Scientia Agricultura Sinica ›› 2016, Vol. 49 ›› Issue (21): 4160-4168.doi: 10.3864/j.issn.0578-1752.2016.21.010

• SOIL & FERTILIZER·WATER-SAVING IRRIGATION·AGROECOLOGY & ENVIRONMENT • Previous Articles     Next Articles

Contributions of Wheat and Corn Residues to Soil Organic Carbon Under Fluvo-Aquic Soil Area—Based on the Modified RothC Model

ZHAO Ya-wen1, WANG Jin-zhou1, WANG Shi-chao1, WU Hong-liang1, HUANG Shao-min2, LU Chang-ai1   

  1. 1Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences/National Engineering Laboratory for Improving Quality of Arable Land, Beijing 100081
    2Henan Soil and Fertilizer Station, Zhengzhou 450002
  • Received:2016-05-06 Online:2016-11-01 Published:2016-11-01

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Abstract: 【Objective】 In order to explore the effect of straw retention on SOC(soil organic carbon)content, the contributions of wheat and corn residues (root and straw) to SOC under fluvo-aquic soil area were studied, which have a great significance to take technical measures to promote SOC content of winter wheat-summer corn rotation system.【Method】The optimized DPM/RPM values (the ratio of decomposable plant material to resistant plant material) of different residues in Roth C-26.3 model was adjusted on the basis of the remaining rates of different organic materials after their decomposition. The modified model was validated with the data obtained from the short-time decomposition experiment (2012.11-2013.11) and the long-term trial conducted in Zhengzhou (1990-2008). Based on the optimized DPM/RPM parameters of Roth C-26.3 model, the contributions of wheat and corn residues to SOC in winter wheat-summer corn rotation system in northern China under three different fertilizer treatments (no fertilizer CK, chemical fertilizer NPK, chemical fertilizer combined with straw NPKS) were simulated. 【Result】DPM/RPM values of wheat root (WR), wheat straw(WS), corn root (CR), corn straw (CS) were 0.89, 3.04, 4.35 and 3.25, respectively, when the model was in optimal condition. It showed that in CK treatment, the carbon input derived from wheat root and corn root were 50%, respectively, while the contributions of wheat root and corn root to newly-formed soil organic (0-20 cm) were 60% and 40%, the retention coefficients of wheat root and corn root were 15.5% and 10.8%, respectively; in NPK treatment the carbon input derived from wheat root and corn root were 60% and 40%, respectively, while the contributions of wheat root and corn root to newly-formed soil organic (0-20 cm) were 71% and 29%, the retention coefficients of wheat root and corn root were 17.5% and 11.4%, respectively; in NPKS treatment the carbon input derived from wheat root and corn root were 47%, 21% and 32%, respectively, while the contributions of wheat root and corn root to newly-formed soil organic (0-20 cm) were 50%, 22% and 28%, the retention coefficients of wheat root and corn root were 16.9%, 11.2% and 11.4%, respectively. In a word, the contribution of wheat residue (50% -71%) to newly-formed SOC was greater than corn residue (22%-40%) in winter wheat-summer corn rotation system in north China whether no fertilization, balanced fertilization or straw returned. The ratio of SOC derived from wheat to newly-formed SOC was greater than the proportion of the carbon input from wheat to total carbon input, instead of the carbon input of corn and its contribution to newly-formed SOC. The carbon efficiency of wheat root (15.5% -17.5%) was more than the carbon efficiency of corn root and corn straw (10.8% -11.4%).【Conclusion】The modified RothC model can be used to explore the contributions of wheat and corn residues to newly-formed SOC in fluvo-aquic soil area. The contribution of wheat root to SOC was greater than corn root in winter wheat-summer corn rotation system in the North China and the retention coefficient of corn root was greater than the corn straw in NPKS treatment, so the application of root residues (especially wheat roots) could promote the soil organic carbon stock.

Key words: RothC model, wheat residue, corn residue, soil organic carbon, fluvo-aquic

