A field trial was undertaken in 2019 to investigate combinations of faba bean sowing time, seed rate and herbicide treatments to control annual ryegrass. ARG plant density was significantly influenced by the time of sowing (P<0.001), herbicide treatment (P<0.001) and the interaction between the time of sowing and herbicide (P=0.012). The 3 week delay in seeding faba beans had no impact on ARG plant density, as shown by the similar ARG density in the simazine + trifluralin treatment. However, POST clethodim and butroxydim had much greater efficacy in the 2nd time of sowing (TOS 2) than in the TOS 1. The same trend was evident in ARG seed set when crop seeding was delayed. In the Simazine + Trifluralin (IBS) treatment there was only an 8% reduction in ARG seed production when seeding was delayed. However, Simazine + Trifluralin (IBS) fb Clethodim had a 62% reduction in ARG seed production in TOS 2 than in TOS 1. ARG seed production was also strongly influenced by faba bean seed rate (P<0.001). The high faba bean seed rate had 43% less ARG seed set compared to the low faba bean seed rate. This result indicates that faba beans can be highly competitive with ARG at the high seed rate. Faba bean grain yield was significantly influenced by crop seed rate (P<0.001), with the high seed rate yielding 14% and 30% higher than the medium and low seed rates, respectively. Herbicide treatment had a significant effect on faba bean grain yield. When POST clethodim was applied after the Simazine + Trifluralin IBS (1.55 t/ha), faba bean grain yield improved by 43% to 2.211 t/ha. Crop yield responses to herbicides treatments were consistent with their efficacy on ARG, which highlights the sensitivity of faba bean grain yield to weed competition. This study has shown that at high plant density, faba beans can provide a significant suppression of ARG. However, faba beans were very intolerant to weeds as shown by the large yield losses. Higher seed rates, are important to both increase competitiveness of faba beans in suppressing ARG, and to also maintain grain yield. However, fungal disease management would need to be monitored and managed effectively.

A field trial was undertaken near Winchelsea, VIC to investigate the effect of faba bean sowing time, seed rate and herbicide treatments on annual ryegrass (ARG) control. ARG plant density was unaffected by the seeding date but was significantly influenced by the herbicide treatments. The results of seed production were somewhat surprising. As expected in such a long growing season, the use of pre-emergent treatment of Simazine + Triflur X IBS was unable to provide adequate weed control and resulted in the highest ARG seed set. The results also show that the post-emergent application of Select and Factor were relatively ineffective when used in TOS 1. However, the post-emergent treatments were highly effective in TOS 2. Previous research has shown reduction in the efficacy of these herbicides under cold and frosty conditions as in this study. Crop seed rate had a significant effect on faba bean grain yield (P<0.001) but time of sowing did not influence grain yield (P=0.61). Grain yield increased significantly as seed rate increased from low (4.65 t/ha), medium (5.96 t/ha) to high seed rate (6.51 t/ha). At this high rainfall site, simply relying on pre-emergence herbicides proved inadequate. Simazine + Triflur X had a significantly lower grain yield than faba beans sprayed with a combination of pre- and post-emergence herbicides. Even though the highest ARG plant density present at the site was 33 plants/m2, it was quite competitive with the crop (P=0.01) and reduced its yield by 0.4 t/ha as compared to the treatments where Select or Select + factor were used as post-emergent treatments.

A field trial was undertaken at Washpool in 2019 to investigate combinations of wheat sowing time, seed rate and herbicide treatments to control annual ryegrass. The average seedbank of annual ryegrass (ARG) at the site was 2249 ± 284 seeds/m2. There was no evidence at this site of any reduction in ryegrass infestation in wheat by delaying sowing by three weeks between TOS 1 (77plants/m2) and TOS (74plants/m2). This result suggests the Washpool ARG population likely has a high level of seed dormancy, reducing the rate of ryegrass germination after the opening rainfall events. Herbicide treatment had a significant influence on ARG plant density (P<0.001). Boxer gold and Sakura + Avadex reduced ARG plant density by 45% and 73% from the untreated control (125 ARG plants/m2). Wheat was much more competitive against ARG when it was sown early. This was made evident by the large increase in ARG seed production when seeding was delayed. When averaged across all other treatments TOS 1 produced 1634 ARG seeds/m2, which was 73% lower than 5974 ARG seeds/m2 produced in TOS 2 (P=0.013). Wheat seed rate had a significant influence on ARG seed production (P=0.005), with the high wheat seed rate supressing ARG seed production by 37% when compared to the lowest wheat seed rate (100 seeds/m2). Wheat grain yield at this site was significantly influenced by the time of sowing (P=0.001), seed rate (P=0.001), herbicide treatments (P=0.001), and the interaction between the time of sowing and herbicides (P=0.011). Wheat was much more tolerant to ryegrass competition when sown early (TOS 1) as shown by the small increase in grain yield in herbicide treated plots. In contrast, there was a significant increase in wheat grain yield in herbicide treatments in TOS 2. The results of this study clearly show that delayed sowing of wheat allows for greater seed set by ryegrass and is also associated with a large yield penalty.

