Effects of Tillage Methods on Ammonia Volatilization of Early Season Rice-ratooning Rice Fields

doi:10.16258/j.cnki.1674-5906.2021.08.009

Ecology and Environment ›› 2021, Vol. 30 ›› Issue (8): 1627-1633.DOI: 10.16258/j.cnki.1674-5906.2021.08.009

• Research Articles • Previous Articles Next Articles

Effects of Tillage Methods on Ammonia Volatilization of Early Season Rice-ratooning Rice Fields

KONG Pan(), XIA Sujing, ZHANG Haiwei, ZHU Jianqiang^*()

College of Agriculture, Yangtze University, Jingzhou 434025, China

Received:2021-05-19 Online:2021-08-18 Published:2021-11-03
Contact: ZHU Jianqiang

耕作方式对早稻-再生稻稻田氨挥发的影响

孔盼(), 夏苏敬, 张海维, 朱建强^*()

长江大学农学院,湖北荆州 434025

通讯作者: 朱建强
作者简介:孔盼（1994年生）,男,硕士研究生,研究方向为作物栽培与耕作。E-mail: 1006282958@qq.com
基金资助:
国家重点研发计划项目(2016YFD0300907)

Abstract

Abstract:

To compare the differences in ammonia volatilization emission of early season rice-ratooning rice field under different tillage methods, four tillage methods, including plowing once and rotary tillage once (T1), plowing once and rotary tillage 2 times (T2), no plowing of field and rotary tillage 2 times (T3) and no plowing of field and rotary tillage 3 times(T4), were set up according to whether the plowing before winter and the rotary tillage status before transplanting. Using a random block design with Fengliangyouxiang 1 as the material, the changes of soil ammonia volatilization and NH₄⁺-N in paddy field water during the rice grown season as well as rice yield were measured to provide scientific basis for reducing nitrogen loss from early season rice-ratooning rice field. The results showed that, the cumulative amount of ammonia volatilization of different treatments accounted for 6.6%?18.8%, 5.6%?13.7%, 9.5%?25.2% and 7.9%?21.9% of the nitrogen input rate, respectively. The emission intensity of ammonia volatilization for each treatment in early rice season and ratooning rice season reached a significant level. The order of ammonia volatilization flux, cumulative amount and emission intensity of each treatment were as following T3>T4>T1>T2. Tillage methods had significant effects on the ammonia volatilization and the yield of early rice. The rice yield of the different tillage methods showed a trend that T2>T1>T4>T3, that was, the amount of ammonia volatilization decreased with the increase in the rice yield. The T2 treatment resulted in the smallest amount of ammonia volatilization and the greatest rice yield. This was mainly owing to the reduced nitrogen loss by improving soil structure. These results suggest that plowing once and then double rotation tillage (T2) is beneficial to reduce ammonia volatilization emission, promote rice growth and development, and improve rice yield. Therefore, plowing once and then double rotation tillage is a recommended tillage method for a production mode of early season rice-ratooning rice.

Key words: ammonia volatilization flux, ammonia volatilization intensity, tillage methods, NH₄⁺-N content in the surface water, early rice-ratooning rice, Jianghan Plain

摘要：

为比较不同耕作方式下早稻-再生稻稻田的氨挥发排放差异,采用随机区组设计,以中稻品种丰两优香1号为材料,按冬前是否翻耕和插秧前旋耕情况,设置4种耕作方式：翻耕一次旋耕一次（T1）、翻耕一次旋耕两次（T2）、不翻耕旋耕两次（T3）和不翻耕旋耕3次（T4）,观察4种耕作方式下土壤氨挥发、田面水NH₄⁺-N变化及产量,以期为早稻-再生稻稻田有效降低氨挥发提供理论依据。结果表明,2019年水稻各生育期不同处理的氨挥发累积量分别占施氮量的6.6%—18.8%、5.6%—13.7%、9.5%—25.2%和7.9%—21.9%,其早稻和再生稻各处理氨挥发排放强度均达到显著水平,各处理氨挥发通量、累积量及排放强度大小均为T3>T4>T1>T2;耕作方式既影响氨挥发又影响早稻产量,不同耕作处理下水稻产量均呈现T2>T1>T4>T3的趋势,即氨挥发与水稻产量呈现此消彼长的关系,T2的氨挥发损失最小而产量最高,主要原因是该耕作方式通过改善土壤结构减少了氮素损失。以上分析表明,翻耕一次旋耕两次（T2）可减少氨挥发排放,促进水稻生长发育,有利于提高水稻产量,是值得推荐采用的适宜早稻-再生稻生产的耕作方式。

关键词: 氨挥发通量, 氨挥发强度, 耕作方式, 田面水NH₄⁺-N, 早稻-再生稻, 江汉平原

CLC Number:

S344
X171.1

KONG Pan, XIA Sujing, ZHANG Haiwei, ZHU Jianqiang. Effects of Tillage Methods on Ammonia Volatilization of Early Season Rice-ratooning Rice Fields[J]. Ecology and Environment, 2021, 30(8): 1627-1633.

