Determination of optimum levels of nitrogen, phosphorus and potassium of oil palm seedlings in solution culture

Mohidin, Hasmah; Hanafi, Mohamed Musa; Rafii, Yusop Mohd; Abdullah, Siti Nor Akmar; Idris, Abu Seman; Man, Sulaiman; Idris, Juferi; Sahebi, Mahbod

doi:10.1590/1678-4499.0408

Abstract

Balanced nutrient elements in fertilizer play a critical role in oil palm seedling successful growth and development, and at the same time reduces of fertilizer losses in the environment. This study examines the effect of different levels of N, P₂O₅ and K₂O for oil palm seedlings in solution culture on growth traits, nutrient uptake in plant tissues and biomass accumulation under nursery conditions. Five concentration levels of N (50, 100, 300, 600 and 900 mg L^–1), P₂O₅ and K₂O (15, 30, 60, 90 and 120 mg L^–1) were used in a completely randomized design (CRD) with five replications for each. Parameters measured during the growing period include - plant height, leaf number/plant, stem diameter, SPAD chlorophyll value, and at harvest – total leaf area, root dry weight, shoot dry weight and total dry weight. Different levels of N, P₂O₅ and K₂O showed significant effects on all the parameters studied. The highest values for diameter, plant height, leaf number/plant, total leaf area, root dry weight, shoot dry weight and total dry biomass were obtained using 100, 90 and 300 mg/L levels of N, P₂O₅ and K₂O, respectively. Most of the growth parameters, declined with lower levels of N, P₂O₅ and K₂O. The results of this study provide a new knowledge to produce oil palm plant with better nutrient management at the nursery under solution culture.

growth parameters; solution culture; oil palm; optimum level

1 INTRODUCTION

Oil palm (Elaeis guineensis, Jacq) is an important perennial crop in Malaysia, Indonesia, Columbia, and some African countries. In 2013, the total exports of oil palm products accounted for RM61.36 billion of national gross income; thus making Malaysia one of the largest producers and exporters in the world (MPOB, 2013Malaysian Palm Oil Board - MPOB. (2013). Oil palm and the environment. Kajang. Retrieved in 15 July 2014, from http://bepi.mpob.gov.my/index.php/statistics/export/121-export-2013.html.
http://bepi.mpob.gov.my/index.php/statis... ). Oil palm is the highest yielding oil crop (t ha^–1) in the world (Corley & Tinker, 2003Corley, R. H. V., & Tinker, P. B. (2003). The oil palm (4th ed.). Oxford: Blackwell Publishing. http://dx.doi.org/10.1002/9780470750971.
http://dx.doi.org/10.1002/9780470750971... ). High yield quality crops can be obtained by supplying optimum mineral nutrition. Mineral nutrition involves the supply, absorption, and utilization of the essential nutrients required for successful growth and yield of the crop plants (Fageria et al., 2010Fageria, N. K., Baligar, V. C., & Jones, C. A. (2010). Growth and mineral nutrition of field crops (3rd ed.). New York: CRC Press. http://dx.doi.org/10.1201/b10160.
http://dx.doi.org/10.1201/b10160... ). Levels of N, P₂O₅, K₂O and water are considered as the major limiting factors in crop growth, development and finally economic yield (Glass, 2003Glass, A. D. M. (2003). Nitrogen use efficiency of crop plants: Physiological constraints upon nitrogen absorption. CRC. Critical Reviews in Plant Sciences, 22, 453-470. http://dx.doi.org/10.1080/07352680390243512.
http://dx.doi.org/10.1080/07352680390243... ; Parry et al., 2005Parry, M. A. J., Flexas, J., & Medrano, H. (2005). Prospects for crop production under drought: research priorities and future directions. Annals of Applied Biology, 147, 211-226. http://dx.doi.org/10.1111/j.1744-7348.2005.00032.x.
http://dx.doi.org/10.1111/j.1744-7348.20... ). Nitrogen is the most important nutrient element in terms of plant growth, physiology and carbohydrate content (Almodares et al., 2008Almodares, A., Taheri, R., Chung, I. M., & Fathi, M. (2008). The effect of nitrogen and potassium fertilizers on growth parameters and carbohydrate contents of sweet sorghum cultivars. Journal of Environmental Biology, 29, 849-852. PMid:19297978.). It is a constituent of chlorophyll, amino acids, proteins, alkaloids, and protoplasm. Phosphorus is the second most limiting nutrient in crop production, playing its most critical role in plants in energy transfer and storage. It is a structural component of nucleic acids, nucleotides, and coenzymes. Low availability is a limiting factor to plant growth (Fita et al., 2011Fita, A., Nuez, F., & Picó, B. (2011). Diversity in root architecture and response to P deficiency in seedlings of L. Cucumis meloEuphytica, 181, 323-339. http://dx.doi.org/10.1007/s10681-011-0432-z.
http://dx.doi.org/10.1007/s10681-011-043... ). Potassium is important for maintaining osmotic balance, phloem transport, and photosynthesis (Tripler et al., 2006Tripler, C. E., Kaushal, S. S., Likens, G. E., & Walter, M. T. (2006). Patterns in potassium dynamics in forest ecosystems. Ecology Letters, 9, 451-466. http://dx.doi.org/10.1111/j.1461-0248.2006.00891.x. PMid:16623731.
http://dx.doi.org/10.1111/j.1461-0248.20... ).

