基于农户施肥和土壤肥力的黑龙江水稻减肥潜力分析

doi:10.3864/j.issn.0578-1752.2019.12.007

摘要/Abstract

摘要：

【目的】黑龙江稻田面积320多万公顷,为全国稻田面积最大的省份,10多年来水稻产量一直徘徊在7 000 kg·hm ^-2,也是我国稻田化肥用量（纯N 约150 kg·hm ^-2）最低的省份。在化肥零增长的背景条件下,黑龙江是否存在节肥潜力有待研究。【方法】调查水稻主产区农户施肥情况。2005年调查区域为五常、方正、木兰、宁安、庆安、铁力、尚志、阿城;2008年调查区域为密山、虎林、庆安、五常、宁安、方正、萝北、桦川、富锦和尚志;2015年调查区域为五常、方正、宁安、虎林和庆安。每个地点随机选择一个乡,每个乡随机选择2或者3个村,每村调查10户,共638户。2009—2010年,采集了黑龙江水稻主产区8万多个土壤样品,测定0—20 cm土层速效磷、速效钾养分含量。采用理论适宜施氮量法估算黑龙江稻田氮肥用量;依据作物养分需求量和稻田土壤养分状况,采用磷钾衡量监控方法,估算稻田磷、钾肥适宜施用量,在此基础上分析黑龙江省水稻减肥潜力。【结果】 2005、2008和2015年黑龙江水稻平均产量分别为6 427、7 593和7 142 kg·hm ^-2 ,3年平均产量为7 104 kg·hm ^-2。农户间产量差异较大,高低相差近5 000 kg·hm ^-2。稻田N、P₂O₅和K₂O用量平均分别为141.0、56.6和51.6 kg·hm ^-2,N、P₂O₅和K₂O用量高低相差均超过300 kg·hm ^-2,农户间施肥变异较大,盲目施肥问题突出。稻田土壤速效磷和速效钾的含量分别约为26和138 mg·kg ^-1。速效磷的变异超过了40%,不同区域间土壤肥力差异较大。70%以上的样品速效磷、速效钾含量处于较高水平。要达到7 500 kg·hm ^-2的产量水平,对应的理论适宜N用量为105 kg·hm ^-2,只有20%的农户实现了高产氮素高效,有70%的农户具有节肥潜力,可以节氮超过26%。通过节肥,每千克氮素生产的粮食可由50 kg提高到70 kg。按照目前的产量和土壤养分状况,稻田P₂O₅和K₂O适宜用量分别为41.6和35.9 kg·hm ^-2,可以减量约30%。调研农户中,具有节磷和节钾潜力的农户分别约占总体的71%和72%,处于低产低效的农户均占总体的30%,节肥潜力最大。【结论】黑龙江作为全国施肥量最低的省份,有约70%的农户处于高产不高效或者低产低效水平,过量施肥问题突出,节肥潜力20%以上。

关键词: 寒地, 稻田, 施肥量, 节肥潜力, 产量, 黑龙江

Abstract:

