Plant Nutrition
Sally Wilkinson; Jolyon Dodgson; Anna K Weston; David J Marks
Abstract
Purpose: Excessive nitrogen use for crop production leads to environmental damage, so nitrogen use efficiency (NUE) needs to be improved. Stabilized amine nitrogen (SAN) (Lono, Levity Crop Science) has been shown to increase quality and yield of several crops. This work assesses the use of SAN for tomato ...
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Purpose: Excessive nitrogen use for crop production leads to environmental damage, so nitrogen use efficiency (NUE) needs to be improved. Stabilized amine nitrogen (SAN) (Lono, Levity Crop Science) has been shown to increase quality and yield of several crops. This work assesses the use of SAN for tomato production. Research method: SAN was applied to experimentally and commercially grown tomato plants and compared to several industry standard forms of nitrogen. Plant growth characters and yield were recorded. Findings: SAN was compared to an industry standard (IS) nitrogen fertilizer, and it significantly increased the harvested yield due to significant increases in fruit on trusses M3, M4 and lateral shoots. SAN was compared to several conventional IS fertilizers resulting in significantly increased chlorophyll levels, fruit-bearing trusses and an increased yield, but there was a shorter growth habit suggesting more energy was put towards fruit production and less to vegetative growth. Finally, SAN was applied to commercial processing tomato (variety HZ1662) production where there was a significant increase in the perfect red fruit when compared to the standard nitrogen application regime. Research limitations: Further work could be done with other commercial tomato crops. Originality/Value: Results from glasshouse experiments and commercial production show that SAN increases the yield of tomato (Solanum lycopersicum) when compared to IS nitrogen applications.
Plant Nutrition
Sally Wilkinson; Anna Weston; David Marks
Abstract
Purpose: Supplying plants with nitrogen in ammonium nitrate- or urea-based fertiliser is wasteful: much is degraded before acquisition, releasing environmental pollutants. Preventing urea degradation can reduce pollution and improve crop nitrogen use efficiency. We investigate benefits to ureic stabilisation, ...
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Purpose: Supplying plants with nitrogen in ammonium nitrate- or urea-based fertiliser is wasteful: much is degraded before acquisition, releasing environmental pollutants. Preventing urea degradation can reduce pollution and improve crop nitrogen use efficiency. We investigate benefits to ureic stabilisation, on flowering and stress tolerance, as organic nitrogen sources favourably alter biomass partitioning in this regard. Research Method: We test effects of adding chemically stabilised urea to soil, on the physical form and flowering of containerised, greenhouse-grown pelargonium, petunia, pansy and marigold, when transplanting seedlings to larger pots. Efficacies of stabilised urea, non-stabilised urea and industry standard fertiliser are compared under identical total nitrogen supply. The significance of treatment differences is calculated using a one-tailed t-test. Findings: Development is favourably altered by ureic stabilisation. Earliest changes measured are increased root lengths, leaf growth rates and chlorophyll concentrations. Plants then develop more shoots and 25-130% more flowers. Improvements arise partially through increased nitrogen longevity in soil, and partially through positive effects of urea itself on biomass partitioning between organs, and on plant physiology; giving rise to improved commercial attributes (more branches and flowers) and tolerance to stress (more root, less apical dominance, more chlorophyll). Research Limitations: Further research could measure leachate nitrogen content, and compare different methods of ureic stabilisation in more crops. Originality/Value: Urea stabilisation can increase fruit and flower yields, whilst reducing vulnerability to erratic climates, and fertiliser-derived pollution. We propose that urea’s effectiveness arises because plants have evolved strategies to proliferate whilst competing with micro-organisms for organic nitrogen.