孔盼, 夏苏敬, 张海维, 朱建强. 耕作方式对早稻-再生稻稻田氨挥发的影响[J]. 生态环境学报, 2021, 30(8): 1627-1633.

Figures/Tables 8

References 22

[1]	FAN X H, SONG Y S, LIN D X, 2006. Ammonia volatilization losses and ¹⁵N balance from urea applied to rice on a paddy soil[J]. Journal of Environmental Sciences, 18(2): 299-303.
[2]	LIANG X Q, ZHANG H F, HE M M, et al., 2016. No-tillage effects on grain yield, N use efficiency, and nutrient runoff losses in paddy fields[J]. Environ-mental Science and Pollution Research, 23(21): 21451-21459.
[3]	MKHABELA M S, MADANI R A, GONDON D, et al., 2007. Gaseous and leaching nitrogen losses from no-tillage and conventional tillage systems following surface application of cattle manure[J]. Soil & Tillage Research, 98(2): 187-199.
[4]	PHILPPE R, DENIS A, ANGERS, et al., 2008. Ammonia volatilization following surface application of urea to tilled and no-till soils: A laboratory comparison[J]. Soil & Tillage Research, 103(2): 310-315.
[5]	ZHANG H, YANG Z L, LUO L G, et al., 2011. Study on the ammonia volatilization from paddy field in irrigation area of the Yellow River[J]. Plant Nutrition and Fertilizer Science, 17(5): 1131-1139.
[6]	曹凑贵, 李成芳, 寇志奎, 等, 2010. 不同类型氮肥和耕作方式对稻田土壤氨挥发的影响[J]. 江西农业大学学报, 32(5): 881-886.
	CAO C G, LI C F, KOU Z K, et al., 2010. Effects of N source and tillage on NH₃ volatilization from paddy soils[J]. Acta Agriculturae Universitis Jiangxiensis, 32(5): 881-886.
[7]	邓美华, 尹斌, 张绍林, 等, 2006. 不同施氮量和施氮方式对稻田氨挥发损失的影响[J]. 土壤, 38(3): 263-269.
	DENG M H, YIN B, ZHANG S L, et al., 2006. Effects of rate and method of N application on ammonia volatilization in paddy fields[J]. Soils, 38(3): 263-269.
[8]	冯国禄, 杨仁斌, 2011. 耕作模式和滞水时间对稻田中氮磷动态变化的影响研究[J]. 农业环境科学学报, 30(5): 917-924.
	FENG G L, YANG R B, 2011. Effect of tillage models and water logging time on dynamics of nitrogen and phosphorus in paddy field[J]. Journal of Agro-Environment Science, 30(5): 917-924.
[9]	葛畅, 刘慧琳, 张世文, 等, 2018. 耕作方式和土壤类型对皖北旱作农田土壤紧实度的影响[J]. 水土保持研究, 25(5): 89-94.
	GE C, LIU H L, ZHANG S W, et al., 2018. Effects of tillage methods and soil types on characteristics of soil compaction in rainfed farmland in northern Anhui province[J]. Research of Soil and Water Conservation, 25(5): 89-94.
[10]	黄进宝, 范晓晖, 张绍林. 2006. 太湖地区铁渗水耕人为土稻季上氮肥的氨挥发[J]. 土壤学报, (5):786-792.
	HUANG J B, FAN X H, ZHANG S L, 2006. Ammonia volatilization from nttrogen fertilzer in the rice field of Fe-leachii-stagnic anthrosols in the Taihu Lake region[J]. Acta Pedologica Sinica, (5): 786-792.
[11]	刘世平, 陈文林, 聂新涛, 等, 2007. 麦稻两熟地区不同埋深对还田秸秆腐解进程的影响[J]. 植物营养与肥料学报, 13(6): 1049-1053.
	LIU S P, CHEN W L, NIE X T, et al., 2007. Effect of embedding depth on decomposition course of crop residues in rice-wheat system[J]. Plant Nutrition and Fertilizer Science, 13(6): 1049-1053.
[12]	刘骁蒨, 涂仕华, 孙锡发, 等, 2013. 秸秆还田与施肥对稻田土壤微生物生物量及固氮菌群落结构的影响[J]. 生态学报, 33(17): 5210-5218.
