[1]陈磊,王金洲,郝小雨,等.DayCent模型模拟黑土长期施肥下土壤碳氮变化[J].黑龙江农业科学,2021,(10):23-31.[doi:DOI:10.11942/j.issn1002-2767.2021.10.0023]
 CHEN Lei,WANG Jin-zhou,HAO Xiao-yu,et al.Using DayCent Model to Simulate Black Soil Organic Carbon and Total Nitrogen Dynamics Under LongTerm Different Fertilization[J].HEILONGJIANG AGRICULTURAL SCIENCES,2021,(10):23-31.[doi:DOI:10.11942/j.issn1002-2767.2021.10.0023]
点击复制

DayCent模型模拟黑土长期施肥下土壤碳氮变化

《黑龙江农业科学》[ISSN:1002-2767/CN:23-1204/S] 卷: 期数: 2021年10 页码: 23-31 栏目: 出版日期: 2021-10-10
Title:
Using DayCent Model to Simulate Black Soil Organic Carbon and Total Nitrogen Dynamics Under LongTerm Different Fertilization
作者:
陈磊12王金洲3郝小雨1马星竹1魏 丹4周 磊5刘荣乐6汪 洪2
1.黑龙江省农业科学院 土壤肥料与环境资源研究所,黑龙江 哈尔滨 150086;2.中国农业科学院 农业资源与农业区划研究所/耕地培育技术国家工程实验室/农业部植物营养与肥料重点实验室,北京 100081;3.北京大学,北京 100871;4.北京农林科学院 植物营养与资源研究所,北京 100097;5.黑龙江省科学院,黑龙江 哈尔滨 150001;6.农业农村部环境保护科研监测所,天津 300191
Author(s):
CHEN Lei12WANG Jin-zhou3HAO Xiao-yu1MA Xing-zhu1WEI Dan4ZHOU Lei5LIU Rong-le6WANG Hong2
1.Institute of Soil and Fertilizer and Environment Resources,Heilongjiang Academy of Agricultural Sciences,Harbin 150086,China;2.Institute of Agricultural Resources and Regional Planning,Chinese Academy of Agricultural Sciences / National Engineering Laboratory for Improving Quality of Arable Land / Key Laboratory of Plant Nutrition and Fertilizer,Ministry of Agriculture,Beijing 100081,China;
关键词:
DayCent模型黑土长期定位施肥土壤碳氮变化
Keywords:
DayCent model long-term fertilization in black soilsoil organic carbon and total nitrogen dynamics
DOI:
DOI:10.11942/j.issn1002-2767.2021.10.0023
文献标志码:
A
摘要:
为促进黑土耕地可持续发展,本研究利用黑龙江省38年长期定位施肥试验的作物产量、土壤有机碳含量和全氮含量等数据,对DayCent模型进行校验和验证,同时,利用试验数据逆向模拟的方法,获取模型最佳的修正系数,分析导致模型模拟偏差的原因,揭示黑土区施肥制度对土壤碳氮动态变化的影响以及土壤碳氮转化的规律。结果表明:DayCent模型验证土壤有机碳时不施肥(CK)、氮肥(N)、二倍量氮肥(N2)、氮磷钾配施(NPK)、有机肥(M)、有机肥+氮肥配施(MN)和有机肥+氮磷钾配施(MNPK)处理的均方根差为7.2%~9.8%,验证全氮时的均方根差为7.1%~10.2%,且模拟评价的相对误差和模拟效率均在很好和较好范围内,说明模型参数组合对以有机肥归还为主的施肥条件下有机碳、全氮动态模拟较好;而验证二倍量有机肥(M2和M2N2)处理的土壤有机碳、全氮的均方根差分别为13.2%、12.5%和10.6%、10.4%,模型模拟的效果较好,DayCent模型能够基本反映土壤有机碳和全氮的变化。利用38年长期定位试验实测数据逆向分析可知,该试验点有机肥投入下的有机碳周转速率是单施化肥的1.7倍。利用DayCent模型模拟东北黑土区大量有机肥投入时的土壤碳动态变化时,需综合考虑土壤碳氮平衡、激发效应及淋洗迁移等问题,可能会在不同程度上高估高量有机肥投入下土壤有机碳动态。
Abstract:
In order to promote the sustainable development of cultivated land in black soil,the data of crop yield,soil organic carbon and total nitrogen were collected from the 38 years long-term fertilizer experiments in Heilongjiang Province.The effects of long-term fertilization on black soil organic carbon and total nitrogen content were verified and stimulated using the DayCent model,at the same time,the model optimization of correction factor was obtained by using the method of reverse simulation of test data,which analyzed the possible reasons for the deviation of the model simulation to reveal the influence of fertilization system on the dynamic change of soil carbon and nitrogen and the law of soil carbon and nitrogen transformation.The results showed that the root mean square error of SOC in CK,N,N2,NPK,M,MN and MNPK treatments were in range of 7.2%-9.8%,those of TN were in range of 7.1%-10.2%,which suggested that the simulated values were consistent with the observed values;but the root mean square error of SOC and TN in M2 and M2N2 treatment were in range of 13.2%,12.5% and 10.6%,10.4%,the evaluation parameters of the model simulation were in a good range,the DayCent model could basically reflect the changes of SOC and TN.The inverse modelling showed that SOC turnover rate of these (M,MN and MNPK) treatments was 1.7 times that of these(N,N2 and NPK)treatments.When applying a large amount of organic fertilizer in northeast China,soil nutrient balance,priming effects,the leaching and transferring issues of SOC should be considered in the DayCent model,which may overestimate SOC content to a certain extent.

