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Abstract

Green cabbage, water spinach, and spinach are important vegetables in the diet of the Ambonese communities, so the vegetables have economic value and contribute to the inflation of Ambon City. The main obstacle for optimizing leafy vegetables in urban farming of Ambon City in Ambon Bay neighborhood is excess water during the rainy season which possibly induces plant diseases and reduces the yield. The purpose of this study was to verify the 11-year weather of Ambon Bay; and the adaptation of vegetable farmers in Ambon City to the change of rainy season as well as precipitation in the study location The research was conducted using a qualitative descriptive method based on interviews with farmers supported by climate data for 11 years. This study explains that the rainfall was variable during 10 years; In 2010-2013 and 2017-2020, the annual rainfall was 3.950-5.264, while in 2014-2016 it ranged from 2.017-2.995 mm.  Farmers adapt to high rainfall by installing plastic rain shelters, shortening the planting distance from 20 cm to 10 cm, and changing the planting calendar. However, in general growers install rain shelters during vegetable cultivation in the wet season resulting in high productivity of leafy vegetables.

Keywords: Climate, Disease incidence, Planting distances, Rain shelter, Rainfall, Yield.

Received: 7 October 2023/ Revised: 10 December 2023/ Accepted: 20 December 2023/ Published: 29 December 2023

Contribution/ Originality

This is the first published-study related to the adaptation of vegetable grower in Ambon Bay to the change of rainfall. High rainfall in Ambon is suggested to change the leafy-vegetable cultivation practice but the rainfall data was not published; and the way of farmer change their cultivation in order to mitigate high precipitation has not been published. The results of study contribute to the improving method of growing vegetable in rainy season.

1. INTRODUCTION

The main livelihood of Maluku Province is agriculture, which is practiced in almost every district, even though the land area is limited compared to Java Island. The total area of Maluku Province is 712,480 km2 but 2.4% is the ocean. In 2010, the population of Maluku was 1.533.506 and there was an increase of approximately 22.7% population resulting to 1.881.727 people in 2022. Currently, Maluku still imports raw food particularly vegetables and meats from outside the province including North Sulawesi, South Sulawesi, and East Java. However, Maluku province is self-sufficiency in leafy vegetables; the consumptions of green cabbage (Brassica juncea L.), water spinach (Ipomoea Aquatica Forsk), and Indonesia’s spinach (Amaranthus spp.) become a food habit.

Commonly, farmers grow leafy vegetables throughout the year with a monocropping system on small-scale vegetable farms.  The vegetable production in Ambon Bay stretches from Paso, Nania, and Waiheru to Hative Besar village. Vegetable production throughout the Ambon Bay has a significant impact on communities’ revenue and the local economy.  The challenges for maintaining and increasing the vegetable yield in the study area are low soil properties, high rainfall in certain months, and changes in the rainy season that increase the soil and air-borne disease intensity. The high demand for leafy vegetables during the wet season caused inflation in two cities of Maluku, namely Ambon and Tual due to its limited production and supply.

The agricultural area at the low altitude of Ambon Island is adjacent to the coast; the soil is formed from Alluvial parent material [1] so the soil texture is loamy sand with good drainage. In general, the soil area in Waiheru is Entisols with low soil fertility; the soil contained low organic-C (1.6-1.76%), low total N (0.12-0.14%) with low P2O5 availability; The pH is slightly acidic 5.5-5.8 [1]. Farmers depend on inorganic fertilizers to increase soil N and P availability during vegetable cultivation. Nitrogen (N) and Phosphorus (P) are the major essential macronutrients that increase the above-ground biomass, growth and productivity of crops. It is well known that nitrogen and phosphorus fertilization correlate significantly with chlorophyll and the biochemical constituent of leaves [2-4].

High rainfall in Ambon Bay is strongly related to plant diseases; according to the local Meteorological Office, changes in the rainy season and dry season as well as higher rainfall have occurred.  Southeast Asia as well as the Pacific Islands will be affected by climate change in the next decades due to the growing population, long coastlines, and low altitude area [5]. Farmer's reliance on the agricultural sector and high dependency on natural resources increase the impact of climate change in such areas. Climate change has a severe impact on the average temperature and precipitation; increases of floods and droughts, hence the economic growth [6].

