Influences of irrigation frequency on the growth and flowering of chrysanthemum grown under restricted root volume were tested. Chrysanthemum cuttings (Chrysanthemum morifolium “Reagan White”) were grown in seedling tray which contained coconut peat in volumes of 73 and 140 cm3. Plants were irrigated with drip irrigation at irrigation frequencies of 4 (266 mL), 6 (400 mL), and 8 (533 mL) times/day to observe their growth and flowering performances. There was interaction between irrigation frequency and substrate volume on plant height of chrysanthemum. Plants grown in 140 cm3 substrates and irrigated 6 times/day produced the tallest plant of 109.25 cm. Plants irrigated 6 and 8 times/day had significantly higher level of phosphorus content in their leaves than those plants irrigated 4 times/day. The total leaf area, number of internodes, leaf length, and leaf width of chrysanthemums grown in 140 cm3 substrate were significantly higher than those grown in 73 cm3 substrate. The numbers of flowers were affected by both irrigation frequencies and substrate volumes. Chrysanthemums irrigated 8 times/day had an average of 19.56 flowers while those irrigated 4 times/day had an average of 16.63 flowers. Increasing irrigation frequency can improve the growth and flowering of chrysanthemums in small substrate volumes.
1. Introduction
Many soilless systems have been studied for growing cut chrysanthemums. However, the production of chrysanthemum in soilless culture still has some problems to be resolved. Chrysanthemum grown in hydroponic systems was easily infected by Pythium [1, 2]. Growing them in substrate had greater possibility for commercial production such as in sand culture [3]. However, using a high amount of substrate will increase production costs for replacing the substrate. Reducing substrate volume can be a possible solution for production in substrate culture [4]. To date, there have been few studies on the growth and flowering response of cut chrysanthemums in substrates of limited volume.
Restricted root volume will limit water and nutrient availability. Many studies have reported that higher frequencies of irrigation can improve plant growth in such limited substrates [5, 6]. High irrigation frequency can maintain moisture content at the root zone of plants grown in restricted substrate volume [7]. Moreover, high irrigation frequency can improve the uptake of nutrients through the replenishment of nutrients in the root zone and improve transport of nutrients by mass flow [8]. Röber and Hafez [9] found that chrysanthemum grown in substrates with high moisture produced high weights of shoots and flowers.
Chrysanthemums that were grown in rockwool and given nutrients 1 or 3 times/day produced satisfactory growth [10]. In the case of nutrient film technique, vegetative growth of chrysanthemums in substrates of volume less than 100 mL can be maintained by fertigation 8 times/day [11]. Gisleröd [12] found that irrigation frequency for growing cut chrysanthemum in substrate depended on the season and variety. The optimal frequency of irrigation should be tested for different substrates [13]. This experiment investigated the effects of irrigation frequency on the growth and flowering of cut chrysanthemum grown in restricted root volumes.
2. Materials and Methods
The experiment was conducted from March, 2014, to June, 2014, at Agro Technology Park, Malaysia Agriculture and Development Institute, Pahang, Malaysia, in a shade house with an average temperature of 25.8°C and relative humidity of 70.50%. Rooted cuttings of Chrysanthemum morifolium “Reagan White” were grown in coconut peat at 73 and 140 cm3 volumes contained in seedling trays and a plant density of 64 plant/m2. Plants were irrigated with a nutrient solution by drip irrigation at frequencies of 4 (266 mL), 6 (400 mL), and 8 (533 mL) times/day. The nutrient solution used in the irrigation system from the first week to the seventh week included N 250, P 30, K 200, Ca 150, Mg 50, Fe 1.05, Mn 0.58, Zn 0.35, B 1, Cu 0.05, and Mo 0.05 mg/L. After the seventh week and until harvest, the nutrient solution contained N 200, P 30, K 200, Ca 150, Mg 50, Fe 1.05, Mn 0.58, Zn 0.35, B 1, Cu 0.05, and Mo 0.05 mg/L. The pH of the nutrient solution was maintained between 5.5 and 6.5 and the electric conductivity (EC) was 1.3–1.5 mS/cm. Night break was provided for 8 weeks from 11.00 pm. to 3.00 am.
