop, carries over to subsequent crops in the same way that legume N carries over.

At Wagga there was an average of +33, +20 and +39 extra kg N/ha/yr measured pre-sowing in the N7 compared to the N2 prior to the canola, wheat and barley respectively, an average of +31 kg N/ha for the system.  This compares with an extra 50 kg N/ha/yr applied to the N7 treatment (Table 3).  At Greenethorpe there was an average of +46, +117 and +9 extra kg N/ha/yr measured pre-sowing in N7 compared to N2 prior to the canola, wheat 1 and wheat 2 crops respectively.  This compares with an extra 41 kg N/ha/yr applied in the N7 treatment (Table 3).  This suggests that a significant portion of the increased N applied that may not be utilised by the crops can carry over as legacy N within the system, although in this case it has only generated a small increase in $GM but a lower ROI within the systems (Table 3).  A more complete N balance will be carried out to provide more detail on the fate of the applied N in terms of offtake, changes in soil organic matter or N losses.

Whole-farm and business considerations

The results at the four sites demonstrate that a range of different systems with relatively small differences in average annual gross margin over 6 years can be quite profitable but may differ in performance in different seasons (wet, dry) and have different risk profiles.  This reminds us that different systems may suit specific businesses depending on a range of factors other than the agronomic management - many of which cannot be measured in these small-scale experiments but must be considered when making decisions to integrate grain legumes into the business.  For example, it is likely that to ensure the best outcome from grain legumes that some storage capacity may be required on farm, the capacity to handle the inoculation process in a timely and effective manner, and careful and timely application of fungicides in wetter seasons. These will generate labour peaks and demand on machinery that must be considered.  Enterprises with significant areas of legume-based pastures may find that these can perform much the same function of organic N supply, disease and weed management as that played by grain legumes in the systems reported here and are suited to phased rotation with more intensive cereal-canola systems. The choice of legume is also clearly important based on those best adapted to specific paddocks.

Never-the-less, the emerging data from these systems experiments demonstrate the importance of fully assessing the value of grain legumes in different systems beyond their performance in individual years, as much of the benefit derives from legacy effects, input savings and more even performance across seasons.  These are difficult to assess without longer-term side-by-side comparisons and supporting data to understand the mechanisms behind the responses.

Acknowledgements

The research undertaken as part of this project is made possible by the significant contributions of growers through both trial cooperation and the support of the GRDC and NSW DPI, the author would like to thank them for their continued support. The authors would like to especially thank Warakirri Cropping “Karoola Park” and Rod and Nick Kershaw “Iandra Pastoral” for their support and co-operation in hosting the Urana and Greenethorpe field experimental sites. The authors would also like to acknowledge the contributions of Graeme Sandral for his role as site leader during the first two and a half seasons of the project. We also thank Chris Baker (Baker Ag Advantage), Tim Condon (Delta Agribusiness), Greg Condon (Grassroots Agronomy), Heidi Gooden (Delta Agribusiness), Peter Watts (Elders), Rod and Nick Kershaw (Iandra), John Stevenson (Warakirri Cropping) and John Francis (Agrista) for the many useful discussions in their role on the project advisory committee.

References

Kirkegaard J, Dunn M, Swan T, Whish J, Pumpa R, Fiske K (2023) Farming systems profit and risk over time:  the impact of three wet consecutive seasons. GRDC Updates Wagga Wagga 2023.

Dunn M, Kirkegaard J, Swan T, Whish J, Pumpa R, Fiske K (2023) Legacy effects and the value of legumes in the farming system after three consecutive wet seasons. GRDC Updates Wagga Wagga 2023.

Kirkegaard J, Swan T, Dunn M, Sandral G, Whish J, Berary M, Reardon D, Woodsford-Smith A, Friske K,  Pumpa R (2022) Farming systems performance at a ‘macro’ scale: effects of management strategies on productivity, profit, risk, WUE GRDC Update Wagga Wagga 2022.

Swan T, Dunn M, Kirkegaard J, Goward L, Leighton E, Sandral G, Hunt J, Bullock M, Pumpa R, Fiske K, Woodford-Smith A, Reardon D, Barry M, Burns H (2022). What is the N legacy following pulses for subsequent crops and what management options are important to optimise N fixation? GRDC update, Wagga Wagga 2022.

Kirkegaard J, Swan T, Dunn M, Sandral G, Whish J, Leighton E, Reardon D, Bullock M, Friske K, Pumpa R (2021) Managing water and N across years and crop sequences to drive profit. GRDC Updates Wagga Wagga 2021.

Flohr BM et al., (2020) Deep Soil Water-Use Determines the Yield Benefit of Long-Cycle Wheat. Frontiers in Plant Science 11, 548 doi: 10.3389/fpls.2020.00548.

Contact details

John Kirkegaard
CSIRO Agriculture and Food
Canberra
0458 354 630
john.kirkegaard@csiro.au

GRDC Project Code: CSP1703-007RTX, CSP2110-004RMX,