A small discussion with vegetable farmers in Ambon Bay in 2018 and 2021 revealed lower yield and revenue during rainy-season vegetable cultivation. At that time small communities of farmers installed rain shelters to avoid high precipitation but the plastic price was not affordable so they depended on the Corporate Social Responsibility program of the Central Bank of Indonesia. The intensity of certain diseases in tropical agricultural areas in the rainy season is higher than in the dry season due to the high rainfall [7-9]. Despite the constraint of vegetable production in rainy seasons, the farmer's adaptability to high precipitation in maintaining vegetable productivity in Ambon Bay has not been studied. The objective of this descriptive research was to 1) confirm the climatic variation – mainly related to the rainfall – in the Ambon Bay area over 11 years, 2) get information from the farmers concerning the way to cope up with the change of wet season, and 3) inventory the plant diseases in the wet season.

2. MATERIALS AND METHODS

The study was conducted in the Waiheru village in Ambon City at an altitude of 4 m above sea level with the geographical coordinates of -3.628805, and 128.2214317 (Figure 1). To confirm the change in rainy season and rainfall, the Pattimura Meteorological Station at Laha of Ambon provided sets of daily weather data from 2010-2020. The station measures the daily weather of Ambon Bay and is located in the geographical position of -3.7110876 S, 128.0828262 E. The office provides temperature, humidity, rainfall, rainy days, and days of sunshine data. The annual weather elements and monthly rainfall are calculated based on daily data and depicted in the Tables.

Primary data related to the productivity of green cabbage, water spinach, and spinach was collected from 10 vegetable farmers of Waiheru Village. A Focus Group Discussion (FGD) was done involving farmers in Waiheru Villages in 2018 and 2023. The information obtained from FGD was the general method of vegetable cultivation, mainly the use of rain shelter and organic matter application, as ways to reduce the disease attack and crop growth failure during the rainy season. The discussion also included the vegetable production and quality during higher precipitation; and their profit compared to the dry season. A field survey has been conducted to identify common diseases in the vegetable areas of Ambon during the rainy season.

Figure 1. Study location in Waiheru Village of  Ambon Bay , Maluku Province

Source:

ArcGis online.

3. RESULTS AND DISCUSSIONS

3.1. Annual Weather inAmbon Bay

Weather in Ambon Island for 10 years has been quite consistent with minor changes in temperature and humidity throughout the year, however there is a major change in the rainfall variation (Table 1). The average temperature is constant 26-270C but the maximum temperature was likely decreased in 2019 and 2020. The annual rainfall in Ambon was huge; during ten years, the annual rainfall was approximately 3.617 mm. The rainy day lasted approximately 250 days, which is almost two-thirds of the year.

Table 1. The annual weather in Ambon Bay from 2010-2020 calculated from daily data.

Weather elements

2010

2011

2012

2013

2014

2015

2016

2017

2018

2019

2020

Av. temperature (0C)

26.7

26.2

26.4

26.5

26.6

26.5

27.3

26.5

26.9

26.7

27.05

Max.  temperature (0C)

30.7

29.7

29.9

29.8

30.2

30.8

31.9

30.8

30.9

28.3

28.7

Humidity (%)

86

86

86

86

84

83

84

86

83

83.25

84

Days of sunshine (%)

56

50

55

56

59

66

63

48

57

55

52

Rainfall (mm)

3,932

4,610

5,042

5,147

2,592

2,017

2,995

5,435

3,948

2,303

4,518

Rainy day 

257

257

232

235

229

210

215

280

252

261

265

Source:

Pattimura meteorological office of Laha, Ambon.

According to Oldeman Climate Classification, the wet month is a month with rainfall over 200 mm, the dry month is a month with rainfall less than 100 mm, and the humid month has rainfall in between [10]. The average of the wet and dry months in a row is 7.5 and 1.6 respectively; the Climate type of Ambon Bay according to Oldeman climate type is B1.

Indonesia’s Meteorological Office classified the monthly rainfall into three categories: low (0 – 100 mm), medium (100 – 300 mm), high (300 – 500 mm), and very high (>500 mm). Table 2 shows that precipitation in Ambon Island is dominated by medium to high rainfall. In the wet season, the rainfall was mostly very high. The pattern of rainfall during 10 years was changed (Table 2).

Table 2. Annual rainfall in Ambon Bay from 2010-2020 calculated from daily data.

