长期施肥紫色土有效磷变化及其对稻麦轮作产量的影响

doi:10.3864/j.issn.0578-1752.2021.21.010

摘要/Abstract

摘要：

【目的】通过总结分析长期施肥处理下紫色土稻麦轮作土壤有效磷的变化特征,以及土壤磷素变化对作物产量的影响,为紫色土稻麦轮作磷素管理提供理论依据。【方法】依托国家肥力监测网紫色土肥力监测试验站27年的稻麦轮作定位试验,选取10种不同施肥处理：CK处理（只种作物不施肥）;N、NP、NK、PK、NPK为不同氮（N）、磷（P）、钾（K）化肥配施处理;M、NPKS、NPKM、1.5NPK+M为有机肥（M）、秸秆还田（S）及其与化肥配施处理。试验数据涵盖1991—2018年,测定不同施肥处理下土壤有效磷含量和作物产量,计算100 kg籽粒磷素吸收量和磷肥利用率,分析土壤磷素变化对累积磷盈亏的响应,采用不同模型计算土壤磷素农学阈值。【结果】长期施用磷肥能够显著提高土壤有效磷含量,各施磷处理有效磷年均增量为0.80—2.32 mg·kg^-1;而不施磷处理CK、N、NK和单施有机肥处理M的土壤有效磷含量则逐年下降至平稳状态。不施磷处理土壤磷素一直处于亏缺状态,施磷各处理27年后土壤累积磷盈余量为244.8—698.2 kg P·hm^-2,其中1.5NPK+M处理累积磷盈余量最高;施磷处理土壤累积盈余量与土壤Olsen-P增量呈显著线性相关,土壤每盈余磷100 kg·hm^-2,土壤有效磷含量提高4.27—6.5 mg·kg^-1。磷肥施用能显著提升稻麦轮作系统作物产量和吸磷量,100 kg水稻籽粒需磷量为0.17—0.41 kg,100 kg小麦籽粒需磷量为0.25—0.57 kg;试验各处理的磷肥利用率为10.3%—39.7%;4种模型（线性-平台模型、双直线模型、BoxLucas模型和米切里西模型）均能较好地拟合作物产量与紫色土有效磷含量的响应关系,其中双直线模型的拟合度最好,其计算的水稻和小麦的土壤有效磷农学阈值分别为13.28和9.93 mg·kg^-1。【结论】在紫色土水稻-小麦轮作体系中,合理施用磷肥能显著提高作物吸磷量、产量以及土壤有效磷含量。推荐双直线模型用于计算紫色土稻麦轮作体系下土壤有效磷的农学阈值,生产上应根据土壤有效磷含量及其农学阈值调整磷肥施用量。

关键词: 紫色土, 稻麦轮作, 长期施肥, 有效磷, 累积磷盈亏, 农学阈值

Abstract:

【Objective】Based on the analyses of soil Olsen-P variation in the purple soil and its effects on crop yield under long-term different fertilizations in the rice-wheat rotation, this paper provided a theoretical basis for efficient and rational P management in purple soil. 【Method】This study were conducted based on the 27-year rice-wheat rotation trial platform in the Purple Soil Fertility Monitoring Station of the national soil fertility monitoring network. The soil Olsen-P content and crop yields of 10 different fertilization treatments were measured and compared, including CK treatment (crops growing without fertilization), N, NP, NK, PK, NPK (treatments with different chemical nitrogen (N), phosphorus (P), potassium (K) fertilizations), and M, NPKS, NPKM, 1.5NPK+M (chemical fertilizer combined with organic manure (M) and straw return (S) treatments) from 1991 to 2018. Then, the plant P uptake per 100 kg grains yield and the recovery rate of P by different fertilizations were calculated and compared, respectively. The responses between soil Olsen-P increment and cumulative P depletion were explored. In addition, the response curve of crop yield to soil Olsen-P content in the purple soil was figured by different modelling methods. The agronomic critical value of Olsen-P content in purple soil was finally calculated. 【Result】Long-term application of P fertilizer could significantly increase soil Olsen-P content. The average annual increment of soil Olsen-P content was 0.80-2.32 mg·kg^-1 in P application treatments, whereas the soil Olsen-P content of CK, N, NK and M treatments decreased year by year to a steady state. The cumulative P surpluses by the 27-year P application treatments were 244.8-698.2 kg P·hm^-2, among which the cumulative P surplus of the 1.5NPK+M treatment was the highest. A significant linear correlation between cumulative soil P surplus and soil Olsen-P increment could be found in P application treatments. In detail, soil Olsen-P increased by 4.27-6.5 mg·kg^-1with 100 kg·P·hm^-2 cumulative surplus in P application treatments. Fertilization could significantly increase crop yields and P uptake in the long-term rice-wheat rotation system. The plant P uptake per 100 kg rice yield was 0.17-0.41 kg, whereas the plant P uptake per 100 kg wheat yield was 0.25-0.57 kg. The utilization rates of P under all treatments were 10.3%-39.7%. Four models (linear-platform model, linear-linear model, BoxLucas model, and Michelice model) were good for fitting the response of crop yield to Olsen-P content in purple soil. The agronomic critical value of Olsen-P content in purple soil of rice and wheat calculated by linear-linear model (with the highest R ²) were 13.28 mg·kg^-1 and 9.93 mg·kg^-1, respectively. 【Conclusion】Appropriate application of P fertilizer could significantly improve the P uptake of crop in rice-wheat rotation system on purple soil, crop yields and soil available P content. The linear-linear model was recommended to calculate the critical value of Olsen-P content in purple soil under rice-wheat rotation system. Application rates of P fertilizer should be adjusted timely according to the difference between actual soil Olsen-P content and agronomic critical value of Olsen-P content in productivity.