Maintaining a balanced nutrition has an important role in determining plant resistance or susceptibility to disease (Fageria et al., 2010Fageria, N. K., Baligar, V. C., & Jones, C. A. (2010). Growth and mineral nutrition of field crops (3rd ed.). New York: CRC Press. http://dx.doi.org/10.1201/b10160.
http://dx.doi.org/10.1201/b10160... ). Moreover, improving nutrient use efficiency (NUE) of crop plants leads to a substantial enhancement of the plant yields to satisfy growing food demand, while concurrently reducing the environmental impacts of agriculture (Lobell, 2007Lobell, D. B. (2007). The cost of uncertainty for nitrogen fertilizer management: a sensitivity analysis. F. Crop. Res, 100, 210-217. http://dx.doi.org/10.1016/j.fcr.2006.07.007.
http://dx.doi.org/10.1016/j.fcr.2006.07.... ). Many studies have been carried out on the balance nutrient uptake under soil based plants (García-Palacios et al., 2014García-Palacios, P., Maestre, F. T., Bradford, M. A., & Reynolds, J. F. (2014). Earthworms modify plant biomass and nitrogen capture under conditions of soil nutrient heterogeneity and elevated atmospheric CO concentrations. 2Soil Biology & Biochemistry, 78, 182-188. http://dx.doi.org/10.1016/j.soilbio.2014.08.002.
http://dx.doi.org/10.1016/j.soilbio.2014... ; Bloomfield et al., 2014Bloomfield, K. J., Farquhar, G. D., & Lloyd, J. (2014). Photosynthesis–nitrogen relationships in tropical forest tree species as affected by soil phosphorus availability: a controlled environment study. Functional Plant Biology, 41, 820-832. http://dx.doi.org/10.1071/FP13278.
http://dx.doi.org/10.1071/FP13278... ; Koorem et al., 2014Koorem, K., Gazol, A., Öpik, M., Moora, M., Saks, Ü., Uibopuu, A., Sõber, V., & Zobel, M. (2014). Soil nutrient content influences the abundance of soil microbes but not plant biomass at the small-scale. PLoS One, 9, e91998. http://dx.doi.org/10.1371/journal.pone.0091998. PMid:24637633.
http://dx.doi.org/10.1371/journal.pone.0... ). However, in soil based plant experiment, there exists a complex interaction between the plant, the soil and microbes which may attribute to competitive effects and does not reflect the real N, P₂O₅ and K₂O nutrients taken up and utilized by the plants precisely. Furthermore, in soil medium there exist a complex interaction between ions within soil particles (Conn et al., 2013Conn, S. J., Hocking, B., Dayod, M., Xu, B., Athman, A., Henderson, S., Aukett, L., Conn, V., Shearer, M. K., Fuentes, S., Tyerman, S. D., & Gilliham, M. (2013). Protocol: optimising hydroponic growth systems for nutritional and physiological analysis of Arabidopsis thaliana and other plants. Plant Methods, 9, 4. http://dx.doi.org/10.1186/1746-4811-9-4. PMid:23379342.
http://dx.doi.org/10.1186/1746-4811-9-4... ). For P nutrition, hydroponic trial is a better way to determine the P₂O₅ optimum level because applied P fertilizers in soil medium become precipitated by complexes with Fe, Al, and Ca in the soils immediately after application, thus does not give the correct amount available for the plant uptake. Hydroponically grown plants (plants cultivated in a soil-free growing system, where a controlled nutrient-rich solution supplies plant roots with nourishment) have been shown to have faster growth rate than soil based plants and are an ideal medium and platform for conveniently evaluating whole plant physiology (Conn et al., 2013Conn, S. J., Hocking, B., Dayod, M., Xu, B., Athman, A., Henderson, S., Aukett, L., Conn, V., Shearer, M. K., Fuentes, S., Tyerman, S. D., & Gilliham, M. (2013). Protocol: optimising hydroponic growth systems for nutritional and physiological analysis of Arabidopsis thaliana and other plants. Plant Methods, 9, 4. http://dx.doi.org/10.1186/1746-4811-9-4. PMid:23379342.
http://dx.doi.org/10.1186/1746-4811-9-4... ). Furthermore, correct nutrient management at nursery stage could avoid wastage and reduces losses of fertilizer. Hydroponic medium give higher yield per unit measured area, continuous year round production, higher quality and ease of processing of harvested product due to minimal contamination from pollutants, pests and pathogens (Pardossi et al., 2006Pardossi, A., Malorgio, F., Incrocci, L., & Tognoni, F. (2006). Hydroponic technologies for greenhouse crops. In R. Dris (Ed.)., Crops: quality, growth and biotechnology. Helsinky: WFL Publisher.) and most importantly an easy handling of the nutrient profile of the growth medium. In this study, the effect of different levels of N, P₂O₅ and K₂O for oil palm seedlings in solution culture on growth, physiological, nutrient uptake in plant tissues and biomass accumulation have been carried out under nursery conditions.

2 MATERIAL AND METHOD

Study site and plant materials

The experiment was conducted in the Experimental Farm, No. 2, Universiti Putra Malaysia, Serdang, Selangor, Malaysia (2°59’20.56”N, 101°42’44.42”E) under nursery glasshouse conditions for 182 days between April - October, 2012. The trial was set up in plastic pails (20 cm diameter × 16 cm depth). Plant materials consist of pre-germinated seeds, Dura × Pisifera (F0046 × 1 HP60) purchased from FELDA Plantations Sdn. Bhd, Sungai Tekam, Jerantut, Pahang, Malaysia. Hydroponic media consisting of distilled water and various prepared concentrations of Hoagland solution (A and B) were employed to provide a calculated five nutrient levels for the primary elements of N, P₂O₅ K₂O were prepared, respectively. The prepared solution was then applied to the growing seedlings.

Growth conditions, treatments and experimental design

The germinated oil palm seedlings were raised in polypropylene trays, kept moist with distilled water and wool, and replaced every three days for 2 weeks. Oil palm seedlings of uniform plant height were selected. The nutrient solution used as the plant growth media was prepared according to Hoagland with some modifications (Hoagland & Arnon, 1950Hoagland, D. R, & Arnon, D. I. (1950). The water culture method for growing plants without soil (Circular 347). Berkeley: California Agricultural Experiment Station, University of California.). The pH of the culture solution was adjusted to 5.5 with 0.1N NaOH or 0.1N HCl, and monitored. Electrical conductivity (EC) reading was also monitored to ensure it remains within the recommended range of 0.1-4.0 mmhos. The solution was permanently aerated using an air pump and was renewed every 14 days to guarantee an adequate nutrient supply and replenishment needs for the growing seedlings. Each seedling was fixed onto foam to hold the seedlings erect and placed on perforated white polystyrene covered with black plastic onto individual polypropylene pail containing 2.0 L of nutrient solution. Treatment levels consisted of 50, 100, 300, 600 and 900 mg L^-1 concentrations of N and K₂O and 15, 30, 60, 90 and 120 mg L^-1concentrations of P₂O₅ laid out in a completely randomized design (CRD) with 5 replications and a total of 75 experimental units

Data collection on growth r parameters

Several growth parameters were measured during the growing period. Plant height, leaf number/plant, stem diameter and physiological parameters including SPAD chlorophyll content were recorded at a biweekly interval beginning 98 DAT. Measurement of stem diameter was made using a digital caliper. The chlorophyll (Chl) value in the third leaf was determined with a SPAD Chl meter (SPAD-502 Minolta) following the Benton Jones method (Jones, 2003Jones, B., Jr. (2003). Agronomic handbook: management of crops, soils, and their fertility. Florida: CRC Press.). The Chl value (commonly called SPAD Chl value) of each leaf was the average of five measurements. In the course of the experiment, some deficiency and/or toxicity symptoms were noted and recorded.

Biomass measurement

The plants were destructively sampled at 182 days (harvest period). Plants were partitioned into shoots and roots and the dry weights - root dry weight, shoot dry weight, total dry weight, total leaf area and root shoot ratio, were recorded and nutrient partitioned. Nutrient analysis for N, P and K nutrient uptake in the tissue was performed.

Sample preparation and analysis

After drying, all the plant components were separately ground and sub-sampled. Oven-dried shoot and roots (250 mg) were digested in 5 mL sulfuric acid in a block digester at 330°C for 2 hours. Hydrogen peroxide (4-5 drops) was added after which the samples were placed in a digester for 1 hour (Gupta, 2007Gupta, P. K. (2007). Soil, plant, water and fertilizer analysis (2nd ed.). India: Agrobios.). Digested solutions were filtered through Whatman filter paper No. 44 and made up to 50 mL with distilled water in volumetric flasks. The concentrations of N and P in solution were determined using an auto-analyzer (QuikChem, Series 8000, Lachat Instruments Inc., USA) and the concentration of K was measured using atomic absorption spectrophotometer (Perkin-Elmer 5100 PC).