A field trial was undertaken in 2020 to investigate combinations of wheat sowing time, seed rate and herbicide treatments to control annual ryegrass. Increase in wheat seed rate from 100 to 200 seeds/m2 caused a significant reduction in ARG spikes and seed set. The level of additional weed suppression from higher wheat seed rate ranged from 30-35%. As expected, both pre-emergent herbicides caused a significant reduction ARG plant density, spikes and seed production. Even though there was a general trend for Sakura to be slightly more effective than Boxer Gold, these differences were non-significant. It is somewhat disconcerting to note that even with the use of the tank mix of Sakura + Avadex Xtra, ARG was able to set more than 34,000 seeds/m2. These results highlight the need for integrating multiple weed control tactics to drive down the populations of this resilient weed. Wheat grain yield at Roseworthy ranged from 1.85 t/ha to 3.48 t/ha and with a site mean across all treatments of 2.773 t/ha. Time of sowing wheat did not have a significant effect on wheat grain yield in 2020 (P=0.168). However, wheat grain yield was significantly influenced by crop seed rate (P=0.023) and herbicide treatments (P=0.001). There was no interaction between these management factors. As seed rate increased from 100 to 200 seeds/m2, wheat grain yield steadily increased by 15%. Herbicide treatments had a highly significant (P<0.001) effect on wheat grain yield in this trial, which was not surprising considering the high ARG seedbank and weed density. Application of Boxer Gold and Sakura + Avadex Xtra increased wheat yield by 41% and 54% compared to the untreated control.

• Summary of 1 year.
• Cu fertiliser previously drilled with wheat appeared more availalble  than current drilled.
• CuSulfate @ 5.5  kg/ha gave maximum dry matter yield.
• Zn & Mo basalled for clover growth.
• Cu  at 5.5 kg Cu sulfate gave maximum yield of barley in year 2..
• Copper deficiency of wheat, barley and poor clover growth has been recorded by many farmers.
•  

• Cu & Zn either separately or in combination increased grain yield.
• Combination of 11 Kg Cu sulfate and 3.3 kg ZnO recommended
• Follow with a combination of 5.5  Kg Cu sulfate and 1.6 kg ZnO recommended in following crops.
• No information on Zn depressing yield with nil or low rates of Cu.

• Neither Cu or Zn added to superphosphate increased grain yield.  Nil Cu & Nil Zn gave maximum grain yield.
• Zinc oxide at 3.3 kg/ha did not reduced yield of wheat with Cu.
• Cu application gave  no yield increase or decrease without Zn applied.
• No combination of Cu sulfate and kg Zn oxide required.
• Plainsuperphosphate gave higher yield than aerophos+gypsum gave maximum yield.
• .

• Cu increased with or without Zn added to superphosphate.  
• Zn depressed yield when Cu was 5.5 or below (0 & 2.75)
• Higher the Zn rate the greater the depression..
• Combination of Cu sulfate (5.5 kg Cu sulfate) and nil kg Zn oxide required.
• Or Cu 2.75 kg Cu sulfate & nil Zn gave maximum yields.
• Highest ZnO (3.3 kg/ha), particularlym at 0 & lowest Cu level (2.75 kg Cu sulfate/ha)
• Plain superphosphate gave same yield as aerophos+gypsum.
• .

• Cu increased with or without Zn added to superphosphate.  
• Zn depressed yield when Cu was 5.5 or below (0 & 2.75)
• Higher the Zn rate the greater the depression..
• Combination of Cu sulfate (5.5 kg Cu sulfate) and nil kg Zn oxide required.
• Or Cu 2.75 kg Cu sulfate & nil Zn gave maximum yields.
• Highest ZnO (3.3 kg/ha), particularlym at 0 & lowest Cu level (2.75 kg Cu sulfate/ha)
• Plain superphosphate gave same yield as aerophos+gypsum.
• .

• 2 experiments in region on the same soil type.
• Cu increased with or without Zn added to superphosphate.  
• Zn markedly depressed yield when nil Cu. Depression smaller for 2.75 & 5.5 kg Cu sulfate /ha.
• Highest the Zn rate (3.3 Kg ZnO/ha) the greater the depresion
• Combination of Cu sulfate (2.75 kg & 5.5 Cu sulfate) and nil kg Zn oxide required for maximum grain yield.
• Plain superphosphate (PS) gave higher grain yield than aerophos+gypsum (AG)
• AS PS >AG indicates Zn wouls be required for oats or Clover.
•  
• .

• Cu & Zn either separately or in combination increased grain yield.
• Zn deficiencies seen in wheat.
• Combination of 11 Kg Cu sulfate and 3.3 kg ZnO recommended
• Follow with a combination of 5.5  Kg Cu sulfate and 1.6 kg ZnO recommended in following crops
•  

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn depressed yield when no  Cu.
• Combination of Cu sulfate (.2.75 kg Cu sulfate) and nil  KgZno /ha required for maximum yields.
• .Best combination of the soil type for both 1967 & 1967 Cu Sulfate at 2.75  and nil  ZnO/ha

• Trend to higher grain yield with increasing Cu & Zn levels
•  Zn O at 0.8 kg/ha supplied enough Zn for maximum grain yield.
• Combination of Cu sulfate with  KgZnO /ha required for maximum yields. Howver, Cu level required could not be determined.
• .Best combination of the soil type for both 1966 & 1967 suggest  that Cu Sulfate at 5.5 -8.25 kgCusulfate   and 0.8  ZnO/ha would be best for the soil type.

• Cu increased grain yield in the absence or presence of Zn.
• Zn application depressed grain yield at lower rates of Cu (nil & 2.75 kg Cu sul/ha).
• Zn increased grain yield with 5.5 & 8.25 kg Cusul/ha
• Combination of Cu sulfate (5.5 &m 8.25 kg Cu sulfate) and 1.6 KgZnO /ha  gave for maximum yield.
• Plain superphosphate yield same as  Aerophos +gypsum.
•  

• Cu increased grain yield in the absence or presence of Zn.
• Zn application depressed grain yield at lower rates of Cu (nil & 2.75 kg Cu sul/ha).
• Zn increased grain yield with 5.5 & 8.25 kg Cusul/ha
• Combination of Cu sulfate (5.5 &m 8.25 kg Cu sulfate) and 1.6 KgZnO /ha  gave for maximum yield.
• Plain superphosphate yield same as  Aerophos +gypsum.
•  

• Cu increased grain yield with & without Zn
• Combination of 5 Cu levels and 4 ZnO [ incomplete factorial].
• Cu application increased grain yield by 50 -100%.
• Zn depressed yield at nil Cu
• Combination of Cu sulfate (2.75kg Cu sulfate) and nil Zn
• 0.6 - 1.0 Kg ZnO /ha for  maximum yield of oats, clover & linseed.

