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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 46, 2015 

A publication of 

 

The Italian Association 
of Chemical Engineering  
Online at www.aidic.it/cet 

Guest Editors: Peiyu Ren, Yancang Li, Huiping Song  
Copyright © 2015, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-37-2; ISSN 2283-9216                                                                                

 

Water Consumption Characteristics of Sugarcane in Dry-Hot 
Region under Climate Change 

Xiaogang Liu*a, Zhihui Hana, Kun Haoa, Xinle W angb, Qiliang Yanga 

 a Faculty of Modern Agricultural Engineering, Kunming University of Science and Technology, Kunming, China, 
 b Faculty of Foreign Language and Culture, Kunming University of Science and Technology, Kunming, China. 
liuxiaogangjy@126.com 

The analysis of the sugarcane water requirement regulation at different temporal scale can provide a basis for 
optimal water management. Based on the daily meteorological observation data in Yuanmou dry-hot region 
during 1956-2010, sugarcane water requirement and crop water surplus deficit index were estimated, and the 
variation characteristics were analyzed at different temporal scale. The impact of several meteorological 
factors on water requirement was studied by the partial correlation analysis method. The variation pattern was 
conducted on the data of the annual water requirement and crop water surplus deficit index by using the 
Mann-Kendall test. The result showed that sugarcane water requirement in dry-hot region was significantly 
higher than other months from June to October and less in April, May, November and December. The 
moisture profit and loss was comparatively large from June to December and sugarcane depended much on 
irrigation, but it was less in April and May and sugarcane depended less on irrigation. Sugarcane water 
requirement fluctuated decreasing trend in recent 55 years. Since the 1980s, water requirement and water 
deficit began to decrease significantly. The changes of sugarcane water requirement were primarily attributed 
to wind speed and sunshine hours in dry-hot region. 

1. Introduction 

The annual average surface temperature was significantly increased in recent 100 years, and increasing 
extent of temperature was slightly higher than the global average of the same period with global warming (Qin, 
2007). The change trend of precipitation was not obvious, but since 1956 there had been a slight increase in 
the trend (Ding, 2006). Dry-hot region has characteristics of dry and hot climate, rich resources of light and 
heat, less rainfall and maldistribution in space and time, and outstanding seasonal drought , which all limited 
the high quality of sugarcane production. Determining the variation characteristics of sugarcane water 
requirement at different stages of growth under climate change can provide scientific reference basis for 
irrigation schemes. 
The change of meteorological factors can significantly change the crop water consumption and water 
requirement. Many scholars have carried out a series of exploration on crop water requirement under the 
climate change. Nkomozepi and Chung (2012) reported water requirement and net irrigation water 
requirement of spring maize in natural agricultural ecological region with GCM and CROPWAT model. 
Reference crop evapotranspiration in Iran semi-arid plateau environment was analyzed based on limited 
weather data by using support vector machine, neural network and regression analysis (Tabari, 2012). Wang 
(2013) simulated the response of rice water requirement to climate change by rice model ORYZA2000 
according to meteorological data and the statistical simulation results of HadCM3 atmospheric general 
circulation model A2 and B2. Yin (2010) studied the cause the variation trend of reference crop 
evapotranspiration and obtained the contribution rate of meteorological factors to the variation trend. 
Sugarcane is the main economic crop in China, but there has less study on water consumption under climate 
changes. 
This paper analyzed the variation pattern about the sugarcane water requirement and crop water surplus 
deficit index at different temporal scale and discussed the influence of the meteorological factors on the water 
requirement of sugarcane in dry-hot region based on the daily meteorological data from 1956 to 2010. 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1546236

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Liu X.G., Han Z.H., Hao K., Wang X.L., Yang Q.L., 2015, Water consumption characteristics of sugarcane in dry-hot 
region under climate change, Chemical Engineering Transactions, 46, 1411-1416  DOI:10.3303/CET1546236  

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2. Data source and research method 

