Crops ›› 2022, Vol. 38 ›› Issue (5): 241-248.doi: 10.16035/j.issn.1001-7283.2022.05.035

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Effects of Long- and Short-Term Reduction of Phosphorus Input on Yield and Phosphorus Utilization of Double Cropping Rice in South China

Pan Junfeng(), Liu Yanzhuo(), Liang Kaiming, Huang Nongrong, Peng Bilin, Fu Youqiang, Hu Xiangyu, Zhong Xuhua(), Li Meijuan, Hu Rui   

  1. Rice Research Institute, Guangdong Academy of Agricultural Sciences/Guangdong Provincial Key Laboratory of New Technology in Rice Breeding, Guangzhou 510640, Guangdong, China
  • Received:2021-07-19 Revised:2021-08-13 Online:2022-10-15 Published:2022-10-19

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Abstract:

Short-term and long-term experiments were conducted to determine the effects of phosphorus (P) fertilizer reduction on rice yield and phosphorus utilization. In the short-term experiment, three treatments, including normal P application (P1), half-dosage P application as basal dressing (P2), half-dosage P application with 50% as basal dressing and 50% as panicle fertilizer (P3), were established in an early and a late cropping season, conventional rice Yuejingsimiao 2 and hybrid rice Jingliangyouhuazhan were used as materials. In the long-term experiment, two treatments of no P application (M0) and normal P application (M1) were set up for nine consecutive years (comprising 18 seasons). Results from the short-term experiment indicated that two P reduction had no significant effect on grain yield, accumulation and translocation of dry matter, P accumulation and utilization. Among three treatments, no significant difference existed in the total and soluble P contents in the soil or in surface water. The P surplus and deficit rate were 8.7%, -35.3% and -31.8% for P1, P2 and P3 treatments, with P1 treatment achieving P apparent balance in the soil. In the long-term experiment, the relative yield under M0 treatment displayed a gradual declining trend across cropping seasons. However, the yields were comparable between two treatments in the six first seasons of three years. It could be concluded that short-term P reduction for three years would do no harm to grain yield and could reduce P loss from paddy soil in these fields with low to medium level of P content. Basal dressing of P fertilizer with half dosage would be better for achieving benefits in both grain yield and environmental protection.

Key words: Double cropping rice, Yield, Phosphorus utilization efficiency, Phosphorus balance

Table 1

Meteorological conditions from transplanting to maturity for short-term experiments"

生长阶段
Growth period		 2016年晚季Late season in 2016 2017年早季Early season in 2017
日均气温
Average daily
temperature
(℃)		 日均最高温
The highest
average daily
temperature
(℃)		 降水量
Rainfall
(mm)		 相对湿度
Relative
humidity
(%)		 总辐射
平均值
Total
radiation mean
[MJ/(m2∙d)]		 日均气温
Average daily
temperature
(℃)		 日均最高温
The highest
average daily
temperature
(℃)		 降水量
Rainfall
(mm)		 相对湿度
Relative
humidity
(%)		 总辐射
平均值
Total
radiation mean
[MJ/(m2∙d)]
移栽-穗分化始期
TR-PI		 28.7 32.8 136.4 83.6 15.2 23.9 27.9 517.4 89.7 9.9
穗分化始期-抽穗期
PI-HD		 27.0 31.5 132.8 81.9 15.5 26.8 31.1 566.6 89.2 13.4
抽穗期-成熟期
HD-MA		 23.6 27.9 134.4 81.1 13.0 27.8 32.3 301.0 89.1 16.0

Table 2

Time and amount of P fertilizer application under different treatments"

生长阶段
Growth stage		 移栽后天数Days after transplanting (d) 施磷量Amount of P application (kg P2O5/hm2)
早稻Early season 晚稻Late season P1 P2 P3 M1a
基肥Basal dressing -1 -1 45 22.5 11.25 45/27
穗分化始期PI 40 35 11.25
合计Total 45 22.5 22.50 45/27

Table 3

Effects of short-term P fertilizer treatments on grain yield and its components"