• General location only as 3 experiments are summarised for 1960's.
• Combination of 4 Cu levels and 3 ZnO.
• Cu application increased grain yield by 50%
• Zn depressed grain yield at nil Cu
• Combination of Cu sulfate 8.25 kg Cu sulfate) and 2.75 Kg ZnO /ha  gave for the same maximum yield.
• Suggested a further application of 5.5 kg Cu sulfate & 1.6 kg ZnO may be benficial.

• General location only as 8 experiments are summarised for 1967.
• Trials over 1965-1967 
• Combination of 4 Cu levels and 3 Zn [0.8 kg ZnO ommitted].
• Summary of  8 experiments with 4 Cu and 3 Zn levels sandy and gravelly laterite derived soils
• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 35 - 50%
• Zn depressed grain yield at nil Cu and 2.75 kg Cu Sulfate/ha
• Combination of Cu sulfate (2.75kg Cu sulfate) and nil KgZnO /ha  gave for the same maximum yield.as 5.5 kg Cu Sulfate & 0.8 kg ZnO/ha
•  

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn depressed yield when no  Cu, 2.75 & 5.5 Kg/ha had been applied.
• With Zn nil and 0.8 kg Zn O Cu at 5.5 kgCu sul/ha gave maximum yield grain yield.Sulfate gave higher yield.
• For wheat, combination of Cu sulfate (5.5 kg Cu sulfate) and nil  KgZno /ha required for maximum yields.
• Zn deficiency symptoms seen extensive in wheat grown on Aerophos + gypsm  
• Plain superphosphate yield higher than Aerophos +gypsum suggested  Zn soil is marginal and Zn addition (0.8 kg/ha) recommended for Oats and Clover.

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn depressed yield when no  Cu, 2.75 & 5.5 Kg/ha had been applied.
• With Zn nil and 0.8 kg Zn O Cu at 5.5 kgCu sul/ha gave maximum yield grain yield.Sulfate gave higher yield.
• For wheat, combination of Cu sulfate (5.5 kg Cu sulfate) and nil  KgZno /ha required for maximum yields.
• Zn deficiency symptoms seen extensive in wheat grown on Aerophos + gypsm  
• Plain superphosphate yield higher than Aerophos +gypsum suggested  Zn soil is marginal and Zn addition (0.8 kg/ha) recommended for Oats and Clover.

• General location only as 15 experiments are summarised.
• Summary of 15 experiments with 4 Cu and 4 Zn levels sandy and gravelly laterite derived soils
• Cu increased grain yield in the absence or presence of Zn.
• Zn depressed grain yield at nil Cu
• Combination of Cu sulfate (2.75 &  5.5 kg Cu sulfate) and 0.8 KgZnO /ha  gave for maximum yield.
•  

• General location only as 15 experiments are summarised for 1965.
• Summary of 15 experiments with 4 Cu and 4 Zn levels sandy and gravelly laterite derived soils
• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 50%
• Zn depressed grain yield at nil Cu
• Combination of Cu sulfate (2.75 &  5.5 kg Cu sulfate) and 0.8 KgZnO /ha  gave for maximum yield.
•  

• General location only as 15 experiments are summarised for 1967.
• Trials over 1965-1967 
• Combination of 4 Cu levels and 3 Zn [0.8 kg ZnO ommitted].
• Summary of 15 experiments with 4 Cu and 3 Zn levels sandy and gravelly laterite derived soils
• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 50%
• Zn depressed grain yield at nil Cu
• Combination of Cu sulfate (2.75kg Cu sulfate) and nil KgZnO /ha  gave for the same maximum yield.as 8.25 kg Cu Sulfate & 3.3 kg ZnO/ha
•  

• General location only as 5 experiments are summarised for 1967.
• Trials over 1965-1967 
• Combination of 4 Cu levels and 4 ZnO.
• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 30-50%
• Zn depressed grain yield at nil Cu
• Combination of Cu sulfate (2.75kg Cu sulfate) and nil KgZnO /ha  gave for the same maximum yield.as 8.25 kg Cu Sulfate & 3.3 kg ZnO/ha
•  

• General location only as 3 experiments are summarised for 1967.
• Trials over 1965-1967 
• Combination of 4 Cu levels and 4 ZnO.
• Cu application increased grain yield by 30-50%
• Zn depressed grain yield at nil Cu
• Combination of Cu sulfate (2.75kg Cu sulfate) and 0.8 Kg ZnO /ha  gave for the same maximum yield.

• Neither Cu & Zn separately nor in combination increased grain yield

• Neither Cu & Zn separately nor in combination increased grain yield

• Cu & Zn either separately or in combination increased grain yield.
• Zn deficiencies seen in wheat during 1968.
• Combination of 2.75 Kg Cu and 0.8 kg ZnO recommended

• General location only as 3 experiments are summarised for 1960'.
• Combination of 4 Cu levels and 4 ZnO.
• Cu application increased grain yield by 30-50%
• Combination of Cu sulfate (5.5kg Cu sulfate) and 2.75 Kg ZnO /ha for  maximum yield.