Key words: purple soil, rice-wheat rotation, long-term fertilization, Olsen-P content, total P balance, agronomic critical value of Olsen-P

任嘉欣,刘京,陈轩敬,张跃强,张勇,王洁,石孝均. 长期施肥紫色土有效磷变化及其对稻麦轮作产量的影响[J]. 中国农业科学, 2021, 54(21): 4601-4610.

REN JiaXin,LIU Jing,CHEN XuanJing,ZHANG YueQiang,ZHANG Yong,WANG Jie,SHI XiaoJun. Variation of Available Phosphorus in Purple Soil and Its Effects on Crop Yield of Rice-Wheat Rotation Under Long-Term Fertilizations[J]. Scientia Agricultura Sinica, 2021, 54(21): 4601-4610.

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https://www.chinaagrisci.com/CN/Y2021/V54/I21/4601

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参考文献 35

[1]	陆景陵. 植物营养学. 北京: 中国农业大学出版社, 2005.
	LU J L. Plant Nutrition. Beijing: China Agriculture University Press, 2005. (in Chinese)
[2]	KOPITTKE P M, DALAL R C, WANG P, MENZIES N W. Effects of long-term cultivation on phosphorus (P) in five low-input, subtropical Australian soils. Agriculture Ecosystems & Environment, 2018, 252:191-199. doi: 10.1016/j.agee.2017.10.018
[3]	SURIYAGODA L D B, RYAN M H, RENTON M, LAMBERS M. Plant responses to limited moisture and phosphorus availability: A meta-analysis. Advances in Agronomy, 2014, 124:143-200.
[4]	LI H G, HUANG G, MENG Q, MA L N, YUANL X, WANG F Y, ZHANG W, CUI Z, SHEN J Y, CHEN X G, JIANG R F, ZHANG F S. Integrated soil and plant phosphorus management for crop and environment in China: A review. Plant and Soil, 2011, 349:157-167. doi: 10.1007/s11104-011-0909-5
[5]	BAI Z H, LI H G, YANG X Y, ZHOU B K, SHI X J, WANG B R, LI D C, SHEN J B, CHEN Q, QIN W, OENEMA O, ZHANG F S. The critical soil P levels for crop yield, soil fertility and environmental safety in different soil types. Plant and Soil, 2013, 372:27-37. doi: 10.1007/s11104-013-1696-y
[6]	YANG Y J, ZHANG H P, QIAN X Q, DUAN J N, WANG G L. Excessive application of pig manure increases the risk of P loss in calcic cinnamon soil in China. Science of the Total Environment, 2017, 609:102-108. doi: 10.1016/j.scitotenv.2017.07.149
[7]	王斌, 刘骅, 李耀辉, 马兴旺, 王西和, 马义兵. 长期施肥条件下灰漠土磷的吸附与解吸特征. 土壤学报, 2013, 50(4):727-733.
	WANG B, LIU H, LI Y H, MA X W, WANG X H, MA Y B. Phosphorus adsorption and desorption characteristics of gray desert soil under long-term fertilization. Acta Pedologica Sinica, 2013, 50(4):727-733. (in Chinese)
[8]	卜容燕, 任涛, 鲁剑巍, 李小坤, 丛日环, 李云春, 汪洋, 鲁君明. 水稻-油菜轮作条件下磷肥效应研究. 中国农业科学, 2014, 7(6):1227-1234.
	BU R Y, REN T, LU J W, LI X K, CONG R H, LI Y C, WANG Y, LU J M. Analysis of phosphorus fertilizer efficiency under rice-rapeseed rotation system. Scientia Agricultura Sinica, 2014, 7(6):1227-1234. (in Chinese)
[9]	展晓莹, 任意, 张淑香, 康日峰. 中国主要土壤有效磷演变及其与磷平衡的响应关系. 中国农业科学, 2015, 48(23):4728-4737.
	ZHAN X Y, REN Y, ZHANG S X, KANG R F. Changes in Olsen phosphorus concentration and its response to phosphorus balance in the main types of soil in China. Scientia Agricultura Sinica, 2015, 48(23):4728-4737. (in Chinese)
[10]	李冬初, 王伯仁, 黄晶, 张扬珠, 徐明岗, 张淑香, 张会民. 长期不同施肥红壤磷素变化及其对产量的影响. 中国农业科学, 2019, 52(21):3830-3841.
	LI D C, WANG B R, HUANG J, ZHANG Y Z, XU M G, ZHANG S X, ZHANG H M. Change of phosphorus in red soil and its effect to grain yield under long-term different fertilizations. Scientia Agricultura Sinica, 2019, 52(21):3830-3841. (in Chinese)
[11]	DODD J R, MALLARINO A P. Soil-test phosphorus and crop grain yield responses to long-term phosphorus fertilization for corn-soybean rotations. Soil Science Society of America Journal, 2005, 69(4):1118-1128. doi: 10.2136/sssaj2004.0279
[12]	TANG X, SHI X, MA Y, HAO X. Phosphorus efficiency in a long-term wheat-rice cropping system in China. Journal of Agricultural Science, 2011, 149(3):297-304.
[13]	刘方, 黄昌勇, 何腾兵, 钱小刚, 刘元生, 罗海波. 长期施肥下黄壤旱地磷对水环境的影响及其风险评价. 土壤学报, 2003, 40(6):838-844.
	LIU F, HUANG C Y, HE T B, QIAN X G, LIU Y S, LUO H B. The environmental impact of phosphorus on water in the upland fields of yellow soil areas under long-term fertilization and its risks evaluation. Acta Pedologica Sinica, 2003, 40(6):838-844. (in Chinese)
[14]	DJODJIC F, BÖRLING K, BERGSTRÖM L. Phosphorus leaching in relation to soil type and soil phosphorus content. Journal of Environmental Quality, 2004, 33(2):678-684. doi: 10.2134/jeq2004.6780
[15]	曹宁, 陈新平, 张福锁, 曲东. 从土壤肥力变化预测中国未来磷肥需求. 土壤学报, 2007, 44(3):536-543.
	CAO N, CHEN X P, ZHANG F S, QU D. Prediction of phosphate fertilizer demand in China based on change in soil phosphate fertility. Acta Pedologica Sinica, 2007, 44(3):536-543. (in Chinese)
[16]	鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2000.
	BAO S D. Soil Agrochemical Analysis. Beijing: China Agriculture Press, 2000. (in Chinese)
[17]	鲁如坤. 土壤农业化学分析方法. 北京: 中国农业科技出版社, 2000.
	LU R K. Soil Agrochemical Analysis Method. Beijing: China Agricultural Science and Technology Press, 2000. (in Chinese)
[18]	刘京. 长期施肥下紫色土磷素累积特征及其环境风险[D]. 重庆: 西南大学, 2015.
	LIU J. Characteristics of phosphorus accumulation in purple soil under long-term fertilization and its environmental risks[D]. Chongqing: Southwest University, 2015. (in Chinese)