参考文献/References:

参考文献:

[1]PCC.Carbon and other biogeochemical cycles[R].STOCKER T F,QIN D,PLATTNER G K,et al.Climate change 2013:The physical science basis.Contribution of working group I to the fifth assessment report of the intergovernmental panel on climate change,Cambridge University Press,Cambridge,United Kingdom and New York,NY,USA,2013:467-544.
[2]LAL R.Sequestering carbon in soils of agroecosystems[J].Food Policy,2011,36:S33-S39.
[3]STOCKMANN U,ADAMS M A,CRAWFORD J W,et al.The knowns,known unknowns and unknowns of sequestration of soil organic carbon[J].Agriculture Ecosystems & Environment,2013,164:80-99.
[4]SMITH P,MARTINO D,CAI Z,et al.Policy and technological constraints to implementation of greenhouse gas mitigation options in agriculture[J].Agriculture Ecosystems & Environment,2007,118:6-28.
[5]CORSI S T,FRIEDRICH A,KASSAM M,et al.Soil organic carbon accumulation and greenhouse gas emission reductions from conservation agriculture:A literature review[R].Rome:FAO,2012.
[6]MEURER K H E,FRANKO U,STANGE C F,et al.Direct nitrous oxide (N2O) fluxes from soils under different land use in Brazil:A critical review[J].Environmental Research Letters,2016,11:023001.
[7]POWLSON D S,STIRLING C M,JAT M L,et al.Limited potential of notill agriculture for climate change mitigation[J].Nature Climate Change,2014,4:678-683.
[8]MAILLARD ,ANGERS D A.Animal manure application and soil organic carbon stocks:A metaanalysis[J].Global Change Biology,2014,20:666-679.
[9]康日峰,任意,吴会军,等.26年来东北黑土区土壤养分演变特征[J].中国农业科学,2016,49(11):2113-2125.
[10]汪景宽,王铁宇,张旭东,等.黑土土壤质量演变初探不同开垦年限黑土主要质量指标演变规律[J].沈阳农业大学学报,2002,33(1):43-47.
[11]郭胜利,党廷辉,郝明德.施肥对半干旱区小麦产量、NO3N累积和水分平衡的影响[J].中国农业科学,2005,38(4):754-760.
[12]STEWART C E,PAUSTIAN K,CONANT R T,et al.Soil carbon saturation:Implications for measurable carbon pool dynamics in longterm incubations[J].Soil Biology and Biochemistry,2009,41(2):357-366.
[13]JENKINSON D S,RAYNER J H.The turnover of soil organ is matter in some of the Rothamsted classical experiments[J].Soil Science,1977,123:298-305.
[14]LI C S,FROLKING S,FROLKING T A.A model of nitrous oxide evolution from soil driven by rainfall events:Model structure and sensitivity[J].Journal of Geophysical Research,1992,97(D9):9759-9776.
[15]PARTON W J,SCHIME D S,COLE C V,et al.Analysis of factors controlling soil organic matter levels in Great Plains grasslands[J].Soil Science Society of America Journal,1987,51:1173-1179.
[16]HARSEN S,JENSEN H E,NIELSEN N E,et al.Simulation of nitrogen dynamic sand biomass production in winter wheat using the Danish simulation model DAISY[J].Nutrient Cycling in Agroecosystems,1991,27:245-259.
[17]MCCOWN R L,HAMMER G L,HARGREAVES J N G,et al.APSIM:A novel software system for model development model testing and simulation in agricultural systems research[J].Agricultural Systems,1996,50:255-271.
[18]MOLINA J A E,CLAPP C E,SHAFER M J,et al.NCSOIL,a model of nitrogen and carbon transformations in soil:Description,calibration and behavior[J].Soil Science Society of America Journal,1983,47:85-91.
