The efficiency of long-term straw return to sequester organic carbon in Northeast China's cropland

doi:10.1016/S2095-3119(17)61739-8

摘要/Abstract

Abstract: Black soil is one of the most precious soil resources on earth because it has abundant carbon stocks and a relatively high production capacity. However, decreasing organic matter after land reclamation, and the effects of long-term inputs of organic carbon have made it less fertile black soil in Northeast China. Straw return could be an effective method for improving soil organic carbon (SOC) sequestration in black soils. The objective of this study was to evaluate whether straw return effectively increases SOC sequestration. Long-term field experiments were conducted at three sites in Northeast China with varying latitudes and SOC densities. Study plots were subjected to three treatments: no fertilization (CK); inorganic fertilization (NPK); and NPK plus straw return (NPKS). The results showed that the SOC stocks resulting from NPKS treatment were 4.0 and 5.7% higher than those from NPK treatment at two sites, but straw return did not significantly affect the SOC stocks at the third site. Furthermore, at higher SOC densities, the NPKS treatment resulted in significantly higher soil carbon sequestration rates (CSR) than the NPK treatment. The equilibrium value of the CSR for the NPKS treatment equated to cultivation times of 17, 11, and 8 years at the different sites. Straw return did not significantly increase the SOC stocks in regions with low SOC densities, but did enhance the C pool in regions with high SOC densities. These results show that there is strong regional variation in the effects of straw return on the SOC stocks in black soil in Northeast China. Additional cultivations and fertilization practices should be used when straw return is considered as an approach for the long-term improvement of the soil organic carbon pool.

Key words: soil organic carbon (SOC) , SOC stock , straw return , soil sequestration rate , straw-C sequestration efficiency , black soil , long-term experiments

. [J]. Journal of Integrative Agriculture, 2018, 17(2): 436-448.

WANG Shi-chao, ZHAO Ya-wen, WANG Jin-zhou, ZHU Ping, CUI Xian, HAN Xiao-zeng, XU Ming-gang, LU Chang-ai . The efficiency of long-term straw return to sequester organic carbon in Northeast China's cropland[J]. Journal of Integrative Agriculture, 2018, 17(2): 436-448.

参考文献

An T, Schaeffer S, Zhuang J, Radosevich M, Li S, Li H, Pei J, Wang J. 2015. Dynamics and distribution of 13C-labeled straw carbon by microorganisms as affected by soil fertility levels in the Black Soil region of Northeast China. Biology and Fertility of Soils, 51, 605–613.

Bastida F, Torres I F, Hernández T, Bombach P, Richnow H H, García C. 2013. Can the labile carbon contribute to carbon immobilization in semiarid soils? Priming effects and microbial community dynamics. Soil Biology and Biochemistry, 57, 892–902.

Bremner J M, Mulvaney C S. 1982. Nitrogen-total. In: Page L A, Milley R H, Keeney D R, eds., Methods of Soil Analysis. American Society of Agronomy, Madison. pp. 595–642.

Blagodatskaya Е, Kuzyakov Y. 2008. Mechanisms of real and apparent priming effects and their dependence on soil microbial biomass and community structure: Critical review. Biology and Fertility of Soils, 45, 115–131.

Cai M, Dong Y J, Chen Z J, Kalbitz K, Zhou J B. 2015. Effects of nitrogen fertilizer on the composition of maize roots and their decomposition at different soil depths. European Journal of Soil Biology, 69, 43–50.

Ding X, Yuan Y, Liang Y, Li L, Han X. 2014. Impact of long-term application of manure, crop residue, and mineral fertilizer on organic carbon pools and crop yields in a Mollisol. Journal of Soils and Sediments, 14, 854–859.

Dou X, He P, Zhu P, Zhou W. 2016. Soil organic carbon dynamics under long-term fertilization in a black soil of China: Evidence from stable C isotopes. Scientific Reports, 6, 21488.

Duiker S W, Lal R. 1999. Crop residue and tillage effects on carbon sequestration in a Luvisol in central Ohio. Soil and Tillage Research, 52, 73–81.