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn depressed yield when no  Cu.
• At 2.75 & 5.5 kg Cu sulfate /ha, 1.6 & 3.3 kg Zn oxide depressed grain yield 
• Combination of Cu sulfate (.8.25kg Cu sulfate) and 1.6 KgZno /ha required for maximum yields.
• .Best combination of the soil type for both 1967 & 1967 Cu Sulfate at 5.5 and ).8 kg ZnO/ha

• Cu increased Grain yield in the absence or presence of Zn.
• Zn application depressed grain yield at lower rates of Cu.
• Combination of Cu sulfate (5.5 kg Cu sulfate) and nil  KgZnO /ha  gave for maximum yield.
• Plain superphosphate yield same as  Aerophos +gypsum.
• Suggest soil was adequate for grain yield of wheat.
• Suggested soil Zn would be adequate for barley and clover.

• Cu increased Grain yield in the absence or presence of Zn.
• Zn application depressed grain yield at lower rates of Cu (nil & 2.75 kg Cu sul/ha).
• Combination of Cu sulfate (2.75 kg Cu sulfate) and nil  KgZnO /ha  gave for maximum yield.
• Plain superphosphate yield same as  Aerophos +gypsum.
• Suggest soil Zn was adequate for grain yield of wheat.
•  

• Trend to higher grain yield with increasing Cu & Zn levels
• Cu at 2.75 Cu sul/ha & Zn O at 1.6 kg/ha supplied enough Zn for maximum grain yield.
• .Best combination of the soil type for both 1966 & 1967 appeat to be inconsistent for the soil type.
• Researchers suggest the combination to cover future crops and the suggest there is a long residual value.in mid-1960's residual value was about 5 years.

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn depressed yield when no  Cu had been applied.
• Zn O at 3.3 kg/ha depressed grain yield with 5.5 or less kg/ha Cu sulfate
• Combination of Cu sulfate (2.75 & 5.5 kg Cu sulfate) and nil  KgZnO  /ha Cu 5.5 and ZnO 1.6 kg/ha required for maximum yield.
• Plain superphosphate yield same as  Aerophos +gypsum.

• Zn application gave varying results in grain yield
• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn depressed yield when no  Cu had been applied.
• Zn O at 3.3 kg/ha depressed grain yield with 5.5 or less kg/ha Cu sulfate
• Combination of Cu sulfate (2.75 & 5.5 kg Cu sulfate) and nil  KgZnO  /ha Cu 5.5 and ZnO 1.6 kg/ha all gave for maximum yield.
• Plain superphosphate yield same as  Aerophos +gypsum.

• Cu increased with Zn added to superphosphate.  
• Zn depressed yield when no  Cu was applied
• Higher the Zn rate the greater the depression at nil Cu..
• Combination of Cu sulfate (2.75 kg Cu sulfate) and 0.8 kg Zn oxide required for maximum yields.
• Plain superphosphate (PS) gave greater yield than aerophos+gypsum (AG).
• PS grester than AG indicates Zn is reqired for oats and a clover ley.
• .

• Cu increased with Zn added to superphosphate.  
• Zn depressed yield when no  Cu was applied
• Higher the Zn rate the greater the depression at nil Cu..
• Combination of Cu sulfate (2.75 kg Cu sulfate) and 0.8 kg Zn oxide required for maximum yields.
• Plain superphosphate (PS) gave greater yield than aerophos+gypsum (AG).
• PS grester than AG indicates Zn is reqired for oats and a clover ley.
• .

• Cu increased with Zn or without Zn added to superphosphate.  
• Zn depressed yield when no  Cu or where 2.75 kg Cu sulfate /ha was applied
• Higher the Zn rate the greater the depression at nil Cu..
• At 5.5 & 8.25 kg Cu sulfate /ha, 1.6 & 3.3 kg Zn oxide depressed grain yield 
• Combination of Cu sulfate (2.75 kg Cu sulfate) and nil Zn oxide or 5,5 kg Cusulfate and 0.8 KgZno /ha required for maximum yields.Comments combinations are not significantly different
• Plain superphosphate (PS) gave greater yield than aerophos+gypsum (AG).
• PS grester than AG indicates Zn is reqired for oats and a clover ley.
• .

• Cu application no effect on grain yield without Zn.
• Zn application depressed grain yiled without Cu
• With Zn applied Cu application restored grain yield
• Cu at 2.75 Cu sul/ha & Zn O at 0.8 kg/ha supplied enough Zn for maximum grain yield.
• .Researchers suggest the combination to cover future crops and the suggest there is a long residual value.in mid-1960's residual value was about 5 years.

• Cu application no effect on grain yield without Zn.
• Zn application depressed grain yiled without Cu
• With Zn applied Cu application restored grain yield
• Cu at 2.75 Cu sul/ha & Zn O at 0.8 kg/ha supplied enough Zn for maximum grain yield.
• .Researchers suggest the combination to cover future crops and the suggest there is a long residual value.in mid-1960's residual value was about 5 years.

• Zn application gave varying results in grain yield
• Cu increased with Zn or without Zn added to superphosphate.  
• Combination of Cu sulfate (8.25 kg Cu sulfate) and nil  KgZnO  /ha  gave for maximum yield.
• Plain superphosphate yield same as  Aerophos +gypsum.

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn depressed yield when no  Cu had been applied.
• Combination of Cu sulfate (2.75 kg Cu sulfate) and nil  KgZno /ha required for maximum yields.
• .Best combination of the soil type for both 1967 & 1967 Cu Sulfate at 2.75  and nil  ZnO/ha.
• Plain superphosphateyield higher than Aerophos +gypsum suggested  Zn soil is marginal and Zn addition recommended for Oats and Clover.

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn levels may have aslight depression on yield with nil Cu 2.75 & 5.5 Cu levels, particularly 3.3 kg /ha of ZnO application.
• Combination of Cu Sul at 5.5 kg/ha and nil  kg/ha ZnO or 8.25 kg Cu/ha& 1.6 kg/ha ZnO was required for maximum yield.
• Plain superphosphate out yielded  Aerophos +gypsum suggested  Zn soil was inadequat for oats and or clover.