Dry-hot region had annual rainfall of 600-800 mm and 90% rainfall was concentrated from June to October. 
The annual average temperature of dry-hot region was above 20℃ and effective accumulated temperature 
was above 7000-8000℃ which caused the annual evaporation was 6 times of annual precipitation. As a 
typical representative of the dry hot region, Yuanmou is located in Longchuan River downstream valley basin 
area, the northern plateau of the central Yunnan Province, China, there serious contradictory of water and 
heat. 
Daily meteorological observation data of Yuanmou (101°52′E, 25°44′N) in dry-hot region during 1956-2010 
provided by China Meteorological Science Data Sharing Service Network. Reference crop evapotranspiration 
is calculated by the latest revision Penman-Monteith formula that recommended by the FAO-56. Sugarcane 
growth period is divided into four stages according to growth characteristics, e.g. seedling stage (from April 
10th to May 23rd), tillering stage (from May 24th to June 25th), elongating stage (from June 26th to October 
8th) and maturity (from October 9th to December 30th). Crop coefficients are Kc ini=0.40, Kcmid=1.25 and 
Kcend=0.75 (Allen, 1998). 
CWSDI (W ater Surplus Deficit Index Crop) is composed of crop water requirement and available water supply, 
which indicates the degree of crop water budget (Wang, 2013). Reference crop daily evaporation and 
sugarcane water requirement were calculated and water surplus deficit index were obtained based on the 
daily meteorological data of Yuanmou dry-hot region according to Penman-Monteith formula and crop 
coefficient of FAO-56. SPSS software was used to analyze the partial correlation coefficient between the 
water sugarcane requirement and the meteorological factors, and the most significant meteorological factors 
were obtained. The Mann-Kendall trend test was carried out on the annual variation of sugarcane water 
requirement and some meteorological factors with Matlab7.0 software, and the variation trend and mutation of 
the water requirement and meteorological factors were analyzed. 

3. Results and analysis 

3.1 Daily variation 
The change curves of sugarcane daily water requirement (ETc), the profit and loss of moisture and the crop 
water surplus deficit index (CW SDI) in dry-hot region were shown in figure 1. The average daily water 
requirement was 3.5 mm/d during one year. The water requirement was stable from 1st to 51st day and 
increased day by day from 52nd day. Water requirement was higher than average from 65th day and reached 
a peak of 5.3 mm/d until 82nd day, and then, water requirement was gradually reduced and trended to 
average. The water requirement started lower than the average from 214th days, so it was clear that from 
65th to 214th days was the peak of the water requirement of sugarcane. The daily profit loss of moisture of the 
sugarcane was negative and indicated that the annual water was deficient, and the average of was -2.5 mm/d. 
The daily profit loss of moisture was lower than the average from 66th to 104th days and from 169th to 266th 
days, and water deficit was obvious. The water deficit was smaller from 1st to 65th and 104th to 168th and the 
degree of dependence on irrigation of sugarcane in this stage was relatively low. The average of sugarcane 
crop water surplus deficit index (CW SDI) was -46.7%. CWSDI was significantly higher than the average from 
26th to 127th and water deficit was relatively small. 
The method of partial correlation coefficient can eliminate mutual influence between the elements according to 
the partial correlation coefficient between daily water requirement of sugarcane and meteorological factors in 
dry-hot region, the degree of correlation from high to low is: sunshine hours (0.473), wind speed (0.436), 
vapor pressure (0.398), pressure (0.208), relative humidity (-0.208), temperature (-0.115), precipitation (-
0.087), daily maximum temperature(-0.05), daily minimum temperature(0.03). The water requirement was 
positively correlated with sunshine hours, wind speed, vapor pressure, pressure and daily minimum 
temperature, but negatively correlated with relative humidity, temperature, precipitation and daily maximum 
temperature. 
 