[19]龙军,毛艳玲,张黎明,等.农田土壤有机碳演变模型的研究进展[J].中国农学通报,2012,28(5):232-239.
[20]SMITH P,SMITH J U,POWLSON D S,et al.A comparison of the performance of nine soil organic matter models using datasets from seven longterm experiments[J].Geoderma,1997,81(12):153-225.
[21]CHENG K,OGLE S M,PARTON W J,et al.Predicting methanogenesis from rice paddies using the DayCent ecosystem model[J].Ecological Modelling,2013,261-262:19-31.
[22]MIKHAILOVA E A,BRYANT R B,DEGLORIA S D,et al.Modelling soil organic matter dynamics after conversion of native grassland to longterm continuous fallow using the Century model[J].Ecological Modelling,2000,132(3):247-257.
[23]ALVARO-FUENTES J,LPEZ M V,ARRUE J L,et al.Tillage and cropping effects on soil organic carbon in Mediterranean semiarid groecosystems testing the CENTURY model[J].Agriculture,Ecosystems and Environment,2009,134(3-4):211-217.
[24]BORTOLON E S O,MIELNICZUK J,TORNQUIST C G,et al.Validation of the CENTURY model to estimate the impact of agriculture on soil organic carbon in southern Brazil[J].Geoderma,2011,167:156-166.
[25]高鲁鹏,梁文举,姜勇,等.利用Century模型研究东北黑土有机碳的动态变化I.自然状态下上壤有机碳的积累[J].应用生态学报,2004,15(5):772-776.
[26]高崇升,杨国亭,张兴义,等.利用Century模型模拟不同农业经营模式下黑土农田土壤有机碳的演变[J].生态学杂志,2008,27(6):911-915.
[27]邓祥征,姜群鸥,林英志,等.中国农田土壤有机碳贮量变化预测[J].地理研究,2010(1):93-101.
[28]李悦,郭李萍,谢立勇,等.不同农作管理措施对东北地区农田土壤有机碳未来变化的模拟研究[J].中国农业科学,2015,48(3):501-513.
[29]CONG R H,WANG X J,XU M G,et al.Evaluation of the CENTURY model using longterm fertilization trials under cornwheat cropping systems in the typical croplands of China[J].P1oS One,2014,9(4):e95142.
[30]PARTON W J,HARTMAN M,OJIMA D,et al.DayCent and its land surface submodel:Description and testing[J].Global and Planetary Change,1998,19(1-4):35-48.[31]DEL GROSSO S J,MOSIER A R,PARTON W J,et al.DayCent model analysis of past and contemporary soil N2O and net greenhouse gas flux for major crops in the USA[J].Soil Tillage Research,2005,83:9-24.
[32]STEHFEST E,HEISTERMANN M,PRIESS J A,et al.Simulation of global crop production with the ecosystem model DayCent[J].Ecological Modelling,2009,209:203-219.
[33]DE GRYZE S,WOLF A,KAFFLCA S R,et al.Simulating greenhouse gas budgets of four California cropping systems under conventional and alternative management[J].Ecological Applications,2010,20:1805-1819.
[34]PARTON W J,STEWART J W B,COLE C V.Dynamics of C,N,P and S in grassland soils:A model[J].Biogeochemistry,1988,5:109-131.
[35]王金洲.秸秆还田的土壤有机碳周转特征[D].北京:中国农业大学,2015.
[36]张璇,谢立勇,郭李萍,等.DayCent模型模拟不同农作管理措施下华北地区土壤有机碳的变化[J].应用生态学报,2016,27(2):539-548.
[37]张茂鑫.东北旱田不同农作情景下土壤有机碳变化及固碳潜力的模拟研究[D].沈阳:沈阳农业大学,2018.
[38]ZHANG W,WANG X,XU M,et al.Soil organic carbon dynamics under longterm fertilizations in arable land of northern China[J].Biogeosciences,2010,7(2):409-425.
[39]HEITKAMP F,WENDLAND M,OFFENBERGER K,et al.Implications of input estimation,residue quality and carbon saturation on the predictive power of the Rothamsted Carbon Model\[J\].Geoderma,2012,170:168-175.
