The information contained in this publication is based on knowledge and understanding at the time of writing (July 2022) and may not be accurate, current or complete. The State of New South Wales (including the Department of Regional New South Wales), the author and the publisher take no responsibility, and will accept no liability, for the accuracy, currency, reliability or correctness of any information included in the document (including material provided by third parties). Readers should make their own inquiries and rely on their own advice when making decisions related to material contained in this publication. The product trade names in this publication are supplied on the understanding that no preference between equivalent products is intended and that the inclusion of a product name does not imply endorsement by the department over any equivalent product from another manufacturer.
Researcher(s) |
Neroli Graham Karl Moore Mark Richards Jessica Simpson |
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Year(s) | 2017, 2019 - 2021 |
Contributor | Department of Primary Industries NSW |
Trial location(s) |
Rankins Springs, NSW
|
Further information | View external link |
To evaluate the phenology and grain yield responses of various albus lupin, faba bean, vetch, lentil and chickpea varieties.
Faba bean
• PBA Amberley was the highest yielding variety, while PBA Samira, PBA Nanu, PBA Marne, PBA Bendoc and Nasma had similar grain yields.
• PBA Marne and PBA Nasma had the highest hundred seed weight.
• PBA Nanu and PBA Nasma were the earliest to flower and continued to flower for over 50 days. PBA Amberley and PBA Samira were last to begin flowering and had two of the three shortest flowering durations.
Albus lupin
• The early flowering Murringo was the highest yielding variety, while Luxor and Rosetta yielded similarly.
• Murringo was the earliest flowering, followed by Luxor then Rosetta.
• Rosetta had the highest hundred seed weight, while Luxor had the lowest.
Vetch
• Timok and Volga were the highest yielding varieties. Studenica and Morava yielded the lowest and were not significantly different from each other.
• There were no significant differences in peak dry matter between varieties.
• Studenica was first to flower and had the longest flowering duration. Morava flowered last.
• Studenica was the earliest to mature, followed by Volga, and Timok. Morava matured significantly later.
Lentil
• The highest yielding variety was PBA Ace. There was some loss of pod/seed due to weather conditions before harvest, but this did not influence grain yield values.
• PBA Blitz and PBA Kelpie XT were the earliest flowering varieties and had the longest flowering duration. Nipper and PBA Flash flowered last.
• PBA Kelpie XT and PBA Hallmark XT matured earliest, while Nipper, PBA Ace and PBA Jumbo2 matured significantly later.
Chickpea
• Average chickpea grain yield was significantly lower than all other pulse species at this site. This is attributed to the cooler than average mean daily temperatures affecting pod set during the critical reproductive window.
• While all varieties yielded above average for this environment, PBA Slasher was the best performing variety with a grain yield of 2.8 t/ha.
The combination of mild winter temperatures, minimal frosts and adequate soil moisture during spring and early summer resulted in all pulse and legume species producing high yields when compared with previous years. Due to minimal biotic and abiotic stress during the growing season, there was no relationship between flowering dates and yield for any of the species tested, however, there were
significant differences in the yields between varieties within individual species.
Lead research organisation |
Department of Primary Industries NSW |
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Host research organisation | N/A |
Trial funding source | GRDC |
Trial funding source | New South Wales DPI |
Related program | N/A |
Acknowledgments |
Thank you to Kim and Nick Eckermann, Hillview, Rankins Springs for their ongoing collaboration and support of pulse research through providing the field site. |
Other trial partners | Not specified |
Crop types | Grain Legume: Faba beans Grain Legume: Chickpeas Grain Legume: Lentils Grain Legume: Lupins Hay: Vetch |
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Treatment type(s) |
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Trial type | Experimental |
Trial design | Replicated |
Sow date | Multiple - please see report |
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Harvest date | Multiple- Please see report |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser |
100 kg/ha, mono-ammonium phosphate (MAP) 50% and single super phosphate (SSP) 50% (blend) |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
Sow date | Not specified |
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Harvest date | Not specified |
Plot size | Not specified |
Plot replication | Not specified |
Fertiliser | Not specified |
Other trial notes |
This research paper is an extract from the publication Southern NSW Research Results 2022, available at |
SILO weather estimates sourced from https://www.longpaddock.qld.gov.au/silo/
Jeffrey, S.J., Carter, J.O., Moodie, K.B. and Beswick, A.R. (2001). Using spatial interpolation to construct a comprehensive archive of Australian climate data , Environmental Modelling and Software, Vol 16/4, pp 309-330. DOI: 10.1016/S1364-8152(01)00008-1.