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 (a)                                                                      (b) 

Figure 1: Change curves of daily average water requirement, moisture profit and loss (K) and CWSDI 

3.2 Monthly variation 
Sugarcane monthly water requirement, moisture profit and loss (K) and the change of crop water surplus 
deficit index CWSDI curve were shown in figure 2. Monthly water requirement was increasing from April, 
reached the maximum of 134.7 mm in July, then decreased progressively, and it fell to the minimum of 86.5 
mm in December. The average of sugarcane water requirement from June to October was significantly higher 
than 102.5 mm, and it was the peak of sugarcane water requirement. Sugarcane monthly moisture profit and 
loss were negative and monthly average deficit was 74.1 mm. The moisture profit and loss increased 
significantly since May and reached a maximum of 89.0 mm in October, and then decreased. Crop water 
surplus deficit index (CWSDI) reached to a peak of -2.3% in May, and from April to September CWSDI was 
significantly higher than the monthly CWSDI average of -13.8%. Thus, sugarcane water requirement in dry-hot 
region was significantly higher than other months from June to October and less in April, May, November and 
December. The moisture profit and loss was comparatively large from June to December and sugarcane 
depended much on irrigation, but it was less in April and May and sugarcane depended less on irrigation. 

 
 (a)                                                                  (b) 

Figure 2: Change curves of monthly average water requirement, moisture profit and loss (K) and CWSDI 

Making partial correlation analysis of monthly water requirement and meteorological factors to further explore 
the influence of meteorological factors on sugarcane water requirement, and the results were shown in Table 
1. Wind speed and sunshine hours were the important factors that affected sugarcane water requirement. The 
partial correlation coefficient of wind speed and sunshine hours passed the test of the reliability of α=0.001, 
and two factors was significantly positive correlation with monthly water requirement. Sunshine hours was the 
most significant meteorological factors affecting the water requirement of sugarcane in May, June, July, 
August and September, and wind speed was the most significant meteorological factors in April, October, 
November and December. Therefore, wind speed and sunshine hours were the most significant impact on 
dry-hot sugarcane water requirement, which was consistent with the results of the daily water requirement and 
the partial correlation coefficient of the meteorological factors. 
 
 

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Table 1: Monthly water requirement and the partial correlation coefficient of the meteorological factors 

Month Precipitati
on 

Pressure Wind 
speed 

Temperat
ure 

Vapor 
pressure 

Relative 
humidity 

Sunshine  
hour 

Daily minimum 
temperature 

Daily 
maximum 
temperatu

re 

4 -0.187 0.070 0.726*** 0.083 -0.195 0.084 0.487*** 0.039 0.157 

5 -0.252 0.055 0.616*** 0.238 -0.567*** 0.416** 0.750*** 0.301* 0.023 

6 -0.141 -0.029 0.326* 0.182 -0.238 0.050 0.771*** 0.086 -0.058 

7 -0.151 0.071 0.613*** 0.640*** -0.613*** 0.482*** 0.959*** 0.163 -0.324 

8 0.482*** 0.072 0.901*** 0.474*** -0.465*** 0.246 0.985*** 0.114 0.090 

9 0.065 -0.009 0.707*** 0.128 -0.076 -0.062 0.887*** -0.031 -0.080 

10 0.069 0.083 0.664*** 0.331* -0.267 0.178 0.618*** -0.097 -0.204 

11 -0.193 0.093 0.540*** 0.171 -0.101 0.026 0.324* 0.003 -0.107 
12 0.001 0.068 0.656*** 0.001 -0.381** -0.007 0.531*** 0.258 0.022 

3.3 Annual variation 
Trend analysis on sugarcane water requirement, moisture profit and loss (K) and CWSDI in dry-hot region and 
the change curve were showed in figure 3. Since 1960, sugarcane water requirement began a downward 
trend in dry-hot region and felled below the threshold until 1980 (Fig 3a). Then this decline was more than 
significant level of 0.05 critical line, and even over 0.001 significance level (u 0.001=2.56). Therefore, the 
downward trend of the sugarcane water requirement in nearly 20 years was extremely significant. Annual 
average of moisture profit and loss was negative (Fig 3b). Sugarcane profit and loss of moisture was large 
than 0 since 1956 and water deficit decreased gradually. The water profit and loss of moisture exceeded the 
critical line in 1984 and the water deficit reduced significantly after 1980s. The curves of UF and UB appeared 
intersection in1978 and the intersection was in the critical line. Thus water deficit was less after 1980s and it 
appeared mutation phenomenon in 1978. The crop water surplus deficit index (CWSDI) was all negative 
nearly 55 years. The UF statistic was larger than 0 since 1961 and CWSDI showed a trend of increase. The 
water surplus deficit index surpassed critical value until 1997 and presented a significant decrease trend (Fig 
3c). 