Statistical analysis

Data were averaged over the replications for all measuring dates and their means were used in deriving relationships between growth and nutrient uptake parameters. The differences in growth and nutrition between the N, P₂O₅ and K₂O treatments were calculated using the SAS statistical procedure, PROC ANOVA, Duncan’s Multiple Range Test (DMRT; p<0.05) was used to detect significant grouping among the treatments.

3 RESULTS AND DISCUSSION

Effect of nitrogen levels on oil palm seedlings growth

The results of growth parameters outlined in Table 1, indicated all plant traits measured - total leaf area and root shoot ratio indicated highly significant (p<0.001) difference among the treatment levels, while plant height, stem diameter, number of leaf/plant indicated significant difference (p<0.05). Level N2 (100 mg L^–1) recording the highest value which began to decline significantly as the N levels were raised. The physiological parameter indicated only SPAD Chl values was significantly different (p<0.05) among the N treatment levels.

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Table 1
Mean comparison of nitrogen nutrition for growth and parameter at harvest, 182 DAT

The total leaf area at level N2 was significantly higher (383.16 cm²) and began to decline significantly as the N level was raised to 300 mg L^–1. The lowest treatment at N1 (50 mg L^–1) resulted in a 32.8% reduction in total leaf area. This increased leaf area in N2 despite only slight differences in the leaf number/plant suggest that higher leaf expansion of treated oil palm seedlings were attained. This study suggested that N nutrition at deficiency affected more strongly the leaf development rather than the photosynthesis. Moreover, N deficiency has great impact on chloroplast in size, composition and function (Lawlor & Cornic, 2002Lawlor, D. W., & Cornic, G. (2002). Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants. Plant, Cell & Environment, 25, 275-294. http://dx.doi.org/10.1046/j.0016-8025.2001.00814.x. PMid:11841670.
http://dx.doi.org/10.1046/j.0016-8025.20... ). On the other hand, the higher rates, N4 and N5 attain the level of toxicity and retard the plant growth and this could also be attributed to toxicity of the nutrient at higher levels, where the symptoms of necrosis of the oil palm seedlings’ leaves initially were observed and eventually the whole plants died.

In solution culture experiment, N is absorbed in large quantity and the forms, such as NO₃^- (anion) or NH₄⁺(cation) , in which this element is supplied exerts a great influence on pH change and pH in turn affect in unequal absorption of cations and anions and nutrient availability in solution culture.

Effect of phosphorus levels on oil palm seedlings growth

Multiple mean comparisons of the growth parameters in table 2 indicated plant traits measured - leaf area, root shoot ratio, SPAD Chl value, - were highly significant (p< 0.001) difference among the treatment levels, while plant height and stem diameter gave the highest values among the treatment levels. Overall, P4 (90 mg L^-1) were optimum for plant height, stem diameter, total leaf area, and root shoot ratio. The higher level of P₂O₅ nutrition caused the highest increase (34.50 cm) in plant height at P4. Similarly, the SPAD Chl value was significantly influenced by the level of P₂O_5. In treatment P1 (15 mg L^-1), total leaf area was reduced (193.79 cm²), a 70.4% reduction from the optimum values and leaves were observed to be shorter as affected by P₂O₅ deficiency. Increasing the levels of P₂O₅ treatments, significantly increase (p<0.001) the root shoot ratio by a 45.5%. Phosphorus nutrition have caused greater percentage of assimilate partitioned towards the roots, thus this lead to an increase in the root shoot ratio. The P1 treatment was too low to impact on the growth parameters, while the higher rate was too toxic to allow proper growth. As observed in this present study, P deficiency had reduced leaf expansion, leaf surface area, and the number of leaves and this was later on reflected in lower biomass production at harvest. This is due to inadequate P slows the processes of carbohydrate metabolism including photosynthesis and respiration, which results in a buildup of carbohydrates and the development of a dark green leaf color. In addition, leaf edges turn scorched brown in deficiency of P.

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Table 2
Mean comparison of phosphorus nutrition for growth and parameter at harvest, 182 DAT

Effect of potassium levels on oil palm seedlings growth

Overall, multiple mean comparisons of all the K₂O treatments (Table 3) indicated all plant growth traits measured - plant height, stem diameter, leaf area, (p<0.001) number of leaf plant (p<0.05) indicated significant difference among the treatment levels, with K3 (300 mg L^–1) recording the highest reading and declining significantly as the K₂O levels were raised. At K1, the lowest treatment levels for K₂O (50 mg L^–1) resulted in 43.8% increase in total leaf area. It can be noticed that optimum concentration of K element in nutrient solution led to maximum plant height, stem diameter, leaf area and other growth traits.

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Table 3
Mean comparison of potassium nutrition for growth and parameter at harvest, 182 DAT

Effect of N, P2O5 and K2O nutrition on dry weight, total biomass and proportion of biomass partitioning

Among all the growth parameters, dry biomass accumulation confirms the positive effects of a balanced nutrition and the importance of these N, P₂O₅ and K₂O nutrition on the oil palm growth performance. For N treatment in Table 4, all of dry biomass i.e. shoot dry weight, root dry weight and total plant biomass for N treatment indicated highly significant ( $p \leq$ 0.001) difference among the treatment levels. Highest shoot dry weight values, 2.35 and 1.85 g plant^–1, were obtained with the first two lower levels of N concentrations (100 and 50 mg L^–1 respectively), being significantly different (p≤0.001). Treatment level of N2 (100 mg L^–1) gave the optimum value for most of the agronomic parameters studied and is recommended to attain optimum seedling growth

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Table 4
Effect of N, P₂O₅ and K₂O nutrition on oil palm dry weight, proportion of biomass accumulation and total biomass accumulation at harvest, 182 DAT

in oil palm. The higher N rate did not have positive impact on the growth parameters studied. A gradual significant decrease in the shoot dry matter was noted as N concentration was raised to 300 mg L^–1 and further raised to 600 and 900 mg L^–1 levels with the values declining to 1.56, 1.10, and 0.63 g plant^–1, respectively. The higher rates attain the level of toxicity and retard the plant growth rate and dry matter accumulation.

For biomass accumulation with P₂O₅ treatment, treatment level P4 (90 mg L^–1) was considered the optimum for the growth parameters studied. The P concentration applied gave the highest shoot dry weight (2.79 g plant^–1) that was significantly different from the other four applied levels. The least shoot dry weight yield (1.35 and 1.42 g plant^–1) were obtained from the lowest applied P concentration in P1 (15 mg L^–1) and the highest in P5 (120 mg L^–1), respectively, and both were not significantly different. At P1 level was too low to impact on the growth parameters, while P5 was too toxic to allow for proper growth. Root dry weight was not significantly affected by the treatment levels but P4 gave the highest root dry weight.