Fan M, Lal R, Gao J, Qiao L, Su Y, RF J, Zhang F. 2013. Plant-based assessment of inherent soil productivity and contributions to China’s cereal crop yield increase since 1980. PLOS ONE, 8, 1–11.

Guenet B, Juarez S, Bardoux G, Abbadie L, Chenu C. 2012. Evidence that stable C is as vulnerable to priming effect as is more labile C in soil. Soil Biology and Biochemistry, 52, 43–48.

Jenkinson D S, Fox R H, Rayner J H. 1985. Interactions between fertilizer nitrogen and soil nitrogen - the so-called ‘priming’ effect. Journal of Soil Science, 36, 425–444.

Keesstra S D, Bouma J, Wallinga J, Tittonell P, Smith P, Cerdà A, Montanarella L, Quinton J N, Pachepsky Y, van der Putten W H, Bardgett R D, Moolenaar S, Mol G, Jansen B, Fresco L O. 2016. The significance of soils and soil science towards realization of the United Nations Sustainable Development Goals. Soil, 2, 111–128.

Kirkby C A, Richardson A E, Wade L J, Passioura J B, Batten G D, Blanchard C, Kirkegaard J A. 2014. Nutrient availability limits carbon sequestration in arable soils. Soil Biology and Biochemistry, 68, 402–409.

Kong A Y Y, Six J, Bryant D C, Denison R F, van Kessel C. 2005. The relationship between carbon input, aggregation, and soil organic carbon stabilization in sustainable cropping systems. Soil Science Society of America Journal, 69, 1078.

Kuzyakov Y, Friedel J K, Stahr K. 2000. Review of mechanisms and quantification of priming effects. Soil Biology and Biochemistry, 32, 1485–1498.

Kuzyakov Y. 2010. Priming effects: interactions between living and dead organic matter. Soil Biology and Biochemistry, 42, 1363–1371.

Lehtinen T, Schlatter N, Baumgarten A, Bechini L, Krüger J, Grignani C, Zavattaro L, Costamagna C, Spiegel H. 2014. Effect of crop residue incorporation on soil organic carbon and greenhouse gas emissions in European agricultural soils. Soil Use Manage, 30, 524–538.

Liang A Z, Zhang X P, Yang X M, Fang H J, Shen Y, Li W F. 2011. Distribution of soil organic carbon and its loss in black soils in Northeast China. Chinese Journal of Soil Science, 39, 533–538. (in Chinese)

Liang Y, Han X, Song C, Li H. 2011. Impacts of returning organic materials on soil labile organic carbon fractions redistribution of Mollisol in Northeast China. Scientia Agricultura Sinica, 44, 3565–3574. (in Chinese)

Liu C, Lu M, Cui J, Li B, Fang C. 2014. Effects of straw carbon input on carbon dynamics in agricultural soils: A meta-analysis. Global Change Biology, 20, 1366–1381.

Liu S, Jia S, Zhang X, Chen X, Zhang S, Sun B, Chen S, Dou Y. 2014. Effects of corn and soybean residues return on microbial biomass and respiration in a black soil. Soil and Crop, 3, 105–111. (in Chinese)

Liu X, Zhang Y, Wang Y, Sui Y, Zhang S, Herbert S, Ding G. 2010. Soil degradation: A problem threatening the sustainable development of agriculture in Northeast China. Plant Soil Environment, 56, 87–97.

Lou Y, Xu M, Wang W, Sun X, Zhao K. 2011. Return rate of straw residue affects soil organic C sequestration by chemical fertilization. Soil Tillage Research, 113, 70–73.

Lu F. 2015. How can straw incorporation management impact on soil carbon storage? A meta-analysis. Mitigation and Adaptation Strategies for Global Change, 20, 1545–1568.

Lu F, Wang X, Han B, Ouyang Z, Duan X, Zheng H, Miao H. 2009. Soil carbon sequestrations by nitrogen fertilizer application, straw return and no-tillage in China’s cropland. Global Change Biology, 15, 281–305.

Luo Z, Wang E, Sun O J. 2010. Can no-tillage stimulate carbon sequestration in agricultural soils? A meta-analysis of paired experiments. Agriculture, Ecosystems & Environment, 139, 224–231.