Month

Rainfall (mm)

2010

2011

2012

2013

2014

2015

2016

2017

2018

2019

2020

January

166

228

100

252.1

307

160

71

284

236

234.8

98.6

February

32

202

119

194.8

177

196

34

152

120

47.1

81.8

March

109

127

298

77.6

62

120

153

143

203

221.4

176.8

April

113

240

80

166.9

155

298

355

129

292

315.5

87.3

May

353

1468

908

295.1

418

180

239

753

797

267.7

679.5

June

833

691

1252

359.6

386

718

199

1430

847

534.4

960.2

July

763

694

1157

1923.1

225

164

914

1046

542

272

842.1

August

849

323

639

629.3

448

70

347

452

299

95.9

302.2

September

213

304

254

360

117

3

342

501

411

101.6

573.6

October

106

143

136

128.5

128

67

185

180

29

171.8

440.6

November

146

44

25

91

32

14

37

18

27

27.4

137.1

December

276

147

75

220.2

137

118

119

176

146

14.2

138.3

Total

3,959

4,611

5,043

4,698.2

2,592

2,108

2,995

5,264

3,949

2,303.8

4,518.1

Note:

*According to Oldeman classification.

Source:

Pattimura meteorological office of Laha, Ambon.

The monthly rainfall in 2014-2016 was lower than other years of 2010-2020. The wet season lasted for 8 consecutive months with 3 months in a row of very high rainfall in 2020. However, heavy rainfall in 2010 lasted for 4 months between May to August. There are only two seasons in Ambon: wet (rainy) season (West Season) and dry season (East Season) with two transition periods. During 10 years, the transition period from the wet to dry season was November-December; and from the dry to wet season was March to April. 

3.2. Cultivation Methods

3.2.1. Planting Distance

The farmers in Ambon transplanted the green cabbage seedlings with a shorter planting distance (Figure 2) compared to the recommended distance given by the Research and Development Institute of the Indonesia, Ministry of Agriculture. They preferred shorter distances (20 cm x 20 cm) since the green cabbages were harvested on 19-21 days instead of 30 days. This is related to the preference of consumers who like low-content fiber vegetables in their daily diet. In the rainy season, the planting distance of green cabbage becomes shorter (10 cm x 10 cm) to avoid the water splashing from the soil surface to the leaves. Some growers planted water spinach in rows of 10-15 cm but usually water spinach and spinach were grown by broadcasting method with various planting distances ranging from 1-2 cm resulting in dense population (Figure 2).

3.2.2. Rain Shelter

The productivity of leafy vegetables grown without rain shelter were lower compared to that grown under a plastic rain shelter; the green cabbage yield reduced up to 77%, water spinach by 51%, and spinach  by 43%. However, the productivity of leafy vegetable under a plastic rain shelter (Figure 2) was still lower compared to that in the dry season since the light intensity is lower and reduces photosynthesis. If the green cabbage is grown in the wet season and without any rain-shelter, its yield is observed to be reduced by 50% compared to the wet season crop grown under rain shelter.

Figure 2. Dense population of green cabbage (b) under the rain shelter.

3.3. Plant Diseases

The pathogens as shown in Table 3, are most common pathogens attacking leafy vegetables throughout the year in Ambon. Disease intensity during wet-season vegetable cultivation was high mainly in the field without rain shelter.

Table 3. Common diseases during vegetable cultivation in the wet season.

Diseases

Target organs

Pathogens

Damping off

Stem base

Rhizoctonia solani (Fungi)

Leaf blight

Leaves

Rhizoctonia solani (Fungi)

Wilt disease

Stem base

Sclerotium rolfsi  and fusarium oxysporum (Fungi), Pseudomonas solanacearum and Erwinia caratofora (Bacteria)

White rust

Leaves

Albugo sp. (Not true fungi; eumycota)

Damping off and leaf blight are soil-borne diseases commonly found in leafy vegetables; both of them were caused by Rhizoctonia solani fungi. Vascular wilt disease is caused by soil potential pathogens that results in plant wilting and loss of vigor. White rust is mainly found in water spinach leaves grown in Ambon; this is an important disease of Cruciferous vegetables (Family Brassicaceae) caused by Albugo candida; the oomycetes.

4. DISCUSSION

A dense plant population reduces the risk of splashing soil droplets to the leaves that might contain pathogenic microbes. Even though most of the bacteria were removed by runoff water, soil-borne microbes might cause plant pathogens [11].  Moreover, warmer temperatures in the tropics increase the proliferation of soil and air-borne potential plant pathogens [12]. The yield of leafy vegetables largely depends on the light intensity and day of sunshine; the benefits of using rain shelter for growing vegetable is reported to improve crop performance compared to the outdoor environment [13-15]. However, in Ambon the high rainfall results in cloudy days that reduce the light intensity. For vegetable cultivation, the light intensity is prominent to increase plant height, leaf numbers, leaf area, net assimilation rate, and relative growth rate of spinach, Spinacia oleraceae L [14]. 