Phosphorus concentrations in P4 and P2 gave the highest total dry matter of 3.16 and 2.72 g plant^–1, respectively, with no significant difference between the two levels. Similarly lowest total dry matter of 1.75 and 1.57 g plant^–1 was obtained from the highest (P5) and lowest (P1) applied P concentrations, respectively, with no significant difference between the two.

Applied K levels in K2 and K3 (100 and 300 mg L^–1 respectively) gave the highest shoot dry weight values of 3.26 and 3.50 g plant^–1respectively, with the difference between the two being insignificant. Lower shoot dry weight values of 2.20, 1.98, and 1.62 g plant^–1 came from the remaining 3 treatment levels of 50, 600, and 900 mg L^–1, respectively, with the difference between them being insignificant. Potassium applied concentration of 300 mg L^–1 gave a correspondingly significantly high root dry weight value (0.62 g plant^-1) than the other applied treatment levels. Lowest root dry weight value came from 3 applied K concentrations of 50, 600, and 900 mg L^–1, with no significant difference between them.

Highest total dry weight values of 3.77 and 4.12 g plant^-1 were obtained from applied K levels of 100 and 300 mg L^–1, respectively. Overall, total plant biomass accumulated in the plant was affected significantly by the different levels of N, P₂O₅ and K₂O treatment, with the optimum values of 2.78, 3.16 and 4.12 g/plant at N2, P4 and K3 levels obtained.

For proportion of biomass partitioning in table 4, all the three treatments indicated shoots portion consisting of leaf, stem and stem accounted for the greatest proportion of dry matter partitioning, 81.1-90.9%, while root accounted only 9.1-18.9%, respectively.

Effect of N, P2O5 and K2O nutrition on the nutrient uptake, nutrient concentration and nutrient partitioning in plant parts

For nutrient uptake (Table 5), all the applied treatment levels indicated higher nutrient uptake in the shoot as compared to the root portion. The highest total N uptake of 58.03 g plant^-1 was obtained with 100 mg L^–1 levels of applied N with mean comparison portrays the differences as highly significant. Irrespective of the N, P₂O₅ and K₂O source in the solution culture, highest nutrient uptake for total N, P and K in plant tissue were 71.43, 23.40 and 214.33 mg plant^-1 respectively, obtained with treatment applications of 100, 90 and 300 mg L^–1 with significant different among treatments. Results indicate a distinct role of N in the export of photosynthesis from leaves to root. The alteration in photosynthetic partitioning plays a major role in the differences in dry matter distribution between leaves and roots of plants (Cakmak et al., 1994Cakmak, I., Hengeler, C., & Marschner, H. (1994). Partitioning of shoot and root dry matter and carbohydrates in bean plants suffering from phosphorus, potassium and magnesium deficiency. Journal of Experimental Botany, 45, 1245-1250. http://dx.doi.org/10.1093/jxb/45.9.1245.
http://dx.doi.org/10.1093/jxb/45.9.1245... ).

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Table 5
Effect of N, P₂O₅ and K₂O nutrition on the nutrient uptake in different plant parts at harvest, 182 DAT

Plant uptake is the most significant removal process in N, P₂O₅ and K₂O cycling. For any actively growing plants, anything that affects the metabolism of the plant will affect nutrient uptake. Elevating the total N, P₂O₅ and K₂O levels (Table 6) had significantly decreased total N, P₂O₅ and K₂O in total nutrient uptake. Potassium levels were found to have similar trend with N (Table 6) in the assessed tissue parts, with concentration up to the highest rate tested in this study. By comparing the same rate of N and K₂O treatment, K uptake greatly exceeds N uptake (more than 3 folds) in the total nutrients uptake in oil palm tissue. However, highest levels of nutrient concentration and nutrient uptake did not give the highest plant biomass accumulation though. These could be attributed to nutrient imbalances at higher levels affecting the physiological, biochemical processes and retard growth of the oil palm seedlings. For instant, nutrient uptake in plant tissues for K4 and K5, indicated no corresponding increase in growth parameters and is reflected in the reduced total dry biomass at K4 and K5. Similarly, for N treatment, despite significantly higher shoot and root N content in N4 and N5, respectively, no corresponding increase of total biomass accumulated (Table 4). These cases shed some light on the antagonistic interaction among the nutrients, thus resulted in inefficient and uneconomical utilization of N and K nutrients in the plant tissues. What is clear is that the rate of nutrient uptake is controlled by the growth rate of plants and related to the physiological requirements.

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Table 6
Effect of N, P₂O₅, and K₂O treatment on nutrient concentration and nutrient partitioning of different plant parts at harvest, 182 DAT

Effect of N, P2O5 and K2O nutrition on nutrient concentration and nutrient partitioning in plant parts

Laboratory analysis conducted to determine nutrient partitioned in oil palm tissues (Table 6) showed that all treatments resulted in higher nutrient concentration were partitioned in shoot parts compared to the root. Within the N treatment application, indicated significant increase in shoot N tissue concentration up to the highest rate tested in this study. The N2, N3 and N4 levels were not significantly different with each other, but were significantly different with N1 and N5, with the highest value of 4.93% obtained in N5.

In P₂O₅ treatment (Table 6), shoot parts for both N and P nutrient concentration indicated the highest values at P4, with the values of 3.50 and 1.00% (p<0.05), respectively, both significantly different from all the other P levels. However, root P were not significantly different for all P levels in these two treatments. Shoot part indicated the highest K nutrient concentration value at P5 and were significantly different compared with other levels. For the root part, K nutrient concentration highest value was 4.99% at P5, but were not significantly different with P3 and P4 levels. Likewise, nutrient partitioning result observed similar trend with highest values of 12.2% for shoot partitioning at P4.

In K₂O treatment (Table 6), N nutrient concentration partitioned in shoot tissues showed higher values of 6.11% at K2 and 6.01% at K3, with significant different from K1, K4 and K4. Phosphorus nutrient concentration partitioned in shoot tissues was highest value of 1.19% at K3. For K concentration of nutrient, both the K shoot and root concentration significantly increased with the increased treatment levels up to the highest rate tested with the values of 9.95 and 7.91% in K5, in the shoot and root, respectively. Similarly, K5 nutrient partitioning significantly gave the highest K5 shoot values of 54.7% and K5 root of 6.2%, respectively.

