Effects of Successive Years of Rice-duck Co-cultivation on Soil Properties, Rice Yield and Quality in Paddy Field

doi:10.11924/j.issn.1000-6850.casb2020-0455

Abstract

Abstract:

To explore the influence of large-scale rice-duck co-cultivation for successive years on paddy soil properties, and rice yield and quality, two treatments were set up for 10 consecutive years (2010 to 2019) of large-scale rice-duck co-cultivation and conventional high-yield rice cultivation. The indexes of soil nutrient content, rice yield structure, rice quality, heavy metal content and pesticide residues in paddy fields were tested for comparison. The results showed that compared with conventional rice cultivation, the soil bulk density decreased by 5.65% after years of rice-duck co-cultivation, and the contents of organic matter, total nitrogen, available phosphorus and available potassium in 0-10 cm topsoil increased by 8.71%, 14.29%, 9.68% and 8.34%, respectively, which improved the fertility of paddy soil. The number of grains per panicle, the seed setting rate and the 1000-grain weight of the rice-duck co-cultivation increased by 11.3%, 2.9% and 3.2%, respectively, which was beneficial to the formation of large panicles, but the reduction of effective panicles reduced rice yield by 16.4%. The rate of brown rice and milled rice increased by 4.8% and 3.6%, respectively, the chalky grain rate and chalkiness degree decreased significantly, and the protein content increased by 7.5%. At the same time, the amylose content and hard gel consistency were not significantly different from those of conventional field and the overall rice quality was improved. In the two treatments, the contents of heavy metal elements in the soil and the contents of heavy metal elements and pesticide residues in rice all meet the green standards. Therefore, rice-duck co-cultivation for successive years could improve soil properties, soil fertility and rice quality, but the reduction of effective panicle can significantly reduce rice yield.

Key words: rice-duck co-cultivation, soil nutrients, rice yield, rice quality, heavy metals, pesticide residue

CLC Number:

S834
S511.01

Ji Li, Shao Wenqi, Chen Fuping, Dong Qingjun, Zhang Ankang. Effects of Successive Years of Rice-duck Co-cultivation on Soil Properties, Rice Yield and Quality in Paddy Field[J]. Chinese Agricultural Science Bulletin, 2021, 37(13): 1-7.

Figures/Tables 6

References 25

[1]	沈晓昆. 稻鸭共作:无公害生产有机稻米新技术[M]. 北京: 中国农业科技出版社, 2003: 16-20.
[2]	向敏, 黄鹤春, 裴正峰, 等. 我国稻鸭共作技术发展现状与对策[J]. 畜牧与饲料科学, 2010,31(10):33-36
[3]	郑建初, 谭淑豪, 刘华周, 等. 中国稻鸭共作系统的理论与技术现状及其发展策略[J]. 江苏农业科学, 2005,31(10):1-5
[4]	李惠珠, 张建, 傅荣富, 等. 川岛镇稻鸭共作有机稻米生产效果及技术要点[J]. 安徽农学通报, 2017,23(13):42-43,74.
[5]	王文青, 庄黎萍, 刘益, 等. 优良食味水稻品种南粳46稻鸭共作模式初探[J]. 中国稻米, 2018,24(5):98-102.
[6]	罗璇. 稻田放养适宜鸭品种的筛选及其对稻鸭共作系统的作用[D]. 扬州:扬州大学, 2019.
[7]	罗璇, 安晨, 路璐, 等. 不同鸭品种在“稻鸭共作”系统中的行为学差异及对水稻产量的影响[J]. 中国农学通报, 2019,35(15):159-164.
[8]	宋广鹏, 陈锦文, 陈怡名, 等. 不同单元规模养殖下稻鸭共作系统对土壤肥力和水稻产量的影响[A].中国农学会耕作制度分会2018年度学术年会论文摘要集[C]. 2018: 13.
[9]	禹盛苗, 朱练峰, 欧阳由男, 等. 稻鸭种养模式对稻田土壤理化性状、肥力因素及水稻产量的影响[J]. 土壤通报, 2014,45(1):151-156.
[10]	刘欣, 王强盛, 许国春, 等. 稻鸭共作农作系统的生态效应与技术模式[J]. 中国农学通报, 2015,31(29):90-96.
[11]	张锦, 章家恩, 秦钟, 等. 稻鸭共作对水稻部分株型结构指标的影响[J]. 中国生态农业学报, 2012,20(1):1-6.
[12]	张为强, 印良柏, 王明, 等. 稻鸭共作对稻米品质影响的试验研究[J]. 农业工程技术, 2016,36(35):21-22.
[13]	梁玉刚, 黄璜, 李静怡, 等. 规模化稻鸭共育对水稻株型结构及产量形成的影响[J]. 生态学杂志, 2016,35(10):2752-2758.
[14]	秦钟, 章家恩, 骆世明, 等. 稻鸭共作系统生态服务功能价值的评估研究[J]. 资源科学, 2010,32(5):864-872.
[15]	张苗苗, 宗良纲, 谢桐洲. 有机稻鸭共作对土壤养分动态变化和经济效益的影响[J]. 中国生态农业学报, 2010,18(2):256-260.
[16]	朱金明, 施其俊, 胡南河, 等. 稻鸭共育对稻田土壤理化性状的影响[J]. 安徽农业科学, 2006,34(12):2803.
[17]	杨志辉, 黄璜, 王华. 稻鸭复合生态系统稻田土壤质量研究[J]. 土壤通报, 2004,35(2):117-121.
[18]	全国明, 章家恩, 杨军, 等. 稻鸭共作对稻米品质的影响[J]. 生态学报, 2008(7):3475-3483.
[19]	张军, 刘菁, 陈长青. 有机稻鸭共作对土壤理化性状和细菌群落空间分布的影响[J]. 生态学杂志, 2020,39(3):822-829.
[20]	章家恩, 赵美玉, 陈进, 等. 稻鸭共作方式对水稻生长的影响[J]. 生态科学, 2005,24(2):117-119.
[21]	王强盛, 黄丕生, 甄若宏, 等. 稻鸭共作对稻田营养生态及稻米品质的影响[J]. 应用生态学报, 2004,15(4):639-645.
[22]	魏守辉, 强胜, 马波, 等. 长期稻鸭共作对稻田杂草群落组成及物种多样性的影响[J]. 植物生态学报, 2006(1):9-16. doi: 10.17521/cjpe.2006.0002 pmid: 84A608F2-0C47-4AAC-AD8C-52FDCA8878DC
[23]	章家恩. 近10多年来我国鸭稻共作生态农业技术的研究进展与展望[J]. 中国生态农业学报, 2013,21(1):70-79
[24]	卢跃红, 李海光, 戴志明, 等. 稻鸭共生对鸭肉用性能的影响[J]. 大理学院学报, 2008,7(8):12-14.
[25]	黄兴国. 稻鸭生态种养对稻、鸭生长与营养品质及生态环境的影响研究[D]. 长沙:湖南农业大学, 2008.