• Cu increased  graiin yield with  all Zn.
• No depression of 3.3 kg ZnO on grain yield across Cu levels
• Concluded that Cu sulfate at 2.75 kg/ha and ZnO @ 0.8 kg /ha .
• Plainsuperphosphate gave higher yield than aerophos + gypsum Zn addition required for grain yield of oats and also clover growth..

• Cu increased  graiin yield with  all Zn.
• No depression of 3.3 kg ZnO on grain yield across Cu levels
• Concluded that Cu sulfate at 2.75 kg/ha and ZnO @ 0.8 kg /ha .
• Plainsuperphosphate gave higher yield than aerophos + gypsum Zn addition required for grain yield of oats and also clover growth..

• Inconsistent graiin yield with Cu & Zn.
•  

• Inconsistent graiin yield with Cu & Zn.
• Inconsistent depression of 3.3 kg ZnO on grain yield across Cu levels although ZnO 3.3 depressed yield of Nil Cu and 2.75 kg Cu sulfate /ha.
• Concluded that grey clay [moort clays] may not need Cu or Zn.
• Zn in plainsuperphosphate may be adequate for grain yield.

• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 30-40%
• Zn depressed grain yield at nil Cu
• Combination of Cu sulfate (2.75 kg & 5.5 kg Cu sulfate) and 0.8 KgZnO /ha  for maximum yield on gravel sites.
• General conclusion for soil ttype was 5.5 kg Cu sulfate and 0.8 kg ZnO
• General conclusion similar results to yellowm-brown gravel  of the central wheatbelt of WA.

• Neither Cu or Zn increased grain yield.  Nil Cu & Nil Zn near maximum grain yield.
• Zinc oxide at 3.3 kg/ha did reduced yield of wheat with Cu.
• Cu application gave  no yield increase or decrease without Zn applied.
• Combination of 2.75 kg Cu sulfate and 0.8 kg Zn oxide suggested as best combination although not different from the Nil treatments.
• Plainsuperphosphate and aerophos+gypsum gave maximum yield.
• .

• Neither Cu or Zn increased grain yield.  Nil Cu & Nil Zn near maximum grain yield.
• Zinc oxide at 3.3 kg/ha did reduced yield of wheat with Cu.
• Cu application gave  no yield increase or decrease without Zn applied.
• No combination of Cu sulfate and kg Zn oxide suggested as a best combination.
• Plainsuperphosphate and aerophos+gypsum gave maximum yield.
• .

• Neither Cu or Zn increased grain yield
• Zinc did not reduced yield of wheat with Cu nil. Cu application gave  no yield increase without Zn applied.
• Combination of 5.5 kg Cu sulfate and 8.25 kg Cu sulfate depressd yield.
• Plainsuperphosphate and aerophos+gypsum gave maximum yield.
• .

• Zinc reduced yield of wheat with Cu nil. Cu application gave a small yield increase without Zn applied.
• Combination of 5.5 kg Cu sulfate and 1.7 kg Zn oxide gace maximum yield.
• There was no evidence that further additions of Cu and Zn was needed in subsequent years.

• Neither Zinc or Cu increased grainyield alone
• Wheat required Cu & Zn applied together.
• Combination of 5.5 kg Cu sulfate and 1.7 kg Zn oxide gace maximum yield.
• There was no evidence that further additions of Cu and Zn was needed in subsequent years.

• Cu increased with Zn or without Zn added to superphosphate.  
•  ZnO application had no consistent effect on grain with Cu applied.
• Combination of Cu Sul at 5.5 kg/ha and  nil  ZnO was required for maximum yield.
• Plain superphosphate yielded  the same as Aerophos +gypsum suggested  Zn soil was adequate.

• General location only as 3 experiments are summarised for 1967.
• Trials over 1965-1967 ; covers a range of locations for the central wheatbelt area
• Summary of 3 experiments with 4 Cu and 4 Zn levels
• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 35 - 50%
• Zn depressed grain yield at nil Cu more in the gravels than sands
• Combination of Cu sulfate (5.5 kg Cu sulfate) and 1.6  KgZnO /ha  for maximum yield on gravel sites
• General conclusion 5.5 kg Cu sulfate and 0.8 kg/ha ZnO adequatefor sandy surfaced grey earths of the central wheatbelt of WA.

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn levels depressed yield with nil Cu other levels of ZnO application increased grain with Cu applied.
• Combination of Cu Sul at 5.5 kg/ha and 0.8 kg/ha ZnO was required for maximum yield.
• Plain superphosphate out yielded  Aerophos +gypsum suggested  Zn soil was inadequate.

• Concluded that Cu and Zn not required for wheat .
• Zn addition not required for grain yield of oats and also clover growth..

• General location only as 5 experiments are summarised for 1967.
• Trials over 1965-1967 ; covers a range of locations for the central wheatbelt area
• Combination of 4 Cu levels and 3 Zn [0.8 kg ZnO ommitted].
• Summary of  5 experiments with 4 Cu and 3 Zn levels sandy
• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 35 - 50%
• Zn depressed grain yield at nil Cu.
• Combination of Cu sulfate (2.75kg Cu sulfate) and nil KgZnO /ha  gave the same maximum yield.

• Cu increased with or without Zn added to superphosphate.  
• Zinc oxide increased yield of wheat with Cu (2.75 & 5.5  Kg Cu sulfate/ha).
• Combination of Cu sulfate (5.5 kg Cu sulfate) and 0.8 kg Zn oxide required.
• Plain superphosphate gave higher yield than aerophos+gypsum.
• .