According to Peterson’s finding, crop plants absorb more K₂O than any other nutrient except N (Peterson et al., 2006Peterson, G. A., Unger, W. P., & Payne, W. A. (2006). Dryland agriculture (2nd ed.). Madison: American Society of Agronomy.). For K concentration of nutrient, both K shoot and root concentration significantly increased with the increased treatment levels indicate potassium is highly mobile within plant. However, K flow and partitioning can change depending on the forms of N supply (Zhang et al., 2010Zhang, F. S., Niu, J., Zhang, W., Chen, X. P., Li, C., Yuan, L., & Xie, J. C. (2010). Potassium nutrition of crops under varied regimes of nitrogen supply. Plant and Soil, 335, 21-34. http://dx.doi.org/10.1007/s11104-010-0323-4.
http://dx.doi.org/10.1007/s11104-010-032... ). The NH₄⁺ nutrition in comparison to NO₃^- supply results in more K translocated to leaves. The partitioning of assimilates between roots and shoots is important for the plant growth process. In this nutrient culture experiment, N and K₂O nutrition favor an increase in nutrient partitioned in the shoot of oil palm seedlings probably due to increase rate of amino acid translocation to the shoot than the root. However, excessive K may cause Ca and Mg deficiencies and nutritional imbalances in the plants, but limited N, P₂O₅and K₂O supply on the other hand, decreases rates of cell division, cell expansion, cell permeability, photosynthesis, leaf production, and growth, plants (Roggatz et al., 1999Roggatz, U., Mcdonald, A. J. S., Stadenberg, I., & Schurr, U. (1999). Effects of nitrogen deprivation on cell division and expansion in leaves of L. Ricinus communisPlant, Cell & Environment, 22, 81-89. http://dx.doi.org/10.1046/j.1365-3040.1999.00383.x.
http://dx.doi.org/10.1046/j.1365-3040.19... ; Reddy et al., 1997Reddy, K. R., Hodges, H. F., & Mckinion, J. M. (1997). Modeling temperature effects on cotton internode and leaf growth. Crop Science, 37, 503-509. http://dx.doi.org/10.2135/cropsci1997.0011183X003700020032x.
http://dx.doi.org/10.2135/cropsci1997.00... ).

Among the nutrients, N, P and K are the major limiting factors in oil palm growth and yield. This study suggested that despite the benefits of these N, P₂O₅ and K₂O nutrition in oil palm seedlings growth, the correct balance nutrient management levels of each element must be apply to avoid antagonistic interactions that could upset or suppress the uptake of other nutrients and affect the plant growth and development. For optimum crop growth and high yield proper doses of these nutrient elements are required. Responses of oil palm to these N, P₂O₅ and K₂O nutrition are of considerable importance in agriculture. Therefore, to determine the optimum levels of N, P and K to grow better oil palm seedlings is crucial.

4 CONCLUSION

The growth traits, biomass accumulation and partitioning of oil palm seedlings were affected by nutrient uptake and availability. For better nutrient management, based on this study, N, P and K nutrient elements play a critical role in oil palm seedlings growth and development. The fertilization practice is to ensure the growing plant get all the required nutrients for optimum growth. Overall, nutrients uptake in palm tissues ranked in ascending order were as followed: P > N > K, respectively. It can be concluded that 100, 90 and 300 mg L^–1 of N, P₂O₅, and K₂O, respectively, gave the best growth traits, biomass accumulation and nutrient uptake and were recommended for sustaining optimum and maximum growth of oil palm seedlings.

ACKNOWLEDGEMENTS

The authors are extremely grateful to Malaysian Palm Oil Board (MPOB) and Universiti Putra Malaysia (UPM), for jointly funding this research study, and to Universiti Technology MARA (UiTM) for granting study fellowship to the first author. The contribution made by Shamsuddeen Rufai is also acknowledged.

REFERENCES

Almodares, A., Taheri, R., Chung, I. M., & Fathi, M. (2008). The effect of nitrogen and potassium fertilizers on growth parameters and carbohydrate contents of sweet sorghum cultivars. Journal of Environmental Biology, 29, 849-852. PMid:19297978.
Bloomfield, K. J., Farquhar, G. D., & Lloyd, J. (2014). Photosynthesis–nitrogen relationships in tropical forest tree species as affected by soil phosphorus availability: a controlled environment study. Functional Plant Biology, 41, 820-832. http://dx.doi.org/10.1071/FP13278.
» http://dx.doi.org/10.1071/FP13278
Cakmak, I., Hengeler, C., & Marschner, H. (1994). Partitioning of shoot and root dry matter and carbohydrates in bean plants suffering from phosphorus, potassium and magnesium deficiency. Journal of Experimental Botany, 45, 1245-1250. http://dx.doi.org/10.1093/jxb/45.9.1245.
» http://dx.doi.org/10.1093/jxb/45.9.1245
Conn, S. J., Hocking, B., Dayod, M., Xu, B., Athman, A., Henderson, S., Aukett, L., Conn, V., Shearer, M. K., Fuentes, S., Tyerman, S. D., & Gilliham, M. (2013). Protocol: optimising hydroponic growth systems for nutritional and physiological analysis of Arabidopsis thaliana and other plants. Plant Methods, 9, 4. http://dx.doi.org/10.1186/1746-4811-9-4. PMid:23379342.
» http://dx.doi.org/10.1186/1746-4811-9-4
Corley, R. H. V., & Tinker, P. B. (2003). The oil palm (4th ed.). Oxford: Blackwell Publishing. http://dx.doi.org/10.1002/9780470750971.
» http://dx.doi.org/10.1002/9780470750971
Fageria, N. K., Baligar, V. C., & Jones, C. A. (2010). Growth and mineral nutrition of field crops (3rd ed.). New York: CRC Press. http://dx.doi.org/10.1201/b10160.
» http://dx.doi.org/10.1201/b10160
Fita, A., Nuez, F., & Picó, B. (2011). Diversity in root architecture and response to P deficiency in seedlings of L. Cucumis meloEuphytica, 181, 323-339. http://dx.doi.org/10.1007/s10681-011-0432-z.
» http://dx.doi.org/10.1007/s10681-011-0432-z
García-Palacios, P., Maestre, F. T., Bradford, M. A., & Reynolds, J. F. (2014). Earthworms modify plant biomass and nitrogen capture under conditions of soil nutrient heterogeneity and elevated atmospheric CO concentrations. ₂Soil Biology & Biochemistry, 78, 182-188. http://dx.doi.org/10.1016/j.soilbio.2014.08.002.
» http://dx.doi.org/10.1016/j.soilbio.2014.08.002
Glass, A. D. M. (2003). Nitrogen use efficiency of crop plants: Physiological constraints upon nitrogen absorption. CRC. Critical Reviews in Plant Sciences, 22, 453-470. http://dx.doi.org/10.1080/07352680390243512.
» http://dx.doi.org/10.1080/07352680390243512
Gupta, P. K. (2007). Soil, plant, water and fertilizer analysis (2nd ed.). India: Agrobios.
Hoagland, D. R, & Arnon, D. I. (1950). The water culture method for growing plants without soil (Circular 347). Berkeley: California Agricultural Experiment Station, University of California.
Jones, B., Jr. (2003). Agronomic handbook: management of crops, soils, and their fertility. Florida: CRC Press.
Koorem, K., Gazol, A., Öpik, M., Moora, M., Saks, Ü., Uibopuu, A., Sõber, V., & Zobel, M. (2014). Soil nutrient content influences the abundance of soil microbes but not plant biomass at the small-scale. PLoS One, 9, e91998. http://dx.doi.org/10.1371/journal.pone.0091998. PMid:24637633.
» http://dx.doi.org/10.1371/journal.pone.0091998
Lawlor, D. W., & Cornic, G. (2002). Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants. Plant, Cell & Environment, 25, 275-294. http://dx.doi.org/10.1046/j.0016-8025.2001.00814.x. PMid:11841670.
» http://dx.doi.org/10.1046/j.0016-8025.2001.00814.x
Lobell, D. B. (2007). The cost of uncertainty for nitrogen fertilizer management: a sensitivity analysis. F. Crop. Res, 100, 210-217. http://dx.doi.org/10.1016/j.fcr.2006.07.007.
» http://dx.doi.org/10.1016/j.fcr.2006.07.007
Malaysian Palm Oil Board - MPOB. (2013). Oil palm and the environment. Kajang. Retrieved in 15 July 2014, from http://bepi.mpob.gov.my/index.php/statistics/export/121-export-2013.html.
» http://bepi.mpob.gov.my/index.php/statistics/export/121-export-2013.html
Pardossi, A., Malorgio, F., Incrocci, L., & Tognoni, F. (2006). Hydroponic technologies for greenhouse crops. In R. Dris (Ed.)., Crops: quality, growth and biotechnology. Helsinky: WFL Publisher.
Parry, M. A. J., Flexas, J., & Medrano, H. (2005). Prospects for crop production under drought: research priorities and future directions. Annals of Applied Biology, 147, 211-226. http://dx.doi.org/10.1111/j.1744-7348.2005.00032.x.
» http://dx.doi.org/10.1111/j.1744-7348.2005.00032.x
Peterson, G. A., Unger, W. P., & Payne, W. A. (2006). Dryland agriculture (2nd ed.). Madison: American Society of Agronomy.
Reddy, K. R., Hodges, H. F., & Mckinion, J. M. (1997). Modeling temperature effects on cotton internode and leaf growth. Crop Science, 37, 503-509. http://dx.doi.org/10.2135/cropsci1997.0011183X003700020032x.
» http://dx.doi.org/10.2135/cropsci1997.0011183X003700020032x
Roggatz, U., Mcdonald, A. J. S., Stadenberg, I., & Schurr, U. (1999). Effects of nitrogen deprivation on cell division and expansion in leaves of L. Ricinus communisPlant, Cell & Environment, 22, 81-89. http://dx.doi.org/10.1046/j.1365-3040.1999.00383.x.
» http://dx.doi.org/10.1046/j.1365-3040.1999.00383.x
Tripler, C. E., Kaushal, S. S., Likens, G. E., & Walter, M. T. (2006). Patterns in potassium dynamics in forest ecosystems. Ecology Letters, 9, 451-466. http://dx.doi.org/10.1111/j.1461-0248.2006.00891.x. PMid:16623731.
» http://dx.doi.org/10.1111/j.1461-0248.2006.00891.x
Zhang, F. S., Niu, J., Zhang, W., Chen, X. P., Li, C., Yuan, L., & Xie, J. C. (2010). Potassium nutrition of crops under varied regimes of nitrogen supply. Plant and Soil, 335, 21-34. http://dx.doi.org/10.1007/s11104-010-0323-4.
» http://dx.doi.org/10.1007/s11104-010-0323-4