Plant growth parameters such as plant height, stem diameter, leaf length, and leaf width were measured from two plant samples. Total leaf number and number of internodes were also counted. Root length was measured by using WinRHIZO, image analysis program (Regent instruments, Canada). Plant samples were dried in an oven at 70°C at least 48 hours, from which the dry weights of leaves, stems, roots, and flowers were determined. Leaf area was measured by Li-3100 area meter (LiCor Biosciences, USA). Leaf water potential was measured from fully expanded leaves by using a pressure chamber (Skye Instruments, UK) every two week and averaged means were used. Chlorophyll fluorescence was measured by Handy PEA (Hansatech Instruments, UK) to observe plant stress. Fully expanded leaf blades were darkened for 15 minutes by leaf clip. Sensor head was attached to the leaf clip, the shutter was opened and maximum quantum efficiency (Fv/Fm) was recorded.
Dry leaves at 14 weeks were ground and digested for nutrient analysis. Nitrogen (N) and phosphorus (P) were analyzed by autoanalyzer QuickChem 8000 (Lachat instruments, USA) and potassium (K), calcium (Ca), and magnesium (Mg) were analyzed using PerkinElmer 3110 atomic absorption spectrophotometer (PerkinElmer, USA).
At the point of harvesting, inflorescence diameter, number of flowers, number of petals, and flower diameter were observed. Lightness, chroma, and hue value of petal from three inflorescences were determined by CR-400 chroma meter (Konica Minolta, Japan). Stems of two flowers at a length of 35 cm were put in distilled water 300 mL at 25±1°C, relative humidity 50–55%, and light intensity 1.3 μmol m−2 s−1 for 10 hours per day to observe vase life.
Analysis of variance was calculated by SAS statistical software and means were compared by Tukey’s test at P<0.05.
3. Results and Discussion
There were significant interactions between irrigation frequency and substrate volume on plant height of chrysanthemum grown in substrate culture. As shown in Figure 1, greater substrate volume resulted in taller plant as compared to lower substrate volume at irrigation frequencies 4 and 8 time/day. The tallest plant of 109.25 cm was obtained from chrysanthemum grown in 140 cm3 irrigated 6 times/day. This corresponded with previous result with marigold by Latimer [14] who reported that increasing container volume resulted in higher plant heights. However, plant heights of chrysanthemum grown in all substrate volumes were lower than those grown in soil (data not shown). This may be due to the stress conditions present for plants grown under restricted root volumes.
Interaction effects of irrigation frequencies and substrate volumes on plant height of chrysanthemum.
Chlorophyll fluorescence efficiency or Fv/Fm values were not significantly different between substrate volumes or irrigation frequencies (Tables 1 and 2). Chrysanthemums grown in all volumes and at all irrigation frequencies had average Fv/Fm values that were lower than the average value of 0.84 of normal plants [15]. This result confirms that the plants experienced some stress. Chlorophyll content did not differ significantly by either variable. Both substrate volumes and irrigation frequencies influenced the water potential in the leaves, but those differences were not significant (Figure 2).
Effect of substrate volumes on chlorophyll fluorescence efficiency (Fv/Fm) and chlorophyll content.
Substrate volume (cm3)
73
140
Fv/Fm
0.68a
0.73a
Chlorophyll content
53.25a
53.99a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Effect of irrigation frequencies on chlorophyll fluorescence efficiency (Fv/Fm) and chlorophyll content.
Irrigation frequency (times/day)
4
6
8
Fv/Fm
0.70a
0.69a
0.73a
Chlorophyll content
53.21a
54.12a
53.53a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Interaction effects of irrigation frequencies and substrate volumes on water potential in leaves of chrysanthemum.