[40]JIANG G,SHIRATO Y,XU M,et al.Testing the modified Rothamsted Carbon Model for paddy soils against the results from longterm experiments in southern China[J].Soil Science and Plant Nutrition,2013,59(1):16-26.
[41]KUZYAKOV Y,FRIEDEL J K,STAHR K.Review of mechanisms and quantification of priming effects[J].Soil Biology and Biochemistry,2000,32(11-12):1485-1498.[42]BLAGODATSKAYA E,KUZYAKOV Y.Mechanisms of real and apparent priming effects and their dependence on soil microbial biomass and community structure:Critical review[J].Biology and Fertility of Soils,2008,45(2):115-131.
[43]〗CHEN R R,SENBAYRAM M,BLAGODATSKY S,et al.Soil C and N availability determine the priming effect:Microbial N mining and stoichiometric decomposition theories[J].Global Change Biology,2014,20(7):2356-2367.
[44]BURNS R G,DEFOREST J L,MARXSEN J,et al.Soil enzymes in a changing environment:Current knowledge and future directions[J].Soil Biology and Biochemistry,2013,58:216-234.
[45]CHOWDHURY S,FARRELL M,BOLAN N.Priming of soil organic carbon by malic acid addition is differentially affected by nutrient availability[J].Soil Biology and Biochemistry,2014,77:158-169.
[46]TIAN Q X,YANG X L,WANG X G,et al.Microbial community mediated response of organic carbon mineralization to labile carbon and nitrogen addition in topsoil and subsoil[J].Biogeochemistry,2016,128(1-2):125-139.
[47]MC KNIGHT D,THRUMAN E M,WERSHAW R L.Biogeochemistry of aquatic humic substances in Thoreau’s Bog,Concord,Massachusetts[J].Ecology,1985,66(4):1339-1352.
[48]倪进治,徐建民,谢正苗.土壤水溶性有机碳的研究进展[J].生态环境,2003,12(1):71-75.
[49]骆坤.黑土碳氮及其组分对长期施肥的响应[D].武汉:华中农业大学,2012.
[50]李文军,彭保发,杨奇勇.长期施肥对洞庭湖双季稻区水稻土有机碳、氮积累及其活性的影响[J].中国农业科学,2015,48(3):488-500.
[51]ZHANG J J,DOU S,SONG X Y.Effect of longterm combined nitrogen and phosphorus fertilizer application on 13C CPMAS NMR spectra of humin in a typic hapludoll of northeast China[J].European Journal of Soil Science,2009,60:966-973.
[52]KINDLER R,SIEMENS J,KAISER K,et al.Dissolved carbon leaching from soil is a crucial component of the net ecosystem carbon balance[J].Global Change Biology,2011,17(2):1167-1185.
[53]周旺明,王金达,刘景双,等.冻融对湿地土壤可溶性碳、氮和氮矿化的影响田[J].生态与农村环境学报,2008,24(3):1-6.
[54]肖伟伟,范晓晖,杨林章,等.长期施肥对黄土旱塬黑垆土有机氮和有机碳的影响[J].农业环境科学学报,2007(2):672-675.
[55]乔云发,韩晓增,赵兰坡.长期定位施肥对黑土碳氮储量的影响[J].农业系统科学与综合研究,2011,27(4):480-484.
[56]LI S Q,LI S X.Priming effect of ammonium nitrogen fertilizer on soil nitrogen under waterlogged condition[J].Plant Nutrition and Fertilizer Science,2001,7(4):361-367.
[57]PAUL E A.Soil Microbiology,ecology and biochemistry[M].Amsterdam:Academic Press,2007.
[58]丛日环.小麦玉米轮作体系长期施肥下农田土壤碳氮相互作用关系研究[D].北京:中国农业科学院,2012.

备注/Memo

收稿日期:2021-04-08

基金项目:国家重点研发计划(2017YFC0504200);黑龙江省博士后面上资助项目(LBH-Z20093)。
第一作者:陈磊(1986-),男,博士,助理研究员,从事土壤有机碳及根际生物学研究。E-mail:chengz5251@163.com。?
通信作者:汪洪(1970-),男,博士,研究员,从事土壤植物中、微量营养元素研究。E-mail:wanghong01@caas.cn。

更新日期/Last Update: 2021-11-06