[19]	吴春艳, 刘晓霞, 陈义, 李艳, 唐旭, 陆若辉. 不同施肥管理下水旱轮作水稻土磷含量的演变. 浙江农业学报, 2019, 31(7):1128-1137.
	WU C Y, LIU X X, CHEN Y, LI Y, TANG X, LU R H. Variation of phosphorus content in paddy soil under different fertilization management. Acta Agriculturae Zhejiangensis, 2019, 31(7):1128-1137. (in Chinese)
[20]	魏猛, 张爱君, 李洪民, 唐忠厚, 陈晓光, 诸葛玉平. 长期施肥条件下黄潮土有效磷对磷盈亏的响应. 华北农学报, 2015, 30(6):226-232.
	WEI M, ZHANG A J, LI H M, TANG Z H, CHEN X G, ZHUGE Y P. The response of available phosphorus in yellow fluvo-aquic soil to phosphorus surplus and loss under long-term fertilization conditions. Acta Agriculturae Boreali-Sinica, 2015, 30(6):226-232. (in Chinese)
[21]	袁天佑, 王俊忠, 冀建华, 牛俊义, 慕兰. 长期施肥条件下潮土Olsen-P的演变及其对磷盈亏的响应. 核农学报, 2017, 31(1):125-134.
	YUAN T Y, WANG J Z, JI J H, NIU J Y, MU L. Changes in soil available phosphorus and its response to phosphorus balance under long-term fertilization in fluvo-aquic soil. Journal of Nuclear Agricultural Sciences, 2017, 31(1):125-134. (in Chinese)
[22]	TANG X, LI J M, MA Y B, HAO X Y, LI X Y. Phosphorus efficiency in long-term (15 years) wheat-maize cropping systems with various soil and climate conditions. Field Crops Research, 2008, 108(3):231-237. doi: 10.1016/j.fcr.2008.05.007
[23]	YANG X Y, SUN B H, ZHANG S L. Trends of yield and soil fertility in a long-term wheat-maize system. Journal of Integrative Agriculture, 2014, 13(2):402-414. doi: 10.1016/S2095-3119(13)60425-6
[24]	SHEN P, XU M G, ZHANG H M, YANG X Y, HUANG S M, ZHANG S X, HE X H. Long-term response of soil Olsen P and organic C to the depletion or addition of chemical and organic fertilizers. Catena, 2014, 118:20-27. doi: 10.1016/j.catena.2014.01.020
[25]	李忠芳, 徐明岗, 张会民, 张文菊, 高静. 长期施肥下中国主要粮食作物产量的变化. 中国农业科学, 2009, 42(7):2407-2414.
	LI Z F, XU M G, ZHANG H M, ZHANG W J, GAO J. Changes in yields of major grain crops in China under long-term fertilization. Scientia Agricultura Sinica, 2009, 42(7):2407-2414. (in Chinese)
[26]	黄琦. 基于“3414”田间试验的吉林省水稻施肥效果分析[D]. 吉林: 吉林农业大学, 2016.
	HUANG Q. Fertilization effect analysis of Rice in Jilin Province based on field experiment of “3414”[D]. Jilin: Jilin Agricultural University, 2016. (in Chinese)
[27]	车升国, 袁亮, 李燕婷, 林治安, 李燕青, 赵秉强, 沈兵. 我国主要麦区小麦产量形成对磷素的需求. 植物营养与肥料学报, 2016, 22(4):869-876.
	CHE S G, YUAN L, LI Y T, LIN Z A, LI Y Q, ZHAO B Q, SHEN B. Phosphorous requirement for yield formation of wheat in main wheat production regions of China. Journal of Plant Nutrition and Fertilizers, 2016, 22(4):869-876. (in Chinese)
[28]	ZHANG B B. LIU W Z, CHANG S X, ANYIO A O. Phosphorus fertilization and fungal inoculations affected the physiology, phosphorus uptake and growth of spring wheat under rainfed conditions on the Canadian prairies. Journal of Agronomy & Crop Science, 2013, 199(2):85-93.
[29]	赵双进, 李晋生. 施肥对冬小麦夏谷氮磷吸收量的影响. 土壤肥料, 1992(3):27-29.
	ZHAO S J, LI J S. Effect of fertilization on nitrogen and phosphorus uptake in winter wheat and summer valley. Soil and Fertilizer Sciences in China, 1992(3):27-29. (in Chinese)
[30]	WANG X R, SHEN J B, LIAO H. Acquisition or utilization, which is more critical for enhancing phosphorus efficiency in modern crops. Plant Science, 2010, 179(4):302-306. doi: 10.1016/j.plantsci.2010.06.007
[31]	孙明, 孙翠平, 李彦, 仲子文, 井永苹, 罗加法, 薄录吉, 张英鹏. 长期定位施肥对山东潮土磷肥回收率演变及不同作物磷素吸收的影响. 农业科学, 2017, 7(6):433-442.
	SUN M, SUN C P, LI Y, ZHONG Z W, JING Y P, LUO J F, BO L J, ZHANG Y P. Effects of long-term fertilization on phosphorus recovery and phosphorus uptake by different crops in fluvo-aquic soil of Shandong Province. Agricultural Sciences, 2017, 7(6):433-442. (in Chinese)
[32]	高静, 张淑香, 徐明岗, 黄绍敏, 杨学云. 长期施肥下三类典型农田土壤小麦磷肥利用效率的差异. 应用生态学报, 2009, 20(9):2142-2148.
	GAO J, ZHANG S X, XU M G, HUANG S M, YANG X Y. Difference of phosphorus use efficiency of wheat in three typical farmland soils under long-term fertilization. Chinese Journal of Applied Ecology, 2009, 20(9):2142-2148. (in Chinese)
[33]	孙翠平, 张英鹏, 罗加法, 仲子文, 孙明, 李彦, 刘兆辉, 井永苹, 薄录吉. 长期施肥对山东潮土磷盈亏及农学阈值的影响. 华北农学报, 2019, 34(5):185-191.
	SUN C P, ZHANG Y P, LUO J F, ZHONG Z W, SUN M, LI Y, LIU Z H, JING Y P, BO L J. The effect of long-term fertilization on the phosphorus gain and loss and agronomic threshold of the fluvo-aquic soil in Shandong. Acta Agriculturae Boreali-Sinica, 2019, 34(5):185-191. (in Chinese)
[34]	黄晶. 基于几个长期定位试验的长江上、中游水稻土磷素肥力与磷肥肥效的演变规律[D]. 长沙: 湖南农业大学, 2017.
	HUANG J. Evolution of soil phosphorus fertility and phosphate fertilizer efficiency of paddy soils in the upper and middle reaches of the Yangtze River based on several stationary experiments[D]. Changsha: Hunan Agricultural University, 2017. (in Chinese)
[35]	KHAN A, LU G Y, AYAZ M, ZHANG H T, WANG R J, LV F L, YANG X Y, SUN B H, ZHANG S L. Phosphorus efficiency, soil phosphorus dynamics and critical phosphorus level under long-term fertilization for single and double cropping systems. Agriculture Ecosystems & Environment, 2018, 256:1-11. doi: 10.1016/j.agee.2018.01.006