• Summary of 2 experimental sites 
• Cu increased with or without Zn added to superphosphate.  
• Zinc oxide increased yield of wheat with Cu (2.75 & 5.5  Kg Cu sulfate/ha).
• Combination of Cu sulfate (5.5 kg Cu sulfate) and 0.8 kg Zn oxide required.
• Plainsuperphosphate gave higher yield than aerophos+gypsum.
• .

• Summary of 2 experimental sites 
• Small additions of Cu or Zn added to superphosphate increased grain yield.  
• Zinc oxide at 3.3 kg/ha did  reduced yield of wheat with Cu (0 & 2.75 Kg Cusulfate/ha).
• Cu application at 8.25 kg Cusulfate without Zn applied decreased grain yield.
• Combination of Cu sulfate (2.75 kg Cu sulfate) and 0.8 kg Zn oxide required.
• Plainsuperphosphate gave higher yield than aerophos+gypsum gave maximum yield.
• .

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn levels followed no consistent pattern some depressed yield other levels of ZnO application increased.
• Concludedd Zn application not real & Zn had no clear reffect on grain yield.
• Combination of Cu Sul at 2.75 kg/ha and nil ZnO was requyired for maximum yield.
• Plain superphosphate yield was the sane as Aerophos +gypsum suggested  Zn soil was adequate; hence no further Zn was recommended for Oats and Clover.

• Cu increased with Zn or without Zn added to superphosphate.  
• All Zn levels depressed yield with nil Cu 2.75 & 5.5 Cu levels, particularly 3.3 kg /ha of ZnO application.
• Combination of Cu Sul at 5.5 kg/ha and nil  kg/ha ZnO or 2.75 kg Cu/ha nil Zn was required for maximum yield.
• Plain superphosphate out yielded  Aerophos +gypsum suggested  Zn soil was inadequat for oats and or clover.

• Summary of 2 experiments
• Nil Cu and Nil Zn gave equal top yield.  
• Even without Zn, CuSulfate @2.75 kg/ha slight nonsignificant increase in the growing season.
• Zn addition decrease wheat yield with no added Cu.
• Cu  at 2.75 kg Cu sulfate gave maximum yield.
• Copper deficiency of wheat and barley have been recorded in trials and farmer paddocks.
• Aerophos and plain superphosphate treatments were not significantly different.

• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 50-60%
• Zn depressed grain yield at nil Cu and in all Cu applications
• Combination of Cu sulfate (2.75 kg Cu sulfate) and nil KgZnO /ha  for maximum yield on gravel sites
• General conclusion similar results to yellowm-brown gravel  of the central wheatbelt of WA.

• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 50-60%
• Zn depressed grain yield at nil Cu and in all Cu applications
• Combination of Cu sulfate (2.75 kg Cu sulfate) and nil KgZnO /ha  for maximum yield on gravel sites
• General conclusion similar results to yellowm-brown gravel  of the central wheatbelt of WA.

• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 50-60%
• Zn depressed grain yield at nil Cu and in all Cu applications
• Combination of Cu sulfate (2.75 kg Cu sulfate) and nil KgZnO /ha  for maximum yield on gravel sites
• General conclusion similar results to yellowm-brown gravel  of the central wheatbelt of WA.

• Nil Cu and Nil Zn gave equal top yield.   Zinc addition reduced yield of wheat with Cu nil. 
• Combination of 2.75 kg Cu sulfate and 1.7 kg Zn oxide gave maximum yield. The increase with 2.75 kg/ha Cu sulfate was about the same magnitude  caused by Zn addition where nil Cu was applied. Zn did not depress yield where Cu was applied.
• There was no evidence that further additions of Cu and Zn was needed for wheat in subsequent years.

• Summary of 2 experiments
• Nil Cu and Nil Zn gave equal top yield.  
• Combination of 2.75 kg Cu sulfate and 0.8 kg Zn oxide gave maximum yield.
• Copper deficiency of wheat and barley have been recorded in trials and farmer paddocks.
• Similarly, Zn deficiency in oats have been recorded in trials grown on yellow sands.

• General location only as 13 experiments are summarised for 1967.
• Trials over 1965-1967 ; covers a range of locations for the central wheatbelt area
• Gravelly sites only slightly more affected by Cu deficiency than sandy sites.
• Summary of 13 experiments with 4 Cu and 4 Zn levels
• Cu increased grain yield in the absence or presence of Zn.
• Cu application increased grain yield by 35 - 50%
• Zn depressed grain yield at nil Cu more in the gravels than sands
• Combination of Cu sulfate (8.25 kg Cu sulfate) and 1.6 or 3.3 KgZnO /ha  for maximum yield on gravel sites
• Zn nil or ZnO0.8 kg/ha Cu Sul 2.75 or 5.5 kg/ha on sandy sites
• General conclusion 5.5 kg Cu sulfate and 0.8 kg/ha ZnO adequatefor sandy and gravelly surfaced yellow earths of the central wheatbelt of WA.

• Cu & Zn either separately or in combination increased grain yield.
• Combination of 11 Kg Cu sulfate and 3.3 kg ZnO recommended
• Follow with a combination of 5.5  Kg Cu sulfate and 1.6 kg ZnO recommended in following crops.
• No information on Zn depressing yield with nil or low rates of Cu.

• Zinc reduced yield of wheat with Cu nil. Cu application gave a small yield increase without Zn applied.
• Cu & Zn apploication both required for maximum grain yield.
• Combination of 5.5 kg Cu sulfate and 1.7 kg Zn oxide grain maximum yield.
• ZnO and 1.7 kg/ha required for maximum pasture and Oat yield.
• There was no evidence that further additions of Cu and Zn was needed in subsequent years.