[1]    Stockmann U, Adams M A, Crawford J W, Fielda D J, Henakaarchchi N, Jenkins M, Minasnya B. The knowns, known unknowns and unknowns of sequestration of soil organic carbon. Agriculture, Ecosystems & Environment, 2013, 164(4): 80-99.
[2]    Lal R. Soil carbon sequestration impacts on global climate change and food security. Science, 2004, 304(5677): 1623-1627.
[3]    Pan G, Xu X, Smith P, Pan W, Lal R. An increase in topsoil soc stock of china's croplands between 1985 and 2006 revealed by soil monitoring. Agriculture, Ecosystems and Environment, 2010, 136(1/2): 133-138.
[4]    Jiang G Y, Xu M G, He X H, Zhang W J, Huang S M, Yang X Y, Liu H, Peng C, Shirato Y, Toshichika L, Wang J Z, Murphy D V. Soil organic carbon sequestration in upland soils of northern china under variable fertilizer management and climate change scenarios. Global Biogeochemical Cycles, 2014, 28(3), 319-333.
[5]    Peltre C, Christensen B T, Dragon S, Icard C, Kätterer T, Houot S. RothC simulation of carbon accumulation in soil after repeated application of widely different organic amendments. Soil Biology and Biochemistry, 2012, 52(2014): 49-60.
[6]    Smith P, Smith J U, Powlson D S, Mcgill W B, Arah J R M, Chertov O G, Coleman K, Franko U, Frolking S, Jenkinson D C, Jensen L S, Kelly R H, Klein- Gunnewiek H, Komarov A S, Li C, Molina J A E, Mueller T, Parton W J, Thornley J H M, Whitmore A P. A comparison of the performance of nine soil organic matter models using datasets from seven long-term experiments. Geoderma, 1997, 81(1/2): 153-225.
[7]    Heitkamp F, Wendland M, Offenberger K, Gerold G. Implications of input estimation, residue quality and carbon saturation on the predictive power of the rothamsted carbon model. Geoderma, 2012, 170: 168-175.
[8]    Ludwig B, Helfrich M, Flessa H. Modelling the long-term stabilization of carbon from maize in a silty soil. Plant and Soil, 2005, 278(1): 315-325.
[9]    Shirato Y, Paisancharoen K, Sangtong P, Nakviro C, Yokozawa M, Matsumoto N. Testing the rothamsted carbon model against data from long-term experiments on upland soils in thailand. European Journal of Soil Science, 2005, 56(2): 179-188.
[10]   Wang J, Lu C, Xu M, Huang S, Zhang W. Soil organic carbon sequestration under different fertilizer regimes in North and Northeast China: Rothc simulation. Soil Use and Management, 2013, 29(2): 182-190.
[11]   Liu D L, Chan K Y, Conyers M K. Simulation of soil organic carbon under different tillage and stubble management practices using the rothamsted carbon model. Soil & Tillage Research, 2009, 104(1): 65-73.
[12]   Jiang G Y, Shirato Y, Xu M G, Yagasaki Y, Huang Q H, Li Z Z. Testing the modified rothamsted carbon model for paddy soils against the results from long-term experiments in southern China. Soil Science and Plant Nutrition, 2013, 59(59): 16-26.
[13]   韩其晟, 任宏刚, 刘建军. 秦岭主要森林凋落物中易分解和难分解植物残体含量及比值研究. 西北林学院学报, 2012, 27(5): 6-10.
Han Q S, Ren H G, Liu J J. Contents and ratios of the decomposable and resistant plant material in the litters of the main trees in Qinling Mountains. Journal of Northwest Forestry University, 2012, 27(5): 6-10. ( in Chinese)
[14]   Ayanaba A, Jenkinson D S. Decomposition of carbon-14 labeled ryegrass and maize under tropical conditions. Soil Science Society of America Journal, 1990, 41(5): 112-115.
[15]   王文山, 王维敏, 张镜清, 蔡典雄, 张美珠. 农作物残体在北京农田土壤中的分解. 土壤通报, 1989, 20(3): 113-115.
Wang W S, Wang W M, Zhang J Q, Cai D X, Zhang M Z. Decomposition of crop residue in farmland soil of Beijing, Chinese Journal of Soil Science, 1989, 20(3): 113-115. ( in Chinese)
[16]   COLEMAN K, JENKINSON D S. RothC-26. 3: A Model for the Turnover of Carbon in Soil Model Description and Windows Users Guide. Harpenden: Lawes Agricultural Trust, 1999.
[17]   Ludwig B, Hu K, Niu L, Liu X. Modelling the dynamics of organic carbon in fertilization and tillage experiments in the North China Plain using the Rothamsted carbon model-initialization and calculation of c inputs. Plant and Soil, 2007, 10(332): 193-206.
[18]   刘朝阳. 我国典型区域有机物料的腐解特征[D]. 贵阳: 贵州大学, 2012.
Liu C Y. The decomposition characteristics of organic materials in typical regional of china [D]. Guiyang: Guizhou University, 2012. (in Chinese)
[19]   Silver W, Miya R. Global patterns in root decomposition: Comparisons of climate and litter quality effects. Oecologia, 2001, 129(3): 407-419.
[20]   Zhang D, Hui D, Luo Y, Zhou G. Rates of litter decomposition in terrestrial ecosystems: Global patterns and controlling factors. Journal of Plant Ecology, 2008, 1(2): 85-93.
[21]   王金洲, 卢昌艾, 张文菊, 冯固, 王秀君, 徐明岗. 中国农田土壤中有机物料腐解特征的整合分析. 土壤学报, 2016, 53(1): 16-27.
Wang J Z, Lu C A, Zhang W J, Feng G, Wang X J, Xu M G. Decomposition of organic materials in cropland soils across China: A meta-analysis. Acta Pedologica Sinica, 2016, 53(1): 16-27. (in Chinese)
[22]   Huang Y, Yu Y, Zhang W, Sun W, Liu S, Jiang J. Agro-c:   A biogeophysical model for simulating the carbon budget of agroecosystems. Agricultural and Forest Meteorology, 2009, 149(1): 106-129.
[23]   Parton W J, Schimel D S, Cole C V, Ojima D S. Analysis of factors controlling soil organic matter levels in great plains grasslands. Soil Science Society of America Journal., 1987, 51(5): 1173-1179
[24]   Wang J, Wang X, Xu M, Feng G, Zhang W, Yang X, Huang S. Contributions of wheat and maize residues to soil organic carbon under long-term rotation in North China. Scientific Reports, 2015, 5: 1-12.
[25]   Qiao Y, Miao S, Li N, Xu Y, Han X, Zhang B. Crop species affect soil organic carbon turnover in soil profile and among aggregate sizes in a mollisol as estimated from natural 13 abundance. Plant and Soil, 2015, 392(1/2): 163-174.C
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