    
 (a) Water requirement                                         (b) Profit loss of moisture    

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(c) CWSDI 

Figure 3: Mann-Kendall test curves of water requirement, moisture profit and loss and CWSDI 

Wind speed and sunshine hours were the most significant meteorological factors affecting water requirement 
according to the correlation between the meteorological factors and the water requirement of sugarcane. The 
average trend of wind speed and sunshine hours in dry-hot region was analyzed by Mann-Kendall test (Fig. 
4). The wind speed appeared a growth trend in dry-hot region (Fig. 4a). The curves UF and UB appeared 
intersection between critical lines and mutation phenomenon. Then wind speed began to show a decreasing 
trend and fell below the critical value until 1984. UF statistics were beyond the 0.001 significant level 
(U0.001=2.56) and wind speed decreased significantly since 1980s. The results of Mann -Kendall test of 
sunshine hour showed in Fig. 4b, and UF statistics was less than 0 since 1956. Thus, sunshine hours showed 
a downward trend and it was beyond the level of significant levels of 0.05 until 1982, which indicated that 
sunshine hours showed a significant downward trend in dry-hot region from late of 1980s. 

 
  (a) Wind speed                                             (b) Sunshine hours 

Figure 4: Mann-Kendall test curves of wind speed and sunshine hours 

4. Discussion 

In recent years, the temperature in southwest China was a significant upward trend, but sugarcane water 
requirement was a significant downward trend in dry-hot region for the last 55 years, which indicated that the 
temperature change was not effect of changes in crop water requirement dominant factor and agreed with 
previous result which was confirmed (Gu, 2008). Crop water requirement is mainly affected by radiation 
variables and aerodynamic variables (McVicar, 2007). In this study the most significant meteorological factor 
affecting sugarcane water requirement were wind speed and sunshine hours, which was confirmed (Zhang, 
2010; Roderick, 2007 and Liang, 2010). 
There was a close relationship between sugarcane water requirement in dry-hot region and the local climate 
change. At the same time, the complex terrain of dry-hot region also affected sugarcane water requirement, 
but the paper only studied the change characteristic of sugarcane water requirement and water surplus deficit 
index from the perspective of climate change. The factors of topography, soil conditions and irrigation 
conditions and other factors that impact on crop water requirement should be considered in future. 

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5. Conclusions 

1) Sugarcane water requirement in dry-hot region was significantly higher than other months from June to 
October and less in April, May, November and December. The moisture profit and loss was comparatively 
large from June to December and sugarcane depended much on irrigation, but it was less in April and May 
and sugarcane depended less on irrigation. 
2) The correlation degree from high to low according to partial correlation coefficient of meteorological factors 
and sugarcane daily water requirement was wind speed, sunshine hours, vapor pressure, pressure, relative 
humidity, temperature, precipitation, daily maximum temperature and daily minimum temperature. Wind speed 
and sunshine hours were the most significant impact on the sugarcane water requirement. 
3) Sugarcane water requirement fluctuated decline trend in dry-hot region, and the gross water surplus deficit 
was negative in near 55 years. Sugarcane water requirement was significantly decreased trend since 1981 , 
which was consistent with the variability of wind speed and sunshine hours. 

Acknowledgements 

We are grateful to the research grants from the Chinese National Natural Science Fund (51109102, 51469010 
and 51379004), Yunnan Province Natural Science Fund (2014FB130) and Yunnan Province Key project of 
Education Department (2011Z035). 

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