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Acta Agronomica Sinica ›› 2018, Vol. 44 ›› Issue (11): 1704-1712.doi: 10.3724/SP.J.1006.2018.01704

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Spatio-temporal Changes of Rice Production in China Based on County Unit

Xiao-Hui WANG1,Yu-Lin JIANG1,Yang LIU1,Jie LU1,Xiao-Gang YIN1,Lei-Gang SHI2,Jing HUANG3,Qing-Quan CHU1,Fu CHEN1,*()   

  1. 1 College of Agronomy and Biotechnology, China Agricultural University / Key Laboratory of Farming System, Ministry of Agriculture and Rural Affairs, Beijing 100193, China
    2 Beijing Research Center of Information Technology in Agriculture, Beijing 100097, China
    3 School of Life and Engineering, Southwest University of Science and Technology, Mianyang 621010, Sichuan, China
  • Received:2018-03-28 Accepted:2018-07-20 Online:2018-11-12 Published:2018-07-26
  • Contact: Fu CHEN E-mail:chenfu@cau.edu.cn
  • Supported by:
    This study was supported by the National Key Research and Development Program of China(2016YFD0300200)

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Abstract:

Rice is one of the most important grain crops in China. To clear spatio-temporal change characteristics of rice in recent decades is of great significance in optimizing the layout of rice and promoting the sustainable development of rice production. This study was conducted to figure out spatio-temporal dynamic changes of national rice production, planting area and yield; to map gravity center migration path of rice production and area based on county data particularly since 1985; and to quantitatively analyze rice production contribution merely caused by area and yield. Variation period was calculated by wavelet analysis using deviations from average of national rice-producing data from 1949 to 2017. Rice-producing gravity centers were computed by ArcGIS using county-level data of rice production and planting area, and then connected them in order of year. Production contribution was firstly divided into three components separately resulted from area, yield and mutual interaction, in that case production changes caused by them could be reckoned to get production contribution rate. ArcGIS was applied to display spatial distribution on the background of two maps including Chinese rice cropping regionalization and provincial administrative division. To come out, the variation periods were respectively 49 years and 21 years, 26 and 60 years of production, area and yield. From 1985 to 2015, nearly 50% of planting region increased in rice production, about 70% decreased in rice planting area, and more than 80% increased their yields. The gravity center of national rice production and planting area migrated northeastwards about 229 km and 225 km. What’s more, the gravity center of the northeast migrated more northeastwards at about 238 km and 242 km. In China, the proportion of yield, as a dominant factor of rice production contribution, fell from 56.3% to 28.3%, and area increased from 34.7% to 63.1%. In conclusion, increasing yield in every rice cropping region, increasing planting area in single cropping region of northeastern and decreasing planting area in double cropping region of South China and single and double cropping region of Central China are main rice distribution characteristics in China. Rational layout of rice planting area and increasing yield are more and more important in stabilizing and enhancing rice production. Rationally using resources, increasing the degree of mechanization and comparative effectiveness are critical pathways to promote Chinese rice production.

Key words: rice, county unit, spatio-temporal changes, contribution, gravity center

Fig. 1

National regionalization of rice cropping I, II, III, IV, V, and VI mean regionalization of rice cropping in South China, Central China, Southwest, North China, Northeast and Northwest."

Fig. 2

Relative value of change and variation period of national rice production, area, and yield"

Fig. 3

Distribution change of national rice-producing in 1985-2000 (a), 2000-2015 (b), and 1985-2015 (c) for planting area HR: highly reduction; LR: low reduction; NC: no change; LI: low increase; HI: highly increased."

Table 1

Changes of yield and proportion of production and planting area of every regionalization of rice cropping"

稻作
Regionalization		 年份Year
1985 1990 1995 2000 2005 2010 2015
产量比例Proportion of production (%)
华南 South China 12.77 13.41 13.45 13.15 11.08 9.63 9.57
华中Central China 71.44* 69.07* 68.11* 64.83* 65.50* 63.70* 62.91*
西南 Southwest 7.51 7.26 7.70 8.54 8.72 7.98 7.59
华北 North China 3.86 4.41 4.72 5.08 5.00 5.69 5.50
东北 Northeast 3.95 5.22 5.36 7.48 8.85 11.84 13.39
西北 Northwest 0.46 0.63 0.66 0.92 0.84 1.15 1.04
面积比例 Proportion of rice-planting area (%)
华南 South China 16.27 15.89 15.53 14.87 12.96 12.39 11.71
华中Central China 67.66* 66.61* 66.43* 64.08* 64.95* 63.26* 61.99*
西南 Southwest 8.48 8.10 8.14 8.65 8.80 8.17 8.30
华北 North China 3.35 3.80 3.97 4.62 4.59 4.84 4.69
东北 Northeast 3.83 4.96 5.26 6.84 8.01 10.37 12.41
西北 Northwest 0.42 0.64 0.68 0.93 0.71 0.98 0.89
单产水平Yield (kg hm-2)
华南 South China 4040 4767 5372 5799 5597 5405 5854
华中Central China 5429* 5934* 6364* 6788* 6623 6893 7073
西南 Southwest 4684 5295 5952 6659 6564 6847 6572
华北 North China 3806 5428 6167 6338 6594 7180* 7044
东北 Northeast 4746 5502 5870 6526 6766 7103 7209
西北 Northwest 4401 4898 5551 5889 7327* 7040 7507*

Fig. 4

Range of variation of national rice production and yield1 and 2 mean production and yield; a, b, and c mean years, corresponding with those given in Figure 3. Abbreviations are the same as thosegiven in Figure 3."

Fig. 5

Gravity migration of rice area and production in nation (a), IV (b), II (c), III (d), and I (e)"

Fig. 6

Proportion of counties of different production dominantAD: area-dominant; AAD: absolute area-dominant; YD: yield-dominant; AYD: absolute yield-dominant; MD: mutual-dominant; AMD: absolute mutual-dominant."

Fig. 7

Distribution of different production dominant during 1985-2000 (a), 2000-2015 (b), and 1985-2015 (c)Abbreviations are the same as those given in Figure 6."

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