Majumder B, Kuzyakov Y. 2010. Effect of fertilization on decomposition of 14C labelled plant residues and their incorporation into soil aggregates. Soil Tillage Research, 109, 94–102.

Mathieu J A, Hatte C, Balesdent J, Parent E. 2015. Deep soil carbon dynamics are driven more by soil type than by climate: A worldwide meta-analysis of radiocarbon profiles. Global Change Biology, 21, 4278–4292.

Nelson D W, Sommers L E. 1996. Total carbon, organic carbon, and organic matter. In: Methods of Soil Analysis. American Society of Agronomy, USA. pp. 961–1010.

Ouyang W, Qi S, Hao F, Wang X, Shan Y, Chen S. 2013. Impact of crop patterns and cultivation on carbon sequestration and global warming potential in an agricultural freeze zone. Ecological Modelling, 252, 228–237.

Pan G, Li L, Wu L, Zheng X. 2003. Storage and sequestratio potential of topsoil organic carbon in China’s paddy soils. Global Change Biology, 10, 79–92.

Pang L, Huang G B. 2006. Impact of different tillage method on changing of soil organic carbon in semi-arid area. Soil and Water Conservation, 20, 110–113.

Piper C S. 1966. Soil and Plant Analysis. Inter Science Publishers, New York.

Pittelkow C M, Liang X, Linquist B A, van Groenigen K J, Lee J, Lundy M E, van Gestel N, Six J, Venterea R T, van Kessel C. 2015. Productivity limits and potentials of the principles of conservation agriculture. Nature, 517, 365–368.

Poeplau C, Kätterer T, Bolinder M A, Börjesson G, Berti A, Lugato E. 2015. Low stabilization of aboveground crop residue carbon in sandy soils of Swedish long-term experiments. Geoderma, 237, 246–255.

Powlson D S, Glendining M J, Coleman K, Whitmore A P. 2011. Implications for soil properties of removing cereal straw: Results from long-term studies. Agronomy Journal, 103, 279.

Van Reeuwijk L P. 2002. Procedures for Soil Analysis. 6th ed. International Soil Reference and Information Centre, Wageningen.

Song Z W, Zhu P, Gao H J, Peng C, Deng A X, Zheng C Y, Mannaf M A, Islam M N, Zhang W J. 2014. Effects of long-term fertilization on soil organic carbon content and aggregate composition under continuous maize cropping in Northeast China. Journal of Agricultural Science, 153, 236–244.

Srinivasarao C, Deshpande A N, Venkateswarlu B, Lal R, Singh A K, Kundu S, Vittal K P R, Mishra P K, Prasad J V N S, Mandal U K, Sharma K L. 2012. Grain yield and carbon sequestration potential of post monsoon sorghum cultivation in Vertisols in the semi arid tropics of central India. Geoderma, 175, 90–97.

Sun B, Wang X Y, Wang F, Jiang Y J, Zhang Y X. 2013. Assessing the relative effects of geographic location and soil type on microbial communities associated with straw decomposition. Applied and Environmental Microbiology, 79, 3327–3335.

Sun Y, Huang S, Yu X, Zhang W. 2013. Stability and saturation of soil organic carbon in rice fields: Evidence from a long-term fertilization experiment in subtropical China. Journal of Soils and Sediments, 13, 1327–1334.

Wang J, Wang X, Xu M, Feng G, Zhang W, Lu C A. 2015a. Crop yield and soil organic matter after long-term straw return to soil in China. Nutrient Cycling in Agroecosystems, 102, 371–381.

Wang J, Wang X, Xu M, Feng G, Zhang W, Yang X, Huang S. 2015b. Contributions of wheat and maize residues to soil organic carbon under long-term rotation in north China. Scientific Reports, 5, 11409.

Wang L, Qiu J, Tang H, Li H, Li C, Van Ranst E. 2008. Modelling soil organic carbon dynamics in the major agricultural regions of China. Geoderma, 147, 47–55.

Wiesmeier M, Hübner R, Kögel-Knabner I. 2015. Stagnating crop yields: An over looked risk for the carbon balance of