Publication Dates

Publication in this collection
07 July 2015
Date of issue
Jul-Sep 2015

History

Received
17 Nov 2014
Accepted
22 Feb 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Almodares, A., Taheri, R., Chung, I. M., & Fathi, M. (2008). The effect of nitrogen and potassium fertilizers on growth parameters and carbohydrate contents of sweet sorghum cultivars. Journal of Environmental Biology, 29, 849-852. PMid:19297978.

[2] Bloomfield, K. J., Farquhar, G. D., & Lloyd, J. (2014). Photosynthesis–nitrogen relationships in tropical forest tree species as affected by soil phosphorus availability: a controlled environment study. Functional Plant Biology, 41, 820-832. http://dx.doi.org/10.1071/FP13278.
» http://dx.doi.org/10.1071/FP13278

[3] Cakmak, I., Hengeler, C., & Marschner, H. (1994). Partitioning of shoot and root dry matter and carbohydrates in bean plants suffering from phosphorus, potassium and magnesium deficiency. Journal of Experimental Botany, 45, 1245-1250. http://dx.doi.org/10.1093/jxb/45.9.1245.
» http://dx.doi.org/10.1093/jxb/45.9.1245

[4] Conn, S. J., Hocking, B., Dayod, M., Xu, B., Athman, A., Henderson, S., Aukett, L., Conn, V., Shearer, M. K., Fuentes, S., Tyerman, S. D., & Gilliham, M. (2013). Protocol: optimising hydroponic growth systems for nutritional and physiological analysis of Arabidopsis thaliana and other plants. Plant Methods, 9, 4. http://dx.doi.org/10.1186/1746-4811-9-4. PMid:23379342.
» http://dx.doi.org/10.1186/1746-4811-9-4

[5] Corley, R. H. V., & Tinker, P. B. (2003). The oil palm (4th ed.). Oxford: Blackwell Publishing. http://dx.doi.org/10.1002/9780470750971.
» http://dx.doi.org/10.1002/9780470750971

[6] Fageria, N. K., Baligar, V. C., & Jones, C. A. (2010). Growth and mineral nutrition of field crops (3rd ed.). New York: CRC Press. http://dx.doi.org/10.1201/b10160.
» http://dx.doi.org/10.1201/b10160

[7] Fita, A., Nuez, F., & Picó, B. (2011). Diversity in root architecture and response to P deficiency in seedlings of L. Cucumis meloEuphytica, 181, 323-339. http://dx.doi.org/10.1007/s10681-011-0432-z.
» http://dx.doi.org/10.1007/s10681-011-0432-z

[8] García-Palacios, P., Maestre, F. T., Bradford, M. A., & Reynolds, J. F. (2014). Earthworms modify plant biomass and nitrogen capture under conditions of soil nutrient heterogeneity and elevated atmospheric CO concentrations. ₂Soil Biology & Biochemistry, 78, 182-188. http://dx.doi.org/10.1016/j.soilbio.2014.08.002.
» http://dx.doi.org/10.1016/j.soilbio.2014.08.002

[9] Glass, A. D. M. (2003). Nitrogen use efficiency of crop plants: Physiological constraints upon nitrogen absorption. CRC. Critical Reviews in Plant Sciences, 22, 453-470. http://dx.doi.org/10.1080/07352680390243512.
» http://dx.doi.org/10.1080/07352680390243512

[10] Gupta, P. K. (2007). Soil, plant, water and fertilizer analysis (2nd ed.). India: Agrobios.

[11] Hoagland, D. R, & Arnon, D. I. (1950). The water culture method for growing plants without soil (Circular 347). Berkeley: California Agricultural Experiment Station, University of California.

[12] Jones, B., Jr. (2003). Agronomic handbook: management of crops, soils, and their fertility. Florida: CRC Press.