【Objective】Heilongjiang has a paddy field of more than 3.2 million hectares, it is the largest province in China with rice fields. In the past ten years, rice production in Heilongjiang Province has been hovering at 7 000 kg·hm ^-2, while it was the province with the lowest amount of fertilizer in paddy fields in China. Under the background of “fertilizer zero increase”, whether is there potential for fertilizer saving in Heilongjiang Province remains to be studied. 【Method】We investigated paddy field fertilization across different farms in the main rice producing areas in Heilongjiang Province. In 2005, the survey areas were Wuchang, Fangzheng, Mulan, Ning'an, Qing'an, Tieli, Shangzhi and Acheng; in 2008, the survey areas were Mishan, Hulin, Qing'an, Wuchang, Ning'an, Fangzheng, Luobei, Huachuan, Fujin and Shangzhi; the survey areas in 2015 were Wuchang, Fangzheng, Ning'an, Hulin and Qing'an. From each county, a random township was selected, and 2 or 3 villages were randomly selected from each township, then 10 households were surveyed in each village. From 2009 to 2010, more than 80,000 soil samples from the main rice producing areas in Heilongjiang Province were collected, and the phosphorus and potassium nutrient contents in 0-20 cm soil layer were determined. The nitrogen application rate was estimated through theoretical appreciate application rate method. Based on the crop nutrient demand and the soil nutrient status of the paddy field, phosphorus and potassium application rate was evaluated. Fertilizer reduction potential was analyzed in Heilongjiang Province.【Result】According to the research data, the average rice yields in 2005, 2008 and 2015 were 6 427, 7 593 and 7 142 kg·hm ^-2, respectively, and the average annual output was 7 104 kg·hm ^-2. The crop yield differed between farms with a range of nearly 5 000 kg·hm ^-2. The average amount of N, P₂O₅ and K₂O in paddy fields were 141.0, 56.6 and 51.6 kg·hm ^-2, respectively, and the difference in the amount of NPK fertilizers was more than 300 kg·hm ^-2. Therefore, the results showed that fertilization variation among farmers was large, so the problem of blind fertilization was prominent. The content of available phosphorus and available potassium in the paddy soil of Heilongjiang Province were about 26 mg·kg ^-1 and 138 mg·kg ^-1, respectively. The variation of available phosphorus in soil exceeded 40%, and soil fertility varied greatly among different regions. High level phosphorus and potassium accounted for above 70% samples. To reach rice production levels of 7 500 kg·hm ^-2, the theoretical suitable nitrogen application rate was 105 kg·hm ^-2. Only 20% of farmers achieved high yield and high nitrogen efficiency, and 70% of the farmers had fertilizer-saving potential with nitrogen reduction of 26%. Through fertilizer saving, the grain produced per kilogram of nitrogen could be increased from 50 kg to 70 kg. According to the current yield and soil nutrient status, the appropriate amount of phosphate and potassium fertilizer in paddy fields was only 41.6 and 35.9 kg·hm ^-2, which could be reduced by about 30%. Among the surveyed households, farmers whose fields had the potential for phosphorus and potassium-saving accounted for 71% and 72% of the total, respectively, among which the low-yield and low-efficiency farmers accounted for 30% of the total farmers, where the fertilizer-saving potential was the largest.【Conclusion】Although Heilongjiang was the province with the lowest fertilization rate in China, about 70% of farmers were high-yield but low efficiency, or low-yield and low efficiency, so the problem of excessive fertilization was prominent, and the fertilizer-saving potential was more than 20% in Heilongjiang Province.

Key words: cold area, paddy field, fertilizer application rate, fertilizer reduction potential, yield, Heilongjiang Province

彭显龙,王伟,周娜,刘海洋,李鹏飞,刘智蕾,于彩莲. 基于农户施肥和土壤肥力的黑龙江水稻减肥潜力分析[J]. 中国农业科学, 2019, 52(12): 2092-2100.

PENG XianLong,WANG Wei,ZHOU Na,LIU HaiYang,LI PengFei,LIU ZhiLei,YU CaiLian. Analysis of Fertilizer Application and Its Reduction Potential in Paddy Fields of Heilongjiang Province[J]. Scientia Agricultura Sinica, 2019, 52(12): 2092-2100.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2019.12.007

