Assessment and Distribution of Waterlogging Damage Risks for Melons and Vegetables in Hainan Province from October to November

Zhang Lei; Huo Zhiguo; Huang Dapeng; Wu Li

doi:10.11898/1001-7313.20150405

Vol.26, NO.4, 2015

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Article Navigation > Journal of Applied Meteorological Science > 2015 > 26(4): 432-441

Zhang Lei, Huo Zhiguo, Huang Dapeng, et al. Assessment and distribution of waterlogging damage risks for melons and vegetables in Hainan Province from October to November. J Appl Meteor Sci, 2015, 26(4): 432-441. DOI: 10.11898/1001-7313.20150405.

Citation:

Zhang Lei, Huo Zhiguo, Huang Dapeng, et al. Assessment and distribution of waterlogging damage risks for melons and vegetables in Hainan Province from October to November. J Appl Meteor Sci, 2015, 26(4): 432-441. DOI: 10.11898/1001-7313.20150405.

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Assessment and Distribution of Waterlogging Damage Risks for Melons and Vegetables in Hainan Province from October to November

DOI: 10.11898/1001-7313.20150405

Zhang Lei^1,2,
Huo Zhiguo^{1,3
,
,},
Huang Dapeng⁴,
Wu Li¹

1.
Chinese Academy of Meteorological Sciences, Beijing 100081
2.
National Meteorological Center, Beijing 100081
3.
Collaborative Innovation Center on Forecast and Evaluation of Meteorological Disasters, Nanjing University of Information Science & Technology, Nanjing 210044
4.
National Climate Center, Beijing 100081

Received Date: 2015-01-05
Rev Recd Date: 2015-05-07
Publish Date: 2015-07-31

Abstract

Abstract

Hainan, as an important agricultural zone for winter melons and vegetables in China, suffers from waterlogging, chilling and drought risks that threat production during its growth period. In order to offer guidance to reduce waterlogging damage and assure production, the theoretical framework of natural disaster risk system is implemented based on meteorological station observations from 1998 to 2011, the yield and planted area data, as well as waterlogging disaster data for melons and vegetables. A waterlogging level index system is constructed through comparing the hazard index with disaster based on the principal component analysis of four factors, i.e., precipitation, rain days, continuous rain days and maximum continuous rain days. A comprehensive waterlogging risk index model for melons and vegetables is built integrating with hazard index, damage sensitivity index, damage loss index and damage prevention capability index.Results show that the waterlogging hazard index increases from southwest to northeast, the risk probability of different level hazard index are different in regions, and the distribution of high and low risk probability are of the opposite. Due to results of disaster hazard spatial pattern, it implicates that more attention should be paid to those high hazard regions. Considering waterlogging sensitivity is partly influenced by slope gradient, the damage index increases from the central mountain to the periphery. Among three disasters, waterlogging causes most yield reduction for paprika, watermelon and cowpea which are in conformity with their biological characteristic. Taking yield loss and production status as factors to represent damage vulnerability and prevention capability, waterlogging damage loss index and prevention capability index differ in different regions. The distribution of comprehensive waterlogging risk index for melons and vegetables is similar for four kinds of melons and vegetables, which increases from southwest to northeast induced by factors such as precipitation, terrain and soil. The distribution characteristic is conformed to the real waterlogging situation in Hainan Province. Results can provide useful information which contribute to a better understanding of disaster damage risk for melons and vegetables and help for the policy formation of agro-meteorological disaster risk management.
- Hainan Province;
- melons and vegetables;
- waterlogging at seeding stage;
- damage risk assessment

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References(34)

Figures and Tables

图 1 瓜菜苗期湿涝危险性分布与等级湿涝风险概率分布

(a) 危险性分布，(b) 轻度湿涝风险概率，(c) 中度湿涝风险概率，(d) 重度湿涝风险概率

Fig. 1 Distribution of waterlogging damage risk and risk probability of different grade index

(a) distribution of damage risk, (b) risk probability of low waterlogging damage, (c) risk probability of medium waterlogging damage, (d) risk probability of high waterlogging damage

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Fig. 2 Distribution of waterlogging damage sensitivity

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图 3 瓜菜苗期湿涝灾损综合指数分布

(a) 西瓜，(b) 豇豆，(c) 辣椒，(d) 丝瓜

Fig. 3 Distribution of waterlogging damage loss

(a) watermelon, (b) cowpea, (c) paprika, (d) luffa

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图 4 瓜菜苗期湿涝防灾能力指数分布

(a) 西瓜，(b) 豇豆，(c) 辣椒，(d) 丝瓜

Fig. 4 Distribution of waterlogging prevention capability

(a) watermelon, (b) cowpea, (c) paprika, (d) luffa

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图 5 瓜菜苗期湿涝综合风险区划

(a) 西瓜，(b) 豇豆，(c) 辣椒，(d) 丝瓜

Fig. 5 Distribution of comprehensive waterlogging risk

(a) watermelon, (b) cowpea, (c) paprika, (d) luffa

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Table 1 Contribution rates of yield reduction rate induced by waterlogging, chilling and drought (unit：%)

品种	苗期湿涝	冬季寒害	春季干旱
西瓜	73.6	14.3	112.1
豇豆	42.8	26.4	30.8
辣椒	81.8	2.8	15.4
丝瓜	14.0	47.3	38.7

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