The substrate volumes had pronounced effects on growth characteristics (Table 3). Even stem diameters did not differ significantly between two substrate volumes. Chrysanthemum grown in substrate volumes of 140 cm3 had a larger number of internodes. Furthermore, total leaf area and number of leaves correlated to substrate volume. Leaf area of plants grown in 140 cm3 was higher than that in 73 cm3 by 69%. This result was in agreement with other findings that found that increased substrate volume led to an increase in leaf area of chrysanthemum [11] and marigold [14]. Increasing substrate volume also increased leaf length and leaf width. Irrigation frequency, on the other hand, did not significantly affect shoot growth (Table 4). Differences between irrigation frequencies were not observed on stem diameter, number of internodes, leaf area, leaf number, leaf length, and leaf width. Substrate volume and irrigation frequency had an interaction effect on root length of chrysanthemum. However, there was no significant difference between each level of treatments alone but larger volumes tended to have longer root (Figure 3).
Effect of substrate volumes on shoot growth of chrysanthemum.
Substrate volume (cm3)
73
140
Stem diameter (cm)
0.57a
0.58a
Number of internodes
38.63b
44.75a
Leaf area (cm2)
487.69b
825.15a
Leaf number
67.33b
89.29a
Leaf length (cm)
9.22b
11.38a
Leaf width (cm)
5.21b
6.20a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Effect of irrigation frequencies on shoot growth of chrysanthemum.
Irrigation frequency (times/day)
4
6
8
Stem diameter (cm)
0.58a
0.58a
0.58a
Number of internodes
40.19a
44.25a
40.63a
Leaf area (cm2)
577.28a
693.84a
698.14a
Leaf number
67.69a
86.81a
80.44a
Leaf length (cm)
9.91a
10.73a
10.26a
Leaf width (cm)
5.56a
5.96a
5.59a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Interaction effects of substrate volumes and irrigation frequencies on root length of chrysanthemum.
There was an interactive relationship between substrate volumes and irrigation frequencies upon the levels of nitrogen in leaves. When irrigated 4 times/day, nitrogen levels in smaller substrate volumes were higher than those in larger substrate volumes (Figure 4). When irrigated 6 and 8 times/day, there was no significant difference between the substrate volumes.
Interaction effects of substrate volumes and irrigation frequencies on nitrogen level of chrysanthemum.
Substrate volume did not show significant differences for levels of phosphorus, potassium, calcium, and magnesium in the leaves of chrysanthemum (Table 5). But phosphorus level was influenced by irrigation frequency. Chrysanthemum irrigated 6 and 8 times/day had significantly higher phosphorus levels than when irrigated 4 times/day (Table 6). This result indicates that higher irrigation frequencies can improve availability of phosphorus [16]. On the other hand, potassium, calcium, and magnesium levels were not influenced by irrigation frequencies.
Effect of substrate volumes on phosphorus, potassium, calcium, and magnesium level in leaves of chrysanthemum at 14 weeks after transplanting.
Substrate volume (cm3)
73
140
P (%)
0.25a
0.25a
K (%)
4.43a
5.29a
Ca (%)
1.45a
1.58a
Mg (%)
0.23a
0.27a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Effect of irrigation frequencies on phosphorus, potassium, calcium, and magnesium level in leaves of chrysanthemum at 14 weeks after transplanting.
Irrigation frequency (times/day)
4
6
8
P (%)
0.14b
0.17a
0.17a
K (%)
2.68a
3.07a
3.16a
Ca (%)
1.18a
1.17a
1.22a
Mg (%)
0.25a
0.25a
0.26a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Substrate volumes and irrigation frequencies influenced dry weight partitioning between plant parts. Increasing substrate volume increased leaf, stem root, flower, and total dry weight significantly as shown in Table 7. The increasing of root dry weight confirmed previous result by Goto et al. [11] who found that root dry weight of chrysanthemum increased with an increase of substrate volume. Total dry weight in 140 cm3 had total dry weight of 24.16 g, which was higher than in 73 cm3 by 47.13%.