	LIU X Q, TU S H, SUN X F, et al., 2013. Effect of different fertilizer combinations and straw return on microbial biomass and nitrogen-fixing bacteria community in a paddy soil[J]. Acta Ecologica Sinica, 33(17): 5210-5218. DOI URL
[13]	马玉华, 刘兵, 张枝盛, 等, 2013. 免耕稻田氮肥运筹对土壤NH₃挥发及氮肥利用率的影响[J]. 生态学报, 33(18): 5556-5564.
	MA Y H, LIU B, ZHANG Z S, et al., 2013. Effects of nitrogen management on NH₃ volatilization and nitrogen use efficiency under no-tillage paddy fields[J]. Acta Ecologica Sinica, 33(18): 5556-5564. DOI URL
[14]	区惠平, 周柳强, 黄金生, 等, 2013. 不同施氮量对稻田氨挥发损失的影响[J]. 南方农业学报, 44(11): 1851-1855.
	QU H P, ZHOU L Q, HUANG J S, et al., 2013. Nitrogen application impact on ammonia volatilization in paddy field[J]. Journal of Southern Agriculture, 44(11): 1851-1855.
[15]	宋勇生, 范晓晖, 2003. 稻田氨挥发研究进展[J]. 生态环境学报, 12(2): 240-244.
	SONG Y S, FAN X H, 2003. Summanry of research on ammonia volatilization in paddy soil[J]. Ecology and Environmnet, 12(2): 240-244.
[16]	王朝辉, 刘学军, 巨晓棠, 等, 2002. 田间土壤氨挥发的原位测定通气法[J]. 植物营养与肥料学报, 8(2): 205-209.
	WANG Z H, LIU X J, XIAO X P, et al., 2002. Field in situ determination of ammonia volatilization from soil: Venting method[J]. Plant Natrition and Fertilizen Science, 8(2): 205-209.
[17]	王大鹏, 杜玉赫, 罗雪华, 等, 2018. 橡胶林下砖红壤不同氮肥处理氨挥发特征[J]. 生态环境学报, 27(4): 685-691.
	WANG D P, DU Y H, LUO X H, et al., 2018. Characteristics of ammonia volatilization under different nitrogen managements in red latosol of rubber plantation[J]. Ecology and Environmental Sciences, 27(4): 685-691.
[18]	汪军, 王德建, 张刚, 等, 2013. 麦秸全量还田下太湖地区两种典型水稻土稻季氨挥发特性比较[J]. 环境科学, 34(1): 27-33.
	WANG J, WANG D J, ZHANG G, et al., 2013. Comparing the ammonia volatilization characteristic of two typical paddy soil with total wheat straw returning in Taihu Lake region[J]. Environmental Science, 34(1): 27-33. DOI URL
[19]	姚秀娟, 2007. 翻耕与旋耕作业对水稻生产的影响[J]. 现代化农业 (7): 27-28.
	YAO X J, 2007. Effect of turning and rotary tillage on rice production[J]. Modernizing Agriculture (7): 27-28.
[20]	张大伟, 刘建, 王波, 等, 2009. 连续两年秸秆还田与不同耕作方式对直播稻田土壤理化性质的影响[J]. 江西农业学报, 21(8): 53-56.
	ZHANG D W, LIU J, WANG B, et al., 2009. Effects of straw-returning and different tillage modes on physical and chemical properties of direct seeding paddy soil[J]. Acta Agriculturae Jiangxi, 21(8): 53-56.
[21]	朱兆良, 2000. 农田中氮肥的损失与对策[J]. 土壤与环境, 9(1): 1-6.
	ZHANG Z L, 2000. Loss of fertilizer n from plants-soil system and the strategies and techniques for its reduction[J]. Soil and Environmental Sciences, 9(1): 1-6.
[22]	张向前, 杨文飞, 徐云姬, 2019. 中国主要耕作方式对旱地土壤结构及养分和微生态环境影响的研究综述[J]. 生态环境学报, 28(12): 2464-2472.
	ZHANG X Q, YANG W F, XU Y J, 2019. Effects of main tillage methods on soil structure, nutrients and micro-ecological environment of upland in China: A review[J]. Ecology and Environmental Sciences, 28(12): 2464-2472.