[13] Koorem, K., Gazol, A., Öpik, M., Moora, M., Saks, Ü., Uibopuu, A., Sõber, V., & Zobel, M. (2014). Soil nutrient content influences the abundance of soil microbes but not plant biomass at the small-scale. PLoS One, 9, e91998. http://dx.doi.org/10.1371/journal.pone.0091998. PMid:24637633.
» http://dx.doi.org/10.1371/journal.pone.0091998

[14] Lawlor, D. W., & Cornic, G. (2002). Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants. Plant, Cell & Environment, 25, 275-294. http://dx.doi.org/10.1046/j.0016-8025.2001.00814.x. PMid:11841670.
» http://dx.doi.org/10.1046/j.0016-8025.2001.00814.x

[15] Lobell, D. B. (2007). The cost of uncertainty for nitrogen fertilizer management: a sensitivity analysis. F. Crop. Res, 100, 210-217. http://dx.doi.org/10.1016/j.fcr.2006.07.007.
» http://dx.doi.org/10.1016/j.fcr.2006.07.007

[16] Malaysian Palm Oil Board - MPOB. (2013). Oil palm and the environment. Kajang. Retrieved in 15 July 2014, from http://bepi.mpob.gov.my/index.php/statistics/export/121-export-2013.html.
» http://bepi.mpob.gov.my/index.php/statistics/export/121-export-2013.html

[17] Pardossi, A., Malorgio, F., Incrocci, L., & Tognoni, F. (2006). Hydroponic technologies for greenhouse crops. In R. Dris (Ed.)., Crops: quality, growth and biotechnology. Helsinky: WFL Publisher.

[18] Parry, M. A. J., Flexas, J., & Medrano, H. (2005). Prospects for crop production under drought: research priorities and future directions. Annals of Applied Biology, 147, 211-226. http://dx.doi.org/10.1111/j.1744-7348.2005.00032.x.
» http://dx.doi.org/10.1111/j.1744-7348.2005.00032.x

[19] Peterson, G. A., Unger, W. P., & Payne, W. A. (2006). Dryland agriculture (2nd ed.). Madison: American Society of Agronomy.

[20] Reddy, K. R., Hodges, H. F., & Mckinion, J. M. (1997). Modeling temperature effects on cotton internode and leaf growth. Crop Science, 37, 503-509. http://dx.doi.org/10.2135/cropsci1997.0011183X003700020032x.
» http://dx.doi.org/10.2135/cropsci1997.0011183X003700020032x

[21] Roggatz, U., Mcdonald, A. J. S., Stadenberg, I., & Schurr, U. (1999). Effects of nitrogen deprivation on cell division and expansion in leaves of L. Ricinus communisPlant, Cell & Environment, 22, 81-89. http://dx.doi.org/10.1046/j.1365-3040.1999.00383.x.
» http://dx.doi.org/10.1046/j.1365-3040.1999.00383.x

[22] Tripler, C. E., Kaushal, S. S., Likens, G. E., & Walter, M. T. (2006). Patterns in potassium dynamics in forest ecosystems. Ecology Letters, 9, 451-466. http://dx.doi.org/10.1111/j.1461-0248.2006.00891.x. PMid:16623731.
» http://dx.doi.org/10.1111/j.1461-0248.2006.00891.x

[23] Zhang, F. S., Niu, J., Zhang, W., Chen, X. P., Li, C., Yuan, L., & Xie, J. C. (2010). Potassium nutrition of crops under varied regimes of nitrogen supply. Plant and Soil, 335, 21-34. http://dx.doi.org/10.1007/s11104-010-0323-4.
» http://dx.doi.org/10.1007/s11104-010-0323-4

Treatment level	N1	N2	N3	N4	N5
Concentration (mg L^-1)	50	100	300	600	900
Plant height (cm)	29.10±0.96^bc	33.22±1.02^a	31.62±1.18^ab	28.74±1.55^bc	22.66±2.14^c
Stem diameter (mm)	12.18±0.57^a	11.84±0.72^a	10.36±0.22^ab	8.35±0.50^b	8.30±0.20^b
Leaf no. plant^-1	4.30 ±0.15^ab	4.60 ±0.24^a	4.60± 0.18^a	4.00 ± 0.0^b	3.90 ±0.24^b
Leaf area (cm²)	257.42±13.46^b	383.16±7.69^a	211.98±16.42^c	103.12±4.43^d	70.70±3.02^d
Root shoot ratio	0.14±0.03^b	0.19±0.04^a	0.12±0.02^b	0.10±0.01^b	0.10±0.03^b
SPAD chl value	54.40±1.75^a	57.74±1.25^a	52.40±2.07^a	36.50±1.53^b	22.03± 2.01^b

Treatment level	P1	P2	P3	P4	P5
Concentration (mg L^-1)	15	30	60	90	120
Plant height (cm)	29.56±0.55^a	32.04±1.40^a	29.16±2.21^a	34.50±1.95^a	31.16±2.13^a
Stem diameter (mm)	10.46±0.84^a	11.92±0.29^a	10.34±0.51^a	12.24±0.44^a	11.36±0.74^a
Leaf no. plant^-1	4.60±0.19^ab	5.00±0.10^a	4.20±0.20^b	4.80±0.20^a	4.20±0.20^b
Leaf area (cm²)	193.79 ±2.48^e	353.99± 3.93^c	427.91±1.68^b	654.33±6.02^a	238.73± 2.51^d
Root shoot ratio	0.072± 0.004^e	0.116± 0.004^d	0.148±0.008^b	0.182±0.003^a	0.132± 0.004^c
SPAD chl value	50.17 ± 1.32^b	52.76± 1.70^a	54.62± 2.13^a	55.20±1.04^a	50.36±2.01^b

Plant height (cm)	32.82±0.94^ab	36.53±1.42^a	36.62±1.16^a	30.26±1.06^b	28.52±1.18^b
Stem diameter (mm	13.18±0.80^a	13.72±0.43^a	13.76±0.61^a	11.32±0.23^ab	10.46±0.30^b
Leaf no. plant^-1	4.60±0.39^a	4.70±0.12^a	4.70±0.12^a	3.90±0.10^ab	4.10±0.10^ab
Leaf area (cm²)	289.36±30.23^b	477.56±40.91^a	515.02±32.43^a	302.08±26.28^b	224.92±27.07^b
Root shoot ratio	0.12±0.02^a	0.16±0.02^a	0.16±0.02^a	0.12±0.02^a	0.12±0.02^a
SPAD chl value	49.42±1.30^b	51.66±1.93^b	56.92±1.21^a	49.72±0.83^b	49.52± 2.09^b

