塔里木盆地北缘盐土有机碳含量的贝叶斯地统计预测

doi:10.13287/j.1001-9332.201702.023

应用生态学报 ›› 2017, Vol. 28 ›› Issue (2): 439-448.doi: 10.13287/j.1001-9332.201702.023

• 中国生态学学会2016年学术年会会议专栏 • 上一篇下一篇

塔里木盆地北缘盐土有机碳含量的贝叶斯地统计预测

伍维模^{1, 2}, 王家强², 曹琦², 吴嘉平^3*

¹浙江大学环境与资源学院, 杭州 310058;
²塔里木大学植物科学学院, 新疆阿拉尔 843300;
³浙江大学海岛海岸带研究所, 浙江舟山 316021

收稿日期:2016-07-06 出版日期:2017-02-18 发布日期:2017-02-18
通讯作者: * E-mail: jw67@zju.edu.cn
作者简介:伍维模, 男, 1971年生, 博士研究生, 副教授. 主要从事干旱区资源环境、生态遥感及空间分析研究. E-mail: 11114055@zju.edu.cn
基金资助:
本文由国家自然科学基金项目(40961028)资助

Bayesian geostatistical prediction of soil organic carbon contents of solonchak soils in nor-thern Tarim Basin, Xinjiang, China.

WU Wei-mo^{1, 2}, WANG Jia-qiang², CAO Qi², WU Jia-ping^3*

¹College of Environmental and Resources Sciences, Zhejiang University, Hangzhou 310058, China;
²College of Plant Science, Tarim University, Alar 843300, Xinjiang, China;
³Institute of Islands and Coastal Ecosystems, Zhejiang University, Zhoushan 316021, Zhejiang, China.

Received:2016-07-06 Online:2017-02-18 Published:2017-02-18
Contact: * E-mail: jw67@zju.edu.cn
Supported by:
This work was supported by the National Science Foundation of China (40961028).

摘要/Abstract

摘要： 准确预测土壤有机碳的空间分布,对于土壤资源开发和保护、应对气候变化和生态系统健康都具有重要意义.本文以塔里木盆地北缘盐土1300 m×1700 m样地为试验区,采集5～10 cm深度土壤样品144个,构建土壤有机碳含量的贝叶斯地统计空间预测模型,并以普通克里格、序惯高斯模拟和逆距离加权方法为对照,评价贝叶斯地统计对土壤有机碳含量的预测性能.结果表明: 研究区土壤有机碳含量处于1.59～9.30 g·kg^-1,平均值为4.36 g·kg^-1,标准偏差为1.62 g·kg^-1;半方差函数符合指数模型,空间结构比参数值为0.57;利用贝叶斯地统计方法,获得了土壤有机碳含量的空间分布图以及评价预测不确定性的预测方差、上95%分位数、下95%分位数分布图;与普通克里格、序惯高斯模拟和逆距离加权方法相比,贝叶斯地统计方法具有更高的土壤有机碳含量空间预测精度,显示出该方法对土壤有机碳含量预测的优越性.

Abstract: Accurate prediction of soil organic carbon (SOC) distribution is crucial for soil resources utilization and conservation, climate change adaptation, and ecosystem health. In this study, we selected a 1300 m×1700 m solonchak sampling area in northern Tarim Basin, Xinjiang, China, and collected a total of 144 soil samples (5-10 cm). The objectives of this study were to build a Baye-sian geostatistical model to predict SOC content, and to assess the performance of the Bayesian model for the prediction of SOC content by comparing with other three geostatistical approaches [ordinary kriging (OK), sequential Gaussian simulation (SGS), and inverse distance weighting (IDW)]. In the study area, soil organic carbon contents ranged from 1.59 to 9.30 g·kg^-1 with a mean of 4.36 g·kg^-1 and a standard deviation of 1.62 g·kg^-1. Sample semivariogram was best fitted by an exponential model with the ratio of nugget to sill being 0.57. By using the Bayesian geostatistical approach, we generated the SOC content map, and obtained the prediction variance, upper 95% and lower 95% of SOC contents, which were then used to evaluate the prediction uncertainty. Bayesian geostatistical approach performed better than that of the OK, SGS and IDW, demonstrating the advantages of Bayesian approach in SOC prediction.