处理
Treatment		 产量
Yield (t/hm2)		 有效穗数
Effective
panicles (m2)		 每穗颖花数
Spikelets per
panicle		 单位面积颖花数
Spikelets per unit
area (×103/m2)		 结实率
Seed-setting
rate (%)		 千粒重
1000-grain
weight (g)		 收获
指数
HI
年份Year (Y)
2016 6.83a 266.9a 177.5a 47.27a 72.33a 22.46a 0.53a
2017 5.84b 263.5a 166.9b 43.82b 64.06b 21.13b 0.41b
磷肥处理Phosphorus (P)
P1 6.32a 259.6b 173.9a 45.02a 67.98a 21.69a 0.47a
P2 6.33a 265.6ab 171.5a 45.49a 69.43a 21.76a 0.48a
P3 6.35a 270.5a 171.2a 46.12a 67.18a 21.94a 0.47a
品种Variety (V)
YJSM2 5.88b 272.5a 160.42b 43.67b 69.29a 21.87a 0.47a
JLYHZ 6.78a 257.9b 184.03a 47.42a 67.10a 21.72a 0.47a
Y×V ns ns ** ** ** ** **
Y×P ns ns ns ns ns ns ns
V×P * ns ns ns ns ns ns
Y×P×V ns ns ns ns ns ns ns

Table 4

Effects of P fertilizer management on uptake, use efficiency and harvest index of phosphorus in 2016"

处理
Treatment		 磷积累量P accumulation (kg/hm2) 磷籽粒生产效率
PUEg (kg/kg)		 磷干物质生产效率
PUEb (kg/kg)		 磷收获指数
PHI
PI HD MA PI-HD HD-MA
磷肥处理Phosphorus (P)
P1 7.6a 22.0a 31.8a 14.3a 9.8a 216.9a 387.5a 0.791a
P2 6.4a 21.8a 31.0a 15.4a 9.2a 222.6a 404.6a 0.817a
P3 6.4a 21.9a 29.7a 15.5a 7.9a 230.1a 426.4a 0.808a
品种Variety (V)
YJSM2 7.3a 21.1a 31.4a 13.8b 10.3a 204.7b 380.9b 0.817a
JLYHZ 6.3b 22.7a 30.3a 16.4a 7.6a 241.7a 431.5a 0.794a
P ns ns ns ns ns ns ns ns
V * ns ns * ns ** ** ns
P×V ns * ns ns ns ns ns ns

Table 5

Effects of different P fertilizer management on dry matter accumulation and transportation"

处理
Treatment		 生物量Biomass (t/hm2)
穗分化―抽穗期
PI-HD		 抽穗―成熟期
HD-MA		 物质转运量
DMT		 总干物质量
TDW
年份Year (Y)
2016 6.68a 3.53a 1.58b 12.41a
2017 6.99a 1.63b 4.16a 12.08a
磷肥处理Phosphorus (P)
P1 6.76a 2.46a 2.94a 12.15a
P2 6.79a 2.64a 2.84a 12.26a
P3 6.95a 2.64a 2.85a 12.35a
品种Variety (V)
YJSM2 6.12b 2.62a 2.43b 11.65b
JLYHZ 7.54a 2.53b 3.31a 12.85a
Y×V ns ns ns ns
Y×P ns ns ns ns
V×P ns ns ns ns
Y×P×V ** * * ns

Fig.1

Effects of various P fertilizer managements on total phosphorus and available phosphorus content in upper-level soil For a given year, different letters indicate significant differences among different treatments by LSD test (P < 0.05), the same below"

Fig.2

Variation of total P and available P content in the surface water under various P fertilizer managements"

Table 6

Input, output and balance of phosphorous under different treatments in 2016"

处理
Treatment		 投入量
Input (kg/hm2)		 输出量
Output (kg/hm2)		 盈亏量
Amount of surplus and deficit (kg/hm2)		 盈亏率
Rate of surplus and deficit (%)		 输入/输出
Input/output
磷肥Phosphorus (P)
P1 27.1a 25.2a 1.9a 8.7a 1.1a
P2 16.2b 25.4a -9.2b -35.3b 0.6b
P3 16.3b 24.0a -7.6b -31.8b 0.7b
品种Variety (V)
YJSM2 19.6a 25.6a -6.0a -22.6a 0.8a
JLYHZ 20.1a 24.0a -3.9a -16.3a 0.8a
P ** ns ** ** **
V ns ns ns ns ns
P×V ns ns ns ns ns

Fig.3

Changes of relative yield under long-term experiment"

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