https://www.chinaagrisci.com/CN/Y2019/V52/I12/2092

图/表 6

表1

图1

表2

图2

表3

图3

参考文献 26

[1]	Food and Agriculture Organization of the United Nations. 2016. . 2016. .
[2]	申建波 . 水稻养分资源综合管理理论与实践. 北京: 中国农业大学出版社, 2017: 8, 308.
	SHEN J B. Theory and Practice of Integrated Management of Rice Nutrient Resources. Beijing: China Agricultural University Press, 2017: 8, 308. (in Chinese)
[3]	国家统计局. 中国统计年鉴. 北京: 中国统计出版社, 2016.
	NBS. China Statistical Yearbook. Beijing: China Statistical Publishing House, 2016. (in Chinese)
[4]	陈琦 . 农户水稻施肥现状调查与分析—以江西省、江苏省为例[D]. 南京: 南京农业大学, 2013.
	CHEN Q . Investigation and analysis of famers , fertilization status on rice-taking Jiangxi Province and Jiangsu Province as examples [D]. Nanjing: Nanjing Agricultural University, 2013. (in Chinese)
[5]	显龙, 刘元英, 罗盛国, 范立春, 盛大海 . 寒地稻田施氮状况与氮素调控对水稻投入和产出的影响. 东北农业大学学报, 2007(4):467-472.
	PENG X L, LIU Y Y, LUO S G, FAN L C, SHENG D H . Nitrogen application situation and effects of nitrogen management on cost and output of paddy field in cold area of northeast China.Journal of Northeast Agricultural University, 2007(4):467-472. (in Chinese)
[6]	郭明亮 . 中国水稻氮过量对农药用量的影响[D]. 北京: 中国农业大学, 2016.
	GUO M L . The impact of excessive nitrogen fertilizer on pesticide usage on rice in China[D]. Beijing: China Agricultural University, 2016. (in Chinese)
[7]	巨晓棠 . 理论施氮量的改进及验证—兼论确定作物氮肥推荐量的方法. 土壤学报, 2015,52(2):249-261.
	JU X T . Improvement and validation of theoretical N rate (TNR)-Discussing the methods for N fertilizer recommendation. Acta Pedologica Sinica, 2015,52(2):249-261. (in Chinese)
[8]	吴良泉, 武良, 崔振岭, 陈新平, 张福锁 . 中国水稻区域氮磷钾肥推荐用量及肥料配方研究. 中国农业大学学报, 2016,21(9):1-13.
	WU L Q, WU L, CUI Z L, CHEN X P, ZHANG F S . Studies on recommended nitrogen, phosphorus and potassium application rates and special fertilizer formulae for different rice production regions in China. Journal of China Agricultural University, 2016,21(9):1-13. (in Chinese)
[9]	刘炜, 谷思玉, 白雅梅, 赵京考 . 施肥量与灌溉量对黑龙江省黑土区水稻产量的影响. 东北农业大学学报, 2012,43(4):49-54.
	LIU W, GU S Y, BAI Y M, ZHAO J K . Effect of fertilizer levels and irrigate on yield of rice in black soil area. Journal of Northeast Agricultural University, 2012,43(4):49-54. (in Chinese)
[10]	何萍, 金继运 , Mirasol F. Pampolino, Adrian M. Johnston. 基于作物产量反应和农学效率的推荐施肥方法. 植物营养与肥料学报, 2012,18(2):499-505. doi: 10.11674/zwyf.2012.11248
	HE P, JIN J Y, PAMPOLINO M F, JOHNSTON A M . Approach and decision support system based on crop yield response and agronomic efficiency. Plant Nutrition and Fertilizer Science, 2012,18(2):499-505. (in Chinese) doi: 10.11674/zwyf.2012.11248
[11]	张福锁, 陈新平, 陈清 . 中国主要作物施肥指南. 北京: 中国农业大学出版社, 2009: 3-4.
	ZHANG F S, CHEN X P, CHEN Q. China's Main Crop Fertilization Guidelines. Beijing: China Agricultural University Press, 2009: 3-4. (in Chinese)
[12]	赵晓宇, 罗盛国, 刘元英, 彭显龙 . 寒地稻田土壤养分状况. 东北农业大学学报, 2009,40(2):34-37.
	ZHAO X Y, LUO S G, LIU Y Y, PENG X L . Nutrient status of paddy field in cold area of northeast China. Journal of Northeast Agricultural University, 2009,40(2):34-37. (in Chinese)
[13]	田卡, 钟旭华, 黄农荣, 潘俊峰 . 还田稻草的钾素利用及其增产效应研究. 中国稻米, 2014,20(3):54-57. doi: 10.3969/j.issn.1006-8082.2014.03.012
	TIAN K, ZHONG X H, HUANG N R, PAN J F . Utilization of potassium in returned straw and its effect on grain yield in rice. China Rice, 2014,20(3):54-57. (in Chinese) doi: 10.3969/j.issn.1006-8082.2014.03.012
[14]	高利伟, 马林, 张卫峰, 王方浩, 马文奇, 张福锁 . 中国作物秸秆养分资源数量估算及其利用状况. 农业工程学报, 2009,25(7):173-179.