处理 Treatment	产量 Yield (kg·hm^-2)		100 kg籽粒需磷量 P uptake per 100 kg grains yield (kg)
处理 Treatment	水稻Rice	小麦Wheat	水稻Rice	小麦Wheat
CK	6115.8±1271.1e	3099.9±790.9c	0.26±0.03b	0.33±0.06b
N	9458.1±1804.4c	3727.0±1382.8c	0.17±0.07c	0.25±0.02c
NP	11060.0±1886.9b	5667.5±1378.2b	0.38±0.04a	0.46±0.05a
NK	11151.5±1916.0b	3687.4±1632.2c	0.27±0.04b	0.25±0.05b
PK	7939.6±1120.4d	3698.0±1061.4c	0.38±0.03a	0.57±0.02a
NPK	12444.9±1793.3a	7015.6±1265.8a	0.36±0.03a	0.48±0.03a
NPKM	12441.7±2033.1a	6958.7±1369.1a	0.37±0.03a	0.50±0.06a
1.5NPKM	12760.5±1937.4a	7624.9±1590.5a	0.41±0.04a	0.52±0.03a
NPKS	13148.4±1910.1a	6883.9±1619.9a	0.39±0.02a	0.48±0.03a
M	8174.1±2174.2d	3161.9±913.2c	0.32±0.03b	0.39±0.05b

