Storage root quality in sugarbeet in relation to nitrogen uptake

Pocock, T. O.; Milford, G. F. J.; Armstrong, Michael J.

doi:10.1017/s0021859600075791

Cited by 35 publications

(25 citation statements)

References 10 publications

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“…This would be in line with the results of Shock et al [62], who found a negative relationship between nitrate concentration in petioles and polarization (albeit only for one of the two years of their study); with Pocock et al [63], who reported that late additions or releases of nitrogen from soil organic matter reduced the sucrose content; and with Draycott and Christenson [64] and Malnou, Jaggard and Sparkes [40], who indicated that an amount of nitrogen above the optimum had a negative effect on sugar yield. Gordo-Ingelmo [17] explained that beet reacts to nitrogen fertilization increases with a greater development of the leaves and roots, which can cause excessive consumption of sucrose and an increase of non-sugars.…”

Section: Nitrogen Content In Leaves Total Nitrogen Absorption and Casupporting

confidence: 90%

Impact of Climatic Variables on Carbon Content in Sugar Beet Root

et al. 2018

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Abstract:The impacts of climatic variables on the growth and carbon content of spring sown sugar beet (Beta vulgaris L.) in the Castilla y Leon region (Northwestern Spain) were assessed by analyzing 35 beet crop variables at four sites over two cultivation years. ANOVA analysis allowed to discern that the location was the factor that had the highest effect on those variables. Fertilization treatments only had a significant impact on the variables derived from the quantity of fresh material (leaves), while the beet variety choice influenced the amount of nitrogen in leaves and the carbon to nitrogen ratio. It could be inferred that the percentage of root carbon content depended mostly on the location and that a higher percentage of root carbon content led to a higher content of dry matter, with a positive relationship with the sucrose content for the two types of varieties that were tested. Principal Component Analysis distinguished the climatic factors that most influenced each cultivation area in each cultivation year and provided a clear separation of the data in clusters, evidencing the uniqueness of each site.

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Section: Nitrogen Content In Leaves Total Nitrogen Absorption and Casupporting

confidence: 90%

Impact of Climatic Variables on Carbon Content in Sugar Beet Root

et al. 2018

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“…Accumulation of harmful N ( α ‐amino N) is also favoured by increased N supply (Winter 1998), a finding confirmed by our results in eight of 12 trials. Amino‐N is the organic form of N which is used by sugar beets for their regrowth (Pocock et al. 1990).…”

Section: Discussionmentioning

confidence: 99%

“…1990). Uptake of N by sugar beet crop is related to N availability in soil and results in increased α ‐amino N concentrations in roots (Pocock et al. 1990).…”

Section: Discussionmentioning

confidence: 99%

Effect of N Fertilization Rate on Sugar Yield and Non‐Sugar Impurities of Sugar Beets (Beta vulgaris) Grown Under Mediterranean Conditions

Tsialtas¹,

Maslaris²

2005

J Agronomy Crop Science

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For three successive growing seasons (1999–2001), a completely randomized block design experiment was established at the surrounding area of each of four sugar beet processing plants of Hellenic Sugar Industry SA, Greece (a total of 12 experiments). Nitrogen was applied at five rates (0, 60, 120, 180 and 240 kg N ha−1) and six replications per rate. Nitrogen fertilization had site‐specific effects on quantitative (fresh root and sugar yields) and qualitative (sucrose content, K, Na, α‐amino N) traits. When data were combined over years and sites, fresh root and sugar yields were maximized at high N rates (330.75 and 295 kg N ha−1 respectively), as derived from quadratic functions fitted to data. In three trials, increased N rates had negative effects on root and sugar yield. These sites were characterized by high yield in control plots, light soil texture (sand > 50 %) and low CEC values. When data were converted into relative values (the ratio of the trait values to the control mean of each experiment), root and sugar yield was found to be maximized at higher N rates (350 and 316 kg N ha−1, respectively). Sucrose content was strongly and linearly reduced by the increased N rates when data were combined but a significant reduction with increasing N rates was found in only two sites. Non‐sugar impurities (K, Na, α‐amino N) were positively related to the increased N rates when data were combined. Sodium and α‐amino N showed to be most affected by N fertilization as positive relationships were found in six and eight of 12 locations, respectively. Increased N supply resulted in higher soil NO3‐N concentrations (0–90 cm depth) at harvest which were related with amino N contents in sugar beet roots (in 1999 and 2001).

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“…The amino N concentration, and often as an accompanying ion, the sodium concentration, increases, so root quality decreases (Fig. 6) (Pocock and Armstrong 1990;Bell et al 1992;Allison et al 1996). As no interaction between variety and N application occurs, varieties with a high concentration of amino N or betaine have a relatively higher concentration irrespective of the N availability and environmental conditions (Hoffmann 2005).…”

Section: N Fertiliser Applicationmentioning

confidence: 99%

Root Quality of Sugarbeet

Hoffmann¹

2010

Sugar Tech

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The composition of the sugar beet root affects the recovery of crystalline sugar in the factory considerably. K, Na and amino N are melassigenic and are, therefore, always considered in the assessment of root quality for variety approval, and in some countries also for payment. The development of root quality during the season and the impact of variety, root rots, drought stress, N fertilizer application, defoliation/topping and storage are discussed. A further increase of the sugar concentration in varieties may be restricted by cell turgor and can probably only be achieved with a simultaneous decrease of the concentration of non-sugars. Future needs of the processing industry could change the criteria for quality assessment. It is observed that the alkalinity reserve (ion balance) of the juices gets lower so that soda has to be added. Moreover, long-term storage and the infestation with root rots result in a marked increase of the invert sugar concentration with detrimental consequences for processing. Therefore, quality assessment would probably be improved by considering alkalinity and invert sugar concentration. For the use of sugar beet for biofuel production, the sugar concentration (ethanol) or the organic dry matter (methane) of the roots are important quality criteria.

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Storage root quality in sugarbeet in relation to nitrogen uptake

Cited by 35 publications

References 10 publications

Impact of Climatic Variables on Carbon Content in Sugar Beet Root

Impact of Climatic Variables on Carbon Content in Sugar Beet Root

Effect of N Fertilization Rate on Sugar Yield and Non‐Sugar Impurities of Sugar Beets (Beta vulgaris) Grown Under Mediterranean Conditions

Root Quality of Sugarbeet

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