The weight of a 50 cm bunch of green cabbage under a rain shelter was 100-150 g, but in the dry season about 300 g. Based on the FGD with farmers in Waiheru, the vegetable price in the rainy season was lower compared to 6-7 years ago since most farmers in Ambon now use rain shelters in the high-precipitation season. The Chinese cabbage growers in Mississippi operate small- to medium-sized farms by using polyethylene (plastic) tunnels in winter producing the highest marketable yield than those without tunnels [16]. In Indonesia, rain shelter in the wet season causes higher shoots and more branches of chili [17]. However, the production of leafy vegetable in Ambon during the rainy season under rain shelter was reduced.

Plant pathogen virulence, survival, and reproduction are influenced by temperature and humidity; the concept in plant pathology is the result of interaction between pathogens, host plants, and the environment [18]. The severity of damping-off in Ambon increased in the rainy season; the higher virulence and reproduction of R. solani is likely caused by the alternate low-high temperature combined with soil water availability. The temperature range for R. solani growth is 20 to 30oC with optimal temperature at 25oC [19] which is actually observed prevailing temperature of Ambon. In the wet season soil water is ample; even though the virulence of R. solani was not determined by soil moisture; the pathogen could not survive even in the extremely dry soils [20].  The soil in the study area is loamy sand with good drainage. Puddled situation is not common in the study area, even during high rainfall events.

In general, plant disease intensity is increased by high air humidity, and high soil moisture which occurs in the rainy season [18]. The virulence of the fungus Sclerotiorum has a positive correlation with the air humidity increases [21]. In the rainy season, the duration of the water presence in the leaves is longer; resulting in disease development on the leaf's surface [22]. In general, sunny weather is observed after the rainy days in Ambon, this increase the disease development in leaves. Rain shelters significantly reduce the soil and air humidity and the pathogen proliferation in soil and hence reduce the disease intensity.

5. CONCLUSION

According to the monthly climate data, high climatic variability has occurred in Ambon; there was a fluctuation of rainfall during 11 years (2010-2020). The rainfall ranged from 2,108 in 2015 to 5,264 in 2017, and the average rainfall was 3.617 mm.  The low productivity in the rainy season in Ambon is likely not only caused by high rainfall but also by cloudy days that induce low light intensity. Rain shelter installation and shorter planting distances are local cultivation practices to avoid high disease intensity, but it doesn’t increase the yield during the wet season. Nonetheless, by using both cultivation practices, vegetable cultivation can be conducted all year round, either in the dry season or wet season.

Funding: This research is supported by Universitas Padjadjaran (Grant number: 542/UN6/WR3/2018).
Institutional Review Board Statement: Not applicable.
Transparency: The authors state that the manuscript is honest, truthful, and transparent, that no key aspects of the investigation have been omitted, and that any differences from the study as planned have been clarified. This study followed all writing ethics.

Competing Interests: The authors declare that they have no competing interests.

Authors’ Contributions: The concept and design of the study, R.H., M.K. and S.B.; provide and analyzed the weather data, R.S.S. and W.P.; wrote the manuscript, R.H. and S.B. All authors have read and agreed to the published version of the manuscript.

REFERENCES

[1]          R. Hindersah, N. Kurniati, A. M. Kalay, and R. Robasu, Vegetable cultivation in Ambon City: Urban agriculture. Bandung: Publication Logoz, 2019.

[2]          I. D. J. M. Viégas et al., "Growth and visual symptoms of nutrients deficiency in mangosteens (Garcinia mangostana L.)," American Journal of Plant Sciences, vol. 9, no. 5, pp. 1014-1028, 2018.  https://doi.org/10.4236/ajps.2018.95078

[3]          A. Siedliska, P. Baranowski, J. Pastuszka-Woźniak, M. Zubik, and J. Krzyszczak, "Identification of plant leaf phosphorus content at different growth stages based on hyperspectral reflectance," BMC Plant Biology, vol. 21, pp. 1-17, 2021.  https://doi.org/10.1186/s12870-020-02807-4

[4]          A. Fathi and E. Zeidali, "Conservation tillage and nitrogen fertilizer: A review of corn growth and yield and weed management," Central Asian Journal of Plant Science Innovation, vol. 1, no. 3, pp. 121-142, 2021.

[5]          National Intelligence Council, "Southeast Asia and pacific Islands: The impact of climate change to 2030: A commissioned research report," presented at the Joint Global Change Research Institute Battelle Memorial Institute, Pacific Northwest Division Scitor Corporation, 2009.

[6]          Y. Dumrul and Z. Kilicaslan, "Economic impacts of climate change on agriculture: Empirical evidence from ARDL approach for Turkey," Journal of Business Economics and Finance, vol. 6, no. 4, pp. 336-347, 2017.  https://doi.org/10.17261/pressacademia.2017.766

[7]          I. S. Samura, N. Nuryanti, and R. Rama, "Effect of working and work environment on the work discipline of employees of the Rokan Hulu Regency environmental agency," Doctoral Dissertation, Riau University, 2017.