处理 Treatment	早稻施入基肥后2天 2 days after applying basal fertilizer to early rice	早稻施入分蘖期后3天 3 days after applying tillering fertilizer to early rice	再生稻施入促芽肥后2天 2 days after applying germination promoting fertilizer to ratooning rice	再生稻施入提苗肥后2天 2 days after applying seedling raising fertilizer to ratooning rice
T1	2.34±0.58c	8.40±1.75b	3.52±0.90abc	2.98±0.07bc
T2	2.26±0.75c	3.92±0.37c	2.30±0.39c	2.10±0.18c
T3	6.32±0.92a	11.25±0.48a	5.55±1.19a	4.63±0.89a
T4	4.77±0.25b	10.08±1.04ab	4.00±0.59ab	3.61±0.61ab

处理 Treatment	早稻施入基肥后2天 2 days after applying basal fertilizer to early rice	早稻施入分蘖期后3天 3 days after applying tillering fertilizer to early rice	再生稻施入促芽肥后2天 2 days after applying germination promoting fertilizer to ratooning rice	再生稻施入提苗肥后2天 2 days after applying seedling raising fertilizer to ratooning rice
T1	2.34±0.58c	8.40±1.75b	3.52±0.90abc	2.98±0.07bc
T2	2.26±0.75c	3.92±0.37c	2.30±0.39c	2.10±0.18c
T3	6.32±0.92a	11.25±0.48a	5.55±1.19a	4.63±0.89a
T4	4.77±0.25b	10.08±1.04ab	4.00±0.59ab	3.61±0.61ab

处理 Treatment	早稻季 In early rice season			再生稻 In ratooning rice season			全生育期 Whole growth period
处理 Treatment	基肥期 Base fertilizer period	分蘖肥期 Tillering fertilizer period	小计 Sub-total	促芽肥期 Germination-promoting fertilizer period	提苗肥期 Seedling raising fertilizer period	小计 Sub-total	全生育期 Whole growth period
T1	13.45±0.12b	12.04±2.33a	25.49±2.44b	10.38±4.85ab	4.54±0.08bc	14.92±4.82ab	40.41±6.36b
T2	12.06±0.46b	7.21±0.51b	19.27±0.08c	5.86±0.82b	3.83±0.31c	9.69±1.13b	28.96±1.24c
T3	19.18±1.71a	14.69±0.82a	33.87±0.92a	13.89±1.77a	6.55±0.71a	20.44±1.18a	54.31±2.62a
T4	18.32±1.53a	13.50±1.44a	31.82±0.63a	12.08±1.10a	5.48±0.79ab	17.56±1.79a	49.38±3.74a

处理 Treatment	早稻季 In early rice season			再生稻 In ratooning rice season			全生育期 Whole growth period
处理 Treatment	基肥期 Base fertilizer period	分蘖肥期 Tillering fertilizer period	小计 Sub-total	促芽肥期 Germination-promoting fertilizer period	提苗肥期 Seedling raising fertilizer period	小计 Sub-total	全生育期 Whole growth period
T1	13.45±0.12b	12.04±2.33a	25.49±2.44b	10.38±4.85ab	4.54±0.08bc	14.92±4.82ab	40.41±6.36b
T2	12.06±0.46b	7.21±0.51b	19.27±0.08c	5.86±0.82b	3.83±0.31c	9.69±1.13b	28.96±1.24c
T3	19.18±1.71a	14.69±0.82a	33.87±0.92a	13.89±1.77a	6.55±0.71a	20.44±1.18a	54.31±2.62a
T4	18.32±1.53a	13.50±1.44a	31.82±0.63a	12.08±1.10a	5.48±0.79ab	17.56±1.79a	49.38±3.74a

处理 Treatment	早稻施入基肥后2天 2 days after applying basal fertilizer to early rice	早稻施入分蘖期后3天 3 days after applying tillering fertilizer to early rice	再生稻施入促芽肥后2天 2 days after applying germination promoting fertilizer to ratooning rice	再生稻施入提苗肥后2天 2 days after applying seedling raising fertilizer to ratooning rice
T1	26.31±0.71b	31.24±3.74b	41.37±5.53bc	42.45±2.74b
T2	22.54±2.59b	18.83±1.17c	39.23±2.09c	33.02±1.51c
T3	36.51±0.51a	51.33±4.29a	56.77±4.11a	52.14±1.51a
T4	33.05±2.17a	45.54±7.61a	48.85±3.21ab	46.39±3.06b

Effects of Tillage Methods on Ammonia Volatilization of Early Season Rice-ratooning Rice Fields

耕作方式对早稻-再生稻稻田氨挥发的影响

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 8

References 22

Related Articles 0

Recommended Articles

Metrics

Comments

生长季 Growing season	处理 Treatment	产量 Yield/ (kg∙hm^-2)	氮肥偏生产力 Partial productivity of nitrogen fertilizer/(kg∙kg^-1)
早稻 Early rice	T1	6800.00±529.15ab	43.31±2.75ab
	T2	7533.33±1006.64a	47.98±5.24a
	T3	4833.33±208.17c	30.79±1.08c
	T4	5200.00±137.07bc	33.12±8.51bc
再生稻 Regenerated rice	T1	3533.33±1006.64a	28.45±6.62a
	T2	3800.00±1249.00a	30.60±8.21a
	T3	2866.67±503.32a	18.79±3.31a
	T4	3466.67±611.01a	27.91±4.02a