Treatment	Level	N nutrition ((g plant^-1, (%))
Treatment	Level	Shoot Dry Wt	Root Dry Wt	Total
N1	50	1.85±0.21^b(86.4)	0.29±0.03^b(13.6)	2.14±0.14^b
N2	100	2.35±0.16^a(84.5)	0.43±0.04^a(16.3)	2.78±0.19^a
N3	300	1.56±0.09^c(89.7)	0.18±0.02^c(10.3)	1.74±0.09^bc
N4	600	1.10±0.14^cd(90.9)	0.11±0.01^c(9.1)	1.21±0.15^cd
N5	900	0.63±0.02^d(90.0)	0.07±0.02^d(10.0)	0.70±0.02^d
		P nutrition (g plant^-1, (%))
		Shoot Dry Wt	Root Dry Wt	Total
P1	15	1.35 ± 0.09^c(86.0)	0.22± 0.04^a(9.4)	1.57± 0.12^c
P2	30	2.36± 0.15^b(86.8)	0.36± 0.03^a(13.2)	2.72± 0.16^ab
P3	60	2.13± 0.05^b(86.6)	0.33± 0.03^a(13.4)	2.46± 0.07^b
P4	90	2.79± 0.17^a(88.3)	0.37± 0.03^a(11.7)	3.16± 0.17^a
P5	120	1.42± 0.12^c(81.1)	0.33± 0.14^a(18.9)	1.75± 0.18^c
		K nutrition (g plant^-1, (%))
		Shoot Dry Wt	Root Dry Wt	Total
K1	50	2.20±0.30^b(87.3)	0.32±0.03^c(12.7)	2.52±0.32^b
K2	100	3.26±0.25^a(86.5)	0.51±0.02^b(13.5)	3.77±0.25^a
K3	300	3.50±0.15^a(85.0)	0.62±0.03^a(15.0)	4.12±0.15^a
K4	600	1.98±0.17^b(88.4)	0.26±0.02^c(11.6)	2.24±0.19^b
K5	900	1.62±0.11^b(87.1)	0.24±0.05^c(12.9)	1.86±0.15^b

Level	Treatment (mg L^-1)	N uptake (mg plant^-1)
Level	Treatment (mg L^-1)	Shoot	Root	Total
N1	50	37.59^ab	8.29^b	45.88^ab
N2	100	58.03^a	13.39^a	71.43^a
N3	300	51.78^ab	9.18^ab	60.96^ab
N4	600	39.07^ab	5.28^bc	44.35^bc
N5	900	31.05^b	3.08^c	34.13^c
		P uptake (mg plant^-1)
		Shoot	Root	Total
P1	15	5.62^b	5.36^a	10.98^b
P2	30	8.64^b	2.33^a	10.97^b
P3	60	9.78^b	2.00^a	11.78^b
P4	90	20.38^a	3.04^a	23.40^a
P5	120	12.21^b	1.52^a	13.72^a
		K uptake (mg plant^-1)
		Shoot	Root	Total
K1	50	84.69^b	8.55^c	93.24^c
K2	100	118.11^b	22.77^ab	140.88^ab
K3	300	181.04^a	33.29^a	214.33^a
K4	600	125.16^ab	16.32^bc	141.48^bc
K5	900	180.62^a	30.11^abc	320.41^ab

Brasil

Brasil

Determination of optimum levels of nitrogen, phosphorus and potassium of oil palm seedlings in solution culture

Abstract

1 INTRODUCTION

2 MATERIAL AND METHOD

Study site and plant materials

Growth conditions, treatments and experimental design

Data collection on growth r parameters

Biomass measurement

Sample preparation and analysis

Statistical analysis

3 RESULTS AND DISCUSSION

Effect of nitrogen levels on oil palm seedlings growth

Effect of phosphorus levels on oil palm seedlings growth

Effect of potassium levels on oil palm seedlings growth

Effect of N, P2O5 and K2O nutrition on dry weight, total biomass and proportion of biomass partitioning

Effect of N, P2O5 and K2O nutrition on the nutrient uptake, nutrient concentration and nutrient partitioning in plant parts

Effect of N, P2O5 and K2O nutrition on nutrient concentration and nutrient partitioning in plant parts

4 CONCLUSION

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History

Treatment Level	N (%)				P (%)				K (%)				Total (%)
	Shoot		Root		Shoot		Root		Shoot		Root
	Conc ^* * Conc = Concentration, Part = Partitioning.	Part ^* * Conc = Concentration, Part = Partitioning.	Conc	Part	Conc	Part	Conc	Part	Conc	Part	Conc	Part
N1	2.11±0.23^c	32.4	3.18±0.21^c	7.0	3.69±0.49^b	5.7	0.62±0.01^a	1.4	2.74±0.04^ab	42.1	5.19±0.13^ab	11.4	100
N2	2.88±0.03^b	38.3	3.62±0.19^c	8.9	3.50±0.19^b	4.7	0.66±0.01^a	1.6	2.46±0.14^abc	32.7	5.57±0.36^a	13.7	100
N3	3.37±0.13^b	44.3	4.96±0.37^b	7.9	4.96±0.37^a	6.5	0.64±0.01^a	1.2	2.41±0.14^bc	31.7	4.60±0.14^b	8.3	100
N4	3.53±0.10^b	27.0	4.93±0.09^a	6.0	4.38±0.45^ab	5.5	0.64±0.01^a	0.8	2.88±0.18^a	36.5	5.28±0.04^ab	6.5	100
N5	4.93±0.43^a	39.0	4.64±0.05^ab	5.9	4.10±0.17^ab	4.9	0.54±0.01^b	0.7	2.14±0.08^c	25.6	3.05±0.43^c	3.9	100
P1	2.75±0.28b^c	35.8	4.27±0.08^a	10.3	0.38±0.04^b	4.9	1.84±1.33^a	4.4	2.67±0.28^a	34.7	4.07±0.17^b	9.8	100
P2	2.50±0.08^c	39.2	4.36±0.27^a	12.2	0.38±0.01^b	6.0	0.58±0.03^a	1.6	1.88±0.05^b	29.5	4.13±0.10^b	11.5	100
P3	2.39±0.08^c	38.5	4.28±0.13^a	9.8	0.42±0.02^b	6.8	0.60±0.02^a	1.4	2.00±0.09^b	32.2	4.98±0.29^a	11.4	100
P4	3.50±0.10^a	42.4	4.39±0.03^a	9.3	1.00±0.13^a	12.2	0.87±0.00^a	1.8	1.99±0.11^b	24.1	4.79±0.17^a	10.1	100
P5	3.11±0.15^ab	44.4	4.51±0.24^a	4.8	0.51±0.02^b	7.3	0.85±0.06^a	0.9	2.60±0.17^a	37.2	4.99±0.06^a	5.3	100
K1	4.76±0.08^b	48.4	4.47±0.08^ab	5.1	0.90±0.07^ab	9.1	0.60±0.06^a	0.7	3.27±0.07^d	33.3	3.04±0.32^c	3.4	100
K2	6.11±0.12^a	47.7	5.09±0.09^a	6.3	1.15±0.12^ab	9.0	0.90±0.01^a	1.1	3.84±0.07^d	30.0	4.64±0.19^bc	5.8	100
K3	6.01±0.23^a	42.9	4.47±0.08^ab	5.4	1.19±0.13^a	8.5	0.78±0.13^a	0.9	5.00±0.40^c	35.7	5.49±0.10^b	6.6	100
K4	5.53±0.41^ab	39.9	3.84±0.17^bc	3.3	0.88±0.08^ab	6.3	0.70±0.04^a	0.6	6.11±0.17^b	44.0	6.80±0.38^ab	5.9	100
K5	5.63±0.35^ab	31.0	3.64±0.36^c	2.8	0.86±0.00^b	4.7	0.71±0.05^a	0.6	9.95±0.39^a	54.7	7.91±1.51^a	6.2	100