[8]          M. V. Sharma and H. Chander, "Severity and intensity of fungal diseases of cucurbit crops of Hamirpur region, HP, India," Plant Archives, vol. 21, no. 2, pp. 148-153, 2021.  https://doi.org/10.51470/plantarchives.2021.v21.no2.025

[9]          S. Widono, S. Poromarto, and W. Noviantoro, "Relationship of weather factors on the progress of shallot moler disease in Brebes, Central Java in the rainy and dry seasons: Intensity increases in humid and warm air," presented at the IOP Conference Series: Earth and Environmental Science, 2023.

[10]        A. G. Kartasapoetra, Climatology: Climate effects on soil and plants, Revised ed. Jakarta: Bumiaksara, 2008.

[11]        J. Butterworth and H. McCartney, "The dispersal of bacteria from leaf surfaces by water splash," Journal of Applied Bacteriology, vol. 71, no. 6, pp. 484-496, 1991.  https://doi.org/10.1111/j.1365-2672.1991.tb03822.x

[12]        M. Delgado-Baquerizo et al., "The proportion of soil-borne pathogens increases with warming at the global scale," Nature Climate Change, vol. 10, no. 6, pp. 550-554, 2020.  https://doi.org/10.1038/s41558-020-0759-3

[13]        I. M. Sharif, C. Mohammud, and M. Illias, "Environmental patterns under rain shelter for strategic environmental control in a tropical greenhouse," Journal of Tropical Agriculture and Food Science, vol. 36, no. 1, pp. 127-134, 2008.

[14]        T. Nguyen, T. Tran, and Q. Nguyen, "Effects of light intensity on the growth, photosynthesis and leaf microstructure of hydroponic cultivated spinach (Spinacia oleracea L.) under a combination of red and blue LEDs in house," International Journal of Agricultural Technology, vol. 15, no. 1, pp. 75-90, 2019.

[15]        T. Tian, G. Qiao, B. Deng, Z. Wen, Y. Hong, and X. Wen, "The effects of rain shelter coverings on the vegetative growth and fruit characteristics of Chinese cherry (Prunus pseudocerasus Lindl.)," Scientia Horticulturae, vol. 254, pp. 228-235, 2019.  https://doi.org/10.1016/j.scienta.2019.04.030

[16]        T. Li, G. T. Lalk, Q. Zhang, Z. Xing, and G. Bi, "Winter production of Asian leafy greens in high tunnels using biodegradable mulches," Horticulturae, vol. 7, no. 11, p. 454, 2021.  https://doi.org/10.3390/horticulturae7110454

[17]        W. Setiawati, A. Hasyim, and A. Hudayya, "The use of Rain Shelter and Atecu Biopesticide in chili cultivation outside the season to reduce the loss of yield and opt attacks," Jurnal Hortikultura, vol. 28, no. 2, pp. 1-12, 2018.  https://doi.org/10.21082/jhort.v28n2.2018.p%p

[18]        A. C. Velásquez, C. D. M. Castroverde, and S. Y. He, "Plant–pathogen warfare under changing climate conditions," Current Biology, vol. 28, no. 10, pp. R619-R634, 2018.  https://doi.org/10.1016/j.cub.2018.03.054

[19]        R. Grosch and A. Kofoet, "Influence of temperature, pH and inoculum density on bottom rot on lettuce caused by Rhizoctonia solani," Journal of Plant Diseases and Protection, vol. 110, no. 4, pp. 366-378, 2003.

[20]        T. Paula Jr and B. Hau, "Effect of soil moisture on activity and dynamics of Rhizoctonia solani and Trichoderma harzianum," Journal of Plant Diseases and Protection -New Series, vol. 114, no. 3, pp. 126-132, 2007.  https://doi.org/10.1007/BF03356720

[21]        J. P. Clarkson, L. Fawcett, S. G. Anthony, and C. Young, "A model for Sclerotinia sclerotiorum infection and disease development in lettuce, based on the effects of temperature, relative humidity and ascospore density," PLoS One, vol. 9, no. 4, p. e94049, 2014.  https://doi.org/10.1371/journal.pone.0094049

[22]        R. Magarey, T. Sutton, and C. Thayer, "A simple generic infection model for foliar fungal plant pathogens," Phytopathology, vol. 95, no. 1, pp. 92-100, 2005.  https://doi.org/10.1094/phyto-95-0092

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