耕层深度	稻田类型	pH	土壤容重/(g/cm³)	土壤有机质/(mg/kg)	全氮/(mg/kg)	速效磷/(mg/kg)	速效钾/(mg/kg)
0~10 cm	RD	7.42±0.12b	1.17±0.08b	28.66±2.16a	1.57±0.15a	18.17±1.59a	130.28±10.00a
0~10 cm	CK	7.56±0.15a	1.24±0.05a	26.37±2.00b	1.38±0.10b	16.56±1.72b	120.25±8.77b
10~20 cm	RD	7.52±0.08a	1.32±0.10a	23.76±2.32a	1.25±0.08a	10.32±0.76a	105.60±7.32a
10~20 cm	CK	7.57±0.10a	1.36±0.08a	23.22±1.40a	1.20±0.10b	9.94±0.71a	100.80±6.58b

耕层深度	稻田类型	pH	土壤容重/(g/cm³)	土壤有机质/(mg/kg)	全氮/(mg/kg)	速效磷/(mg/kg)	速效钾/(mg/kg)
0~10 cm	RD	7.42±0.12b	1.17±0.08b	28.66±2.16a	1.57±0.15a	18.17±1.59a	130.28±10.00a
0~10 cm	CK	7.56±0.15a	1.24±0.05a	26.37±2.00b	1.38±0.10b	16.56±1.72b	120.25±8.77b
10~20 cm	RD	7.52±0.08a	1.32±0.10a	23.76±2.32a	1.25±0.08a	10.32±0.76a	105.60±7.32a
10~20 cm	CK	7.57±0.10a	1.36±0.08a	23.22±1.40a	1.20±0.10b	9.94±0.71a	100.80±6.58b

稻田类型	总穗数(×10⁴/hm²)	每穗粒数/粒	结实率/%	千粒重/g	产量/(kg/hm²)
RD	252.2±14.8b	129.0±2.7a	93.5±1.1a	27.18±0.27a	8.3±0.3b
CK	355.9±26.4a	115.9±1.1b	90.8±1.2b	26.34±0.57b	9.9±0.5a

稻田类型	总穗数(×10⁴/hm²)	每穗粒数/粒	结实率/%	千粒重/g	产量/(kg/hm²)
RD	252.2±14.8b	129.0±2.7a	93.5±1.1a	27.18±0.27a	8.3±0.3b
CK	355.9±26.4a	115.9±1.1b	90.8±1.2b	26.34±0.57b	9.9±0.5a

稻田类型	加工品质		外观品质		营养品质		食味品质
稻田类型	糙米率/%	精米率/%	垩白粒率/%	垩白度/%	蛋白质含量/%	赖氨酸含量/%	直链淀粉含量/%	胶稠度/cm	糊化温度/℃
RD	85.9±3.3a	66.1±3.2a	19.2±2.3a	4.2±0.5a	8.0±0.3b	3.5±0.3a	16.7±1.4a	8.7±0.7a	74.7±1.3a
CK	81.9±4.3b	63.5±3.8b	21.6±2.4b	5.1±0.7b	7.5±0.5a	3.6±0.2a	16.3±1.2a	8.3±0.6a	74.5±0.7a