Effect of substrate volumes on leaf dry weight, stem dry weight, root dry weight, flower dry weight, and total dry weight.
Substrate volume (cm3)
73
140
Leaf (g)
3.44b
5.07a
Stem (g)
10.66b
15.60a
Root (g)
0.40b
0.67a
Flower (g)
1.92b
2.82a
Total (g)
16.42b
24.16a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Chrysanthemums irrigated 6 and 8 times/day had higher leaf dry weight, stem dry weight, and total dry weight than those irrigated 4 times/day as shown in Table 8. Schuch et al. [17] reported that chrysanthemums grown with high rates of irrigation produced higher stem dry weight than those obtained with lower irrigation frequency while root dry weight did not differ between irrigation frequencies. Chrysanthemum irrigated 8 times/day produced the highest flower dry weight. For total dry weight, plants irrigated 6 and 8 times/day were significantly higher than those irrigated 4 times/day by a factor of 32% and 23%. Katsoulas et al. [18] also founded that increasing irrigation frequency increased total dry mass of rose.
Effect of irrigation frequencies on leaf dry weight, stem dry weight, root dry weight, flower dry weight, and total dry weight.
Irrigation frequency (times/day)
4
6
8
Leaf (g)
3.68b
4.85a
4.23a
Stem (g)
10.96b
14.91a
13.52a
Root (g)
0.50a
0.58a
0.53a
Flower (g)
2.02b
2.29ab
2.78a
Total (g)
17.16b
22.64a
21.07a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
The number of flowers was affected by both substrate volumes and irrigation frequencies (Tables 9 and 10). When grown in 140 cm3, there were 33% more flowers than in 73 cm3. Irrigation 8 times/day produced the highest number of flowers, an average of 20.44. However, inflorescence diameter, flower diameter, number of petals, flower color, and vase life were not significantly influenced by either irrigation frequency or substrate volume. This outcome accorded with the studied one in gerbera, in which flower diameter was not influenced by irrigation frequency [19]. Carvalho et al. [20] noted that flower size of chrysanthemum was mainly influenced by genetic inheritance.
Effect of substrate volumes on flowering characteristics of chrysanthemum.
Substrate volume (cm3)
73
140
Inflorescence diameter (cm)
12.57a
13.52a
Number of flowers
16.21b
21.54a
Flower diameter (cm)
6.37a
6.06a
Number of petals
25.50a
25.35a
Flower color
Lightness
75.92a
77.05a
Chroma
2.93a
2.96a
Hue
81.33a
83.84a
Vase life (days)
20.96a
21.21a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
Effect of irrigation frequencies on flowering characteristics of chrysanthemum.
Irrigation frequency (times/day)
4
6
8
Inflorescence diameter (cm)
11.92a
13.59a
13.62a
Number of flowers
16.63b
19.56ab
20.44a
Flower diameter (cm)
5.71a
6.19a
6.76a
Number of petals
26.31a
25.33a
24.63a
Flower color
Lightness
70.76a
81.40a
77.30a
Chroma
2.67a
3.17a
3.00a
Hue
78.76a
86.66a
82.33a
Vase life (days)
21.19a
20.81a
21.25a
Values in each column accompanied by different letters differ significantly at P<0.05 by Tukey’s test.
4. Conclusions
Results from this experiment demonstrated that irrigation frequencies of 6 and 8 times/day can improve plant growth and flowering characteristics such as plant dry weight and number of flowers of chrysanthemum plants grown under restricted root conditions. This may be attributable to a higher availability of nitrogen and phosphorus. We conclude that for cultivation efficiency, an irrigation frequency of 6 times/day can be suggested for growing chrysanthemums under restricted root volume.
However, further studies are required to confirm that increasing the irrigation frequency can improve plant growth under restricted conditions.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
This research was supported by the Southeast Asian Regional Center for Graduate Study and Research in Agriculture (SEARCA) and Malaysian Agricultural Research and Development Institute (MARDI).
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