	GAO L W, MA L, ZHANG W F, WANG F H, MA W Q, ZAHNG F S . Estimation of nutrient resource quantity of crop straw and its utilization situation in China. Transactions of the Chinese Society of Agricultural Engineering, 2009, 25(7):173-179. (in Chinese)
[15]	尹娟, 费良军, 田军仓, 王艳芳, 韩丙芳, 张学科, 勉韶平 . 水稻田中氮肥损失研究进展. 农业工程学报, 2005(6):189-191.
	YIN J, FEI L J, TIAN J C, WANG Y F, HAN B F, ZHANG X K, MIAN S P . Research advance of nitrogen fertilizer losses from paddy field. Transactions of the Chinese Society of Agricultural Engineering, 2005(6):189-191. (in Chinese)
[16]	PENG X L, YANG Y M, YU C L, CHEN L N, ZHANG M C, LIU Z L, LUO S G, LIU Y Y . Crop management for increasing rice yield and nitrogen use efficiency in Northeast China. Agronomy Journal, 2015,107(5):1682-1690. doi: 10.2134/agronj15.0013
[17]	武良 . 基于总量控制的中国农业氮肥需求及温室气体减排潜力研究[D]. 北京: 中国农业大学, 2014.
	WU L . Nitrogen fertilizer demand and greenhouse gas mitigation potential under nitrogen limiting conditions for Chinese agriculture production[D]. Beijing: China Agricultural University, 2014. (in Chinese)
[18]	PENG X L, LIU Y Y, LUO S G, FAN L C, SONG T X, GUO Y W . Effects of site-specific nitrogen management on yield and dry matter accumulation of rice from cold areas of northeastern China. Journal of Integrative Agriculture, 2007,6(6):715-723.
[19]	刘海涛, 童良军, 赵立琴, 王玉良 . 寒地水稻磷素适宜施用量的研究. 黑龙江八一农垦大学学报, 2011,23(4):15-19.
	LIU H T, TONG L J, ZHAO L Q, WANG Y L . The study on reasonable dosage of phosphate fertilization in paddy in cold areas. Journal of Heilongjiang Bayi Agricultural University, 2011,23(4):15-19. (in Chinese)
[20]	郝小雨, 周宝库, 马星竹, 高中超 . 长期不同施肥措施下黑土作物产量与养分平衡特征. 农业工程学报, 2015,31(16):178-185.
	HAO X Y, ZHOU B K, MA X Z, GAO Z C . Characteristics of crop yield and nutrient balanced in black soil under long-term different fertilization measures. Transactions of the Chinese Society of Agricultural Engineering, 2015,31(16):178-185. (in Chinese)
[21]	周米平, 刘金华, 杨靖民, 于小斌 . 吉林省不同区域黑土供钾能力研究. 吉林农业大学学报, 2008,30(5):712-715,752.
	ZHOU M P, LIU J H, YANG J M, YU X B . Study on the capability of releasing potassium in several phaeozem in Jilin Province. Journal of Jilin Agricultural University, 2008,30(5):712-715, 752. (in Chinese)
[22]	彭显龙, 刘元英, 罗盛国, 李广宇, 盛大海 . 寒地稻田钾素状况与平衡. 东北农业大学学报, 2008,39(1):46-49.
	PENG X L, LIU Y Y, LUO S G, LI G Y, SHENG D H . Potassium state and balance of paddy field in cold area of Northeast China. Journal of Northeast Agricultural University, 2008,39(1):46-49. (in Chinese)
[23]	彭显龙, 袁英才, 刘元英, 罗盛国 . 实地养分管理对寒地水稻磷钾吸收的影响. 东北农业大学学报, 2011,42(7):39-45.
	PENG X L, YUAN Y C, LIU YY, LUO SG . Effect of site-specific nutrient management on P and K uptake of rice in cold region of northeastern China. Journal of Northeast Agricultural University, 2011,42(7):39-45. (in Chinese)
[24]	王英 . 黑龙江省农田养分循环与平衡状况的初步探讨. 土壤通报, 2002(4):268-271.
	WANG Y . Preliminary study on nutrient's cycle and balance in farmland soil of Heilongjiang Province.Chinese Journal of Soil Science, 2002(4):268-271. (in Chinese)
[25]	王建国, 王德禄, 王守宇, 何喜云, 王忠伟 . 黑龙江农田养分平衡和养分水平的动态变化. 农业系统科学与综合研究, 2000,16(2):124-127.
	WANG J G, WANG D L, WANG S Y, HE X Y, WANG Z W . Dynamic variation of the farmland nutrient’s balance and its content in Heilongjiang Province. System Sciences and Comprehensive Studies in Agriculture, 2000, 16(2):124-127. (in Chinese)
[26]	金梦灿, 张舒予, 郜红建, 高时凤, 王宜坤 . 麦秆还田下钾肥减量对水稻产量及钾肥利用率的影响. 中国生态农业学报, 2017,25(11):1653-1660.
	JIN M C, ZHANG S Y, GAO H J, GAO S F, WANG Y K . Effects of reducing potassium fertilizer on rice yield and potassium use efficiency under wheat straw return condition. Chinese Journal of Eco-Agriculture, 2017,25(11):1653-1660. (in Chinese)

