Scientia Agricultura Sinica ›› 2023, Vol. 56 ›› Issue (23): 4717-4728.doi: 10.3864/j.issn.0578-1752.2023.23.013

• SOIL & FERTILIZER·WATER-SAVING IRRIGATION·AGROECOLOGY & ENVIRONMENT • Previous Articles     Next Articles

Research Progress on the Carbon and Nitrogen Sink of Duckweed Growing in Paddy and Its Effects on Rice Yield

JING LiQuan1(), LI Fan1, ZHAO YiHan1, WANG XunKang1, ZHAO FuCheng2, LAI ShangKun3, SUN XiaoLin4, WANG YunXia5, YANG LianXin1()   

  1. 1 Agricultural College of Yangzhou University/Jiangsu Key Laboratory of Crop Genetics and Physiology/Jiangsu Key Laboratory of Crop Cultivation and Physiology/Jiangsu Co-Innovation Center for Modern Production Technology of Grain Crops, Yangzhou 225009, Jiangsu
    2 Institute of Maize and Featured Upland Crops, Zhejiang Academy of Agricultural Sciences, Dongyang 322100, Zhejiang
    3 Suqian Institute, Jiangsu Academy of Agricultural Sciences, Suqian 223800, Jiangsu
    4 Eco-Environmental Protection Research Institute, Shanghai Academy of Agricultural Sciences, Shanghai 201403
    5 College of Environmental Science and Engineering, Yangzhou University, Yangzhou 225009, Jiangsu
  • Received:2023-03-29 Accepted:2023-06-21 Online:2023-12-04 Published:2023-12-04
  • Contact: YANG LianXin

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Abstract:

Duckweed (Lemna minor L.) is a floating microscopic plant that is usually found in standing water. Climate change is characterized by rising temperature, which is mainly due to increasing atmospheric CO2 concentration, and it poses potential risks to food production. Owing to factors such as climate warming and/or the eutrophication of water, duckweed growth in paddy fields has shown an increasing trend year by year in China. This paper focused on the impacts of duckweed on paddy fields and highlighted some vital trends. Duckweed reduced the water temperature of paddy by 0.86-2.76 ℃ and the pH value by 0.10-0.45, changed the structure of microbial community, reduced the NH3 volatilization by 18.2%-59.0%, and increased the nitrogen utilization rate by 17.2%-78.0%. As a result, the nitrogen sink of paddy increased and the rice yield rose by 9.0%-34.6% upon duckweed growing in paddy. Duckweed grew and reproduced rapidly, and its annual biomass could reach 8×103-13×103 kg·hm-2, making its carbon sink almost equal to that of rice in the same season. The mutualism between duckweed and rice was greater than its competition, and the coexistence of duckweed and rice in paddy showed an adaptation of the rice field ecosystem to environmental changes. Future research in this field should focus on the effect and its mechanism of duckweed on the paddy environment changes, rice growth, yield, and quality, and the risks which might bring to the paddy fields, especially the interaction with environmental factors (elevated temperature and CO2 concentration, etc.). Such research would provide theoretical support for the sustainable agricultural development of rice farming technology based on biological collaboration, such as rice-duckweed, which can adapt to future changes in climate and environment.

Key words: duckweed (Lemna minor L.), rice, carbon sink, nitrogen sink, yield

Fig. 1

Growth and reproduction of duckweed growing in paddy in the fields of production (a-c) and simulation of future climate condition (d-f) Fig. a and Fig. b are the production fields of rice in Sanya, Hainan province, and Zhenjiang, Jiangsu province, respectively—duckweed grew quickly; Fig. c shows a rice production field in Qian’an, Jilin province—duckweed grew relatively slowly; Fig. d, the growth and reproduction of duckweed growing in the control area of rice field experiment (conventional treatment, Yangzhou, Jiangsu province) was relatively slow; Fig. e, the growth and reproduction of duckweed growing under the treatment of elevated temperature (+1℃) were accelerated; Fig. f, the growth and reproduction of duckweed growing in paddy under the treatment of elevated CO2 concentration (+200 μmol·mol-1) and temperature (+1℃) were fast"

Fig. 2

Botanical characteristics of duckweed and its morphology in paddy Fig. a and Fig. b as quoted from AN et al. [1], represent the morphological characteristics of duckweed during different periods; Fig. c and Fig. d come from the Jiangsu Key Laboratory and Field of Crop Genetics and Physiology"

Table 1

Effects of duckweed growing in field on the ecological environment factors of paddy and rice yield"

报道年份
Report year		 组织
Organization		 试验地点
Experiment location		 施氮水平
N level (kg·hm-2)		 产量
Yield
(%)		 氨挥发
NH3 volatilization (%)		 氮利用率
Nitrogen utilization rate (%)		 pH 参考文献Reference
2003 中国水稻研究所
China National Rice Research Institute		 温室试验
Greenhouse experiment		 0 无效应
No effect		 —— —— —— [36]
2008 广西大学
Guangxi University		 广西大学科研基地
(108°17′E, 22°50′N) Research base of Guangxi University		 275 11.1↑ 18.2↓ —— —— [39]
2009 浙江大学
Zhejiang University		 浙江嘉兴
(120°40′E, 30°50′N)
Jiaxing, Zhejiang Province		 90/180 9.4-9.8↑ 33.2-53.7↓ —— 0.45↓ [17]
2017 中国科学院
南京土壤研究所
Institute of Soil Science of Chinese Academy of Sciences		 中国科学院常熟实验站
(120°57′E, 31°15′N) Changshu Experimental Station, Chinese Academy of Sciences		 225/300 9.0-10.0↑ 36.0-59.0↓ 35.0-78.0↑ 0.10-0.30↓ [72]
2017 贵州民族大学
Guizhou Minzu University		 贵州省岑巩县水稻基地
(108°46E, 27°12′N)
Rice base in Cengong County, Guizhou Province		 —— 11.7-34.6↓ —— —— —— [44]
2019 南京林业大学
Nanjing Forestry University
中山大学
Sun Yat-Sen University		 江苏省宜兴
(119°59′E,31°28′N)
Yixing, Jiangsu Province		 240 10.9↑ 50.6-54.2↓ 17.2↑ 0.27-0.33↓ [12]
江西省鹰潭
117°10′N)
Yingtan, Jiangxi Province
2021 上海交通大学
Shanghai Jiaotong University		 上海市青浦现代农业园
(30°58'9"E, 121°0'34"N)
Shanghai Qingpu Modern Agricultural Park		 189.2 28.0↑ —— —— —— [73]
2022 上海交通大学
Shanghai Jiaotong University		 上海市青浦现代农业园
(30°58'9"E, 121°0'34"N)
Shanghai Qingpu Modern Agricultural Park		 —— 23.0↑ —— —— 0.32-0.39↓ [19]
2023 浙江省农业科学院
Zhejiang Academy of Agricultural Sciences		 太湖地区
(120°40' E, 30°50'N)
Taihu region		 170/225 —— —— —— —— [20]
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