处理 Treatment	水稻季 Rice	小麦季 Wheat	全年 Annual
CK	—	—	—
N	—	—	—
NP	24.4±7.5b	12.3±2.4b	36.7±6.9b
NK	—	—	—
PK	14.2±2.0c	7.4±2.0c	21.5±2.7c
NPK	27.0±7.4a	17.4±3.1a	44.4±7.2a
NPKM	27.7±4.9a	17.1±2.7a	44.8±5.4a
1.5NPKM	31.1±7.4a	19.9±2.7a	50.9±7.3a
NPKS	32.9±6.5a	16.8±2.7a	49.6±5.2a
M	—	—	—

模型 Model	小麦 Wheat			水稻 Rice
模型 Model	农学阈值 Agronomy threshold (mg·kg^-1)	相对产量 Relative yield (%)	R²	农学阈值 Agronomy threshold (mg·kg^-1)	相对产量 Relative yield (%)	R²
线性-平台模型 LP	10.10	88.3	0.643**	14.34	92.4	0.427**
双直线模型 LL	9.93	87.5	0.654**	13.28	92.9	0.548**
BoxLucas模型 BL	9.17	79.5	0.595**	3.96	80.0	0.229**
米切里西模型 EXP	12.50	80.8	0.621**	10.01	84.0	0.414**
均值 Mean	10.44	84.1	—	10.73	87.4	—