土壤养分等级 Soil nutrient level	校正系数 Correction coefficient	施磷量 Phosphorus application rate (kg P₂O₅·hm^-2)	施钾量 Potassium application rate (kg K₂O·hm^-2)
低 Low	1.25	产量/100×100kg籽粒需磷量×1.25 Yield/100×Potassium content of 100 kg grain×1.25	产量/100×100kg籽粒需钾量×0.4×1.25 Yield/100×Phosphorus content of 100 kg grain×0.4×1.25
中Medium	1.00	产量/100×100kg籽粒需磷量×1 Yield/100×Potassium content of 100 kg grain×1	产量/100×100kg籽粒需钾量×0.4×1 Yield/100×Phosphorus content of 100 kg grain×0.4×1
高 High	0.75	产量/100×100kg籽粒需磷量×0.75 Yield/100×Potassium content of 100 kg grain×0.75	产量/100×100kg籽粒需钾量×0.4×0.75 Yield/100×Phosphorus content of 100 kg grain×0.4×0.75
极高 Especially high	0.50	产量/100×100kg籽粒需磷量×0.5 Yield/100×Potassium content of 100 kg grain×0.5	产量/100×100kg籽粒需钾量×0.4×0.5 Yield/100×Phosphorus content of 100 kg grain×0.4×0.5

养分 Nutrient	最大值 Max	最小值 Min.	平均值±标准差 Average ± Standard deviation	变异系数 Coefficient of variation (%)	各级养分占比 Nutrient ratio at all levels (%)				样本数 n
养分 Nutrient	最大值 Max	最小值 Min.	平均值±标准差 Average ± Standard deviation	变异系数 Coefficient of variation (%)	低 Low	中 Medium	高 High	极高 Especially high	样本数 n
速效磷 Available phosphorus (mg·kg^-1)	75.30	5.00	26.00±10.46	40.22	3.87	26.85	52.50	17.35	88183
速效钾 Available potassium (mg·kg^-1)	433.00	56.00	138.14±50.94	7.57	4.89	22.28	41.19	33.09	86260