伍维模, 王家强, 曹琦, 吴嘉平. 塔里木盆地北缘盐土有机碳含量的贝叶斯地统计预测[J]. 应用生态学报, 2017, 28(2): 439-448.

WU Wei-mo, WANG Jia-qiang, CAO Qi, WU Jia-ping. Bayesian geostatistical prediction of soil organic carbon contents of solonchak soils in nor-thern Tarim Basin, Xinjiang, China.[J]. Chinese Journal of Applied Ecology, 2017, 28(2): 439-448.

参考文献

[1] McBratney AB, Stockmann U, Angers DA, et al. Challenges for soil organic carbon research// Hartemink AE, McSweeney K, eds. Soil Carbon: Progress in Soil Science. Cham, the Switzerland: Springer International Publishing, 2014: 3-16
[2] Bationo A, Kihara J, Vanlauwe B, et al. Soil organic carbon dynamics, functions and management in West African agro-ecosystems. Agricultural Systems, 2007, 94: 13-25
[3] Marks E, Aflakpui GKS, Nkem J, et al. Conservation of soil organic carbon, biodiversity and the provision of other ecosystem services along climatic gradients in West Africa. Biogeosciences, 2009, 6: 1825-1838
[4] Stockmann U, Adams MA, Crawford JW, et al. The knowns, known unknowns and unknowns of sequestration of soil organic carbon. Agriculture, Ecosystems and Environment, 2013, 164: 80-89
[5] Minasny B, McBratney AB, Malone BP, et al. Digital mapping of soil carbon. Advances in Agronomy, 2013, 118: 1-47
[6] Hartemink AE, Gerzabek MH, Lal R, et al. Soil carbon research priorities// Hartemink AE, McSweeney K, eds. Soil Carbon: Progress in Soil Science. Cham, the Switzerland: Springer International Publishing, 2014: 483-490
[7] Hempel J, McBratney AB, Arrouays D, et al. Global soil map and global carbon predictions// Hartemink AE, McSweeney K, eds. Soil Carbon: Progress in Soil Science. Cham, the Switzerland: Springer International Publishing, 2014: 363-372
[8] Ungaro F, Staffilani F, Tarocco P. Assessing and mapping topsoil organic carbon stock at a regional scale: A scorpan kriging approach conditional on soil map delineations and land use. Land Degradation & Development, 2010, 21: 565-581
[9] Adhikari K, Hartemink AE, Minasny B, et al. Digital mapping of soil organic carbon contents and stocks in Denmark. PLoS One, 2014, 9(8): e105519
[10] Liu S-L (刘世梁), An N-N (安南南), Yang J-J (杨珏婕), et al. Effects of different land-use types on soil organic carbon and its prediction in the mountainous areas in the middle reaches of Lancang River. Chinese Journal of Applied Ecology (应用生态学报), 2015, 26(4): 981-988 (in Chinese)
[11] Brevik EC, Calzolari C, Miller BA, et al. Soil mapping, classification, and pedologic modeling: History and future directions. Geoderma, 2016, 264: 256-274
[12] Yang RL, Zhang GL, Liu F, et al. Comparison of boosted regression tree and random forest models for mapping topsoil organic carbon concentration in an alpine ecosystem. Ecological Indicators, 2016, 60: 870-878
[13] Taghizadeh-Mehrjardi R, Nabiollahi K, Kerry R. Digital mapping of soil organic carbon at multiple depths using different data mining techniques in Baneh region, Iran. Geoderma, 2016, 266: 98-110
[14] Wu CF, Wu JP, Luo YM, et al. Spatial prediction of soil organic matter content using coKriging with remotely sensed data. Soil Science Society of America Journal, 2009, 73: 1202-1208
[15] Zhi JJ, Jing CW, Lin SP, et al. Estimating soil organic carbon stocks and spatial patterns with statistical and GIS-based methods. PLoS One, 2014, 9(5): e97757
[16] Le ND, Zidek JV. Statistical Analysis of Environmental Space-Time Processes. New York: Springer, 2006
[17] Patil AP, Huard D, Fonnesbeck CJ. PyMC: Bayesian stochastic modelling in Python. Journal of Statistical Software, 2010, 35: 1-81