• Zinc reduced yield of wheat with Cu nil. Cu application gave a small yield increase without Zn applied.
• Combination of 5.5 kg Cu sulfate and 1.7 kg Zn oxide gace maximum yield.
• There was no evidence that further additions of Cu and Zn was needed in subsequent years.

• Plants grown in small pots containing Mn deficient calcareous (pH 8.5, 80% CaCO3) sand collected from Wangary, S.A with 0-50 ppm added Mn in growth room at 15°C.
• Plants harvested at approx. 4 weeks (early tillering). Also 30 wheat cultivars were screened at Wangary using plant breeders' plots (4 rows x 5 m) with a split plot application of foliar MnSO (1 kg/ha ).
• Effects of seed soaking were evaluated for wheat and barley by soaking for 6 h with 1.5% MnSO4 prior to sowing.
• Without Mn, all cultivars showed no differences in growth and Mn uptake at 4 weeks (pots) but significant differences at 8 weeks in the field. With Mn supplied either in soil or on seed large cultivar differences were apparent at 4 weeks.
• Conclude that use of Mn efficient varieties coupled with a suitable seed Mn content will lessen the need for Mn fertilisers.

• Deep ripping to 500mm increased plant biomass, tiller numbers and ultimately yield, by 500kg/ha
• There was no significant difference in weed numbers between ripped and un-ripped treatments; however, weeds in the deep ripping treatment were bigger and had more seeds, therefore potentially a greater seed bank.
• The root lesion nematode species P. neglectus population increased over the season with a ten times higher increase in un-ripped compared to ripped soil. 

• Baiting with metaldehyde baits resulted in approximately 50-60% mortality.
• Baits had most effect on snails larger then 6mm.
• This trial highlight the need for further research into the growth rates and fecundity of snails under different environmental conditions and availability of sources of food and refuges.

• Grain yield and quality was significantly reduced in all varieties when harvest was delayed. Oxford and La TrobeA suffered least yield penalty, while BassA, and FathomA had the greatest yield losses.

• Yield losses and quality downgrades ranged from $75–300/ha in lost revenue in 2016, despite overall low prices and distinction between malt and F1 grades.

• Despite seed boron concentrations being very high (>20 mg/kg) there was no detectable effect on seedling emergence or growth.
• The amount of boron in the shoots was similar irrespective of the amount of boron in the grain.
• It would appear that grain boron is not mobilised to the developing seedling.

• Just 50 kg DAP/ha knife point drilled with 70 kg/ha wheat seed is enough to reduce wheat plant  establishment.
• Wheat fertilised with DAP with seed yielded 0.5 t/ha (20%) less than wheat with DAP placed below seed in 2016.
• The addition of 35 kg urea/ha below the seed overcame the yield penalty in the DAP-with-seed plots, suggesting access to N was a driver.

• Just 50 kg DAP/ha knife point drilled with 70 kg/ha wheat seed is enough to reduce wheat plant establishment
• Wheat fertilised with DAP with seed yielded 0.5 t/ha (20%) less than wheat with DAP placed below seed in 2016. 
• The addition of 35 kg urea/ha below the seed overcame the yield penalty in the DAP-with-seed plots, suggesting access to N was a driver.

• Blackleg infection of flowers, pods, branches and upper stems can be collectively termed as upper canopy infection (UCI).

• Early flowering of canola increases the risk of UCI.

• Fungicide can reduce disease levels and increase grain yield, but does not provide full disease control.

• Matching sowing date and varietal phenology so that flowering occurs in late winter will reduce UCI.

Responses to cutting treatments in Mackellar wheat and Breakwell triticale were examined in an early sowing (March).  Frost damage was severe and both uncut treatments produced significantly lower grain yields being at mid flowering (Breakwell) and late ear emergence (Mackellar) at the time of the frosts.  Grain yields did not tend to correlate with the number of ears per m2 or grain weight.  However for both varieties the higher yields of cut treatments related to the number of grains per ear.

For trial results please see the attached trial report.

Very dry conditions during the growing season and the inherent variability with the trial site requires the results to be viewed with caution.  However these results show grazing Yerong barley during the vegetative stage of growth will have no impact on grain yield and is likely to be beneficial.  The grazing benefits to the whole farm system are considerable and the small reduction in stubble mass, although not huge is a positive outcome.

Intensive grazing at GS 30 – GS 31 (start of stem elongation) reduced grain yield compared to no grazing by an average of 37%. The greatest yield loss of 57% occurred with Monstress triticale and the lowest yield loss occurred with Amarok wheat (18%). Up to 2.1 t/ha of drymatter was available for grazing before stem elongation was reached. Yerong barley yielded the greatest drymatter pre grazing, with Brennan wheat the lowest drymatter yielding at 1.5 t/ha.

• Heat stress during the reproductive development phase significantly reduced grain yield, harvest index and oil percentage.
• Varieties respond differently to heat stress: Nuseed Diamond had the highest reduction in grain yield and oil percentage under heat stress, whereas ATR Stingray had the lowest reduction in grain yield.
• Under heat stress, seed formation is more severely affected than pod formation.
• Canola pods that appear healthy can produce less, or even no, seed, and therefore do not achieve yield potential under heat stress.

• A preliminary experiment in 2017 showed that extra heat can be applied to canola plots successfully using specially designed heat chambers.

• Heat stress of four days, applied seven days after flowering started, significantly reduced the grain yield of the flowers opening during that period.

• Four days of heat stress significantly reduced harvest index and thousand seed weight at the plot level, however, grain yield and biomass yield was not affected due to recovery during cooler nights.

• Further research is needed to extend the duration and intensity of heat stress to show differences, and for rigorous validation across different varieties.

• Yield responses were achieved when Hombre seed treatment was used at Frances and Conmurra sites in 2012.
• Crop rotation effects had a much greater impact on grain protein than whether a seed treatment was used or not.
• Reducing aphid activity reduces the risk of developing BYDV.
• Most occurrences of BYDV occur from aphid activity early in the season, so early protection is best 

• Yield responses were achieved when Hombre seed treatment was used at Frances and Conmurra sites in 2012.
• Crop rotation effects had a much greater impact on grain protein than whether a seed treatment was used or not.
• Reducing aphid activity reduces the risk of developing BYDV.
• Most occurrences of BYDV occur from aphid activity early in the season, so early protection is best 

• Yield responses were achieved when Hombre seed treatment was used at Frances and Conmurra sites in 2012
• Crop rotation effects had a much greater impact on grain protein than whether a seed treatment was used or not
• Reducing aphid activity reduces the risk of developing BYDV
• Most occurrences of BYDV occur from aphid activity early in the season, so early protection is best

Yield responses were closely related to blackleg resistance rating. Varieties with a resistance rating of 7 or greater showed low or no response to fungicide application. Varieties with a mid range rating showed large responses to fungicide.Fungicide does not totally compensate for a low resistance rating.

Three years after application of lime, soil pH (CaCl2) increased by 0.68–1.45 units at 0–10 cm depth, 0.20–0.47 units at 10–20 cm and 0.08–0.18 at 20–30 cm depth. • Lime reduced density of ryegrass by 42% and barley grass density by 67%, improved barley crop vigour by up to 13%, and increased barley grain yield by up to 7% in 2013. • Boxer Gold in 2013 season together with Sakura and simazine in previous seasons reduced annual ryegrass density by 96% and barley grass density by 99%, improved barley crop vigour by up to 15%, and increased barley grain yield by up to 16%. • Lime effect on efficacy of herbicides in controlling weeds was not evident.

Three years after application of lime, soil pH increased by about 1 unit at the top soil and 0.08-0.26 units at the sub-soil layers. • The effect of liming improved crop vigour in 2013 by up to 16% and this effect reduced wild radish density by 50%. This reduction was however not significant, most likely due to low radish densities and a high level of variability. • Velocity together with simazine in previous seasons reduced wild radish density by 98% in 2013 season and improved crop vigour by up to 16%. • Lime increased barley grain yield by up to 6% and Velocity by up to 8%. • Lime effect on herbicide efficacy to control radish in barley crop was not evident.

• Our results suggest shifting investment from nutrients to lime and cultivation and maintaining profit in the first year for the 2 sites we ran is a feasible proposition.  However, this is dependent on the soil constraints and existing soil fertility.  In this trial, it appears that the cultivation response was driven by an increase in the mineralisation rate of organic matter. The incorporation of lime did not provide any yield benefit; while the rotary spader provided adequate mixing of the lime this had no impact on growth because soil pH was already above target levels.  The yield benefit from cultivation was enough to offset the cost of the cultivation and most of the lime application, and the net margin in the year of application could be improved by reducing fertiliser rates.
•  

Our results so far suggest that there is an important interaction between year (timing and distribution of rainfall) and soil and nutrient management. There were no significant treatment effects on grain yield in 2013 and 2015, but there were in 2014 and this may be related to autumn rainfall. At the end of March, 75 and 57 mm had fallen in 2013 and 2015 respectively (Figure 3), however, only 16 mm had fallen at this time in 2014. In 2014, soil water repellence as measured in a laboratory test was significantly higher in the no-till control treatments compared to the rotary spader treatments. Seedling density in 2014 was highest in treatments that had the highest soil water repellence, however, this effect did not carry through to grain yield which was lowest in the no-till control. This trial will continue for at least one more year.

 

• There was a significant yield difference due to liming in the Magenta and Roe plots; however, the Buloke plots were not significantly different.
• Soil pH increased from 4.68 to 5.24.
• This iste had a massive radish seed bank after poor control in lupins in 2008.

• Leaves showing strongly developed symptoms of manganese deficiency or toxicity obtained from the field.
• Wherever possible parallel samples from healthy plants were also taken.
• Healthy green and chlorotic laminar tissue was dissected and manganese determined by atomic absorption spectrometry on acid digests of the wet ashed sample.
• In healthy leaves manganese is not distributed uniformly but is accumulated in the interveinal areas and the tip and margins of the blade.
• In deficient leaves this pattern is reversed and manganese concentrations are lowest in these areas.
• The distribution suggested that manganese is mobilised under severe deficiency however at luxury supply manganese behaves as an immobile element.
• The strong association between visual symptoms of manganese deficiency and toxicity and the distribution of manganese in the leaf suggest these symptoms are the product of local changes in manganese concentrations in the leaf.

• Summary of  2 experiments

• Soil extractable Cu was 0.23 mg/kg.

• Plant density were not effected by Cu or N fertiliser (29-36 plants/m of row2)

• Plant B concentrations 26 -30 mg/kg.

• Cu fertiliser had no effect on seedling density; September Dry matter (DM) (2.0 t/ha); Seed yield (1.55 t/ha) or N % in DM (3.43 % N) or N in the seed (3.6 %).

• B had no effect on %oil (41.9) or on oil yield (650 kg/ha).

• Soil extractable B Hot CaCl2 of 0.7 was adequate

  Care needs to be taken on use of borax fertilizer as toxicity was induced in canola with 0.34 to 1 kg B ha−1(3-10 kg borax ha−1) at sowing depressing seed yield, mostly by decreasing plant density. Rather than making general recommendation for B fertilizer application based on 0.01M CaCl2 soil extractable B, soil and plant analysis should be used to diagnose B deficiency and B fertilizer use limited to calcium borate or foliar borax rather than soil-applied borax on low B sands.

• Boron not required