[18] Patil AP, Gething PW, Piel FB, et al. Bayesian geostatistics in health cartography: The perspective of malaria. Trends in Parasitology, 2011, 27: 245-252
[19] Clifford D, Pagendam D, Baldock J, et al. Rethinking soil carbon modelling: A stochastic approach to quantify uncertainties. Envionmetrics, 2014, 25: 265-278
[20] Wills S, Loecke T, Sequeirea C, et al. Overview of the U.S. rapid carbon assessment project: Sampling design, initial summary and uncertainty estimates// Hartemink AE, McSweeney K, eds. Soil Carbon: Progress in Soil Science. Cham, the Switzerland: Springer International Publishing, 2014: 95-104
[21] Xiong X, Grunwald S, Myers DB, et al. Assessing uncertainty in soil organic carbon modeling across a highlyheterogeneous landscape. Geoderma, 2015, 251/252: 105-116
[22] Gao Y-X (高以信), Li J (李锦). 1:4 M Map of China. Beijing: Science Press, 1998 (in Chinese)
[23] Xie X-L (解宪丽), Sun B (孙波), Zhou H-Z (周慧珍), et al. Organic carbon density and storage in soils of China and spatial analysis. Acta Pedologica Sinica (土壤学报), 2004, 41(1): 35-43 (in Chinese)
[24] Yan A (颜安). Spatial Distribution and Storage Estimation of Soil Organic Carbon and Soil Inorganic Carbon in Xinjiang, China. PhD Thesis. Beijing: China Agricultural University, 2015 (in Chinese)
[25] Gong L (贡璐), Zhu M-L (朱美玲), Liu Z-Y (刘曾媛), et al. Correlation among soil organic carbon, soil inorganic carbon and the environmental factors in a typical oasis in the southern edge of the Tarim Basin. Environmental Science (环境科学), 2016, 37(4): 1516-1522 (in Chinese)
[26] Huang Y, Sun WJ, Zhang W, et al. Changes in soil organic carbon of terrestrial ecosystems in China: A mini-review. Science China Life Science, 2010, 53: 766-775
[27] Deutsch CV, Journel AG. GSLIB Geostatistical Software Library and User’s Guide. 2nd Ed. New York: Oxford University Press, 1998
[28] Krivoruchko K. Spatial Statistical Data Analysis for GIS Users. New York: Esri Press, 2011
[29] Bao S-D (鲍士旦). Soil and Agricultural Chemistry Analysis. Beijing: China Agricultural Press, 2000 (in Chinese)
[30] R Core Team. R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, Austria [EB/OL]. [2015-01-20] (2016-01-01). http://www.R-project.org/
[31] Reimann C, Filzmoser P. Normal and lognormal data distribution in geochemistry: Death of a myth. Consequences for the statistical treatment of geochemical and environmental data. Environmental Geology, 2000, 39: 1001-1014
[32] Remy N, Boucher A, Wu J. Applied Geostatistics with SGeMS: A User’s Guide. Cambridge: Cambridge University Press, 2009
[33] Goovaerts P. Geostatistics for Natural Resources Evaluation. Oxford: Oxford University Press, 1997
[34] Cambardella CA, Moorman TB, Novak JM, et al. Field-scale variability of soil properties in central Iowa soils. Soil Science Society of America Journal, 1994, 58: 1501-1511
[35] Banerjee S, Carlin BP, Gelfand AE. Hierarchical Mo-deling and Analysis for Spatial Data. Boca Raton, FL: Chapman and Hall/CRC Press, 2004
[36] Cressie N, Wikel K. Statistics for Spatio-Temporal Data. New Jersey: John Wiley & Sons, Inc., 2011
[37] Li J, Heap AD. A review of comparative studies of spatial interpolation methods in environmental sciences: Performance and impact factors. Ecological Informatics, 2011, 6: 3-4
[38] Agricultural Bureau of Uygur Autonomous Region of Xinjiang (新疆维吾尔自治区农业厅), Soil Survey Office of Uygur Autonomous Region of Xinjiang (新疆维吾尔自治区土壤普查办公室). Soil in Xinjiang. Beijing: Science Press, 1996 (in Chinese)

塔里木盆地北缘盐土有机碳含量的贝叶斯地统计预测

Bayesian geostatistical prediction of soil organic carbon contents of solonchak soils in nor-thern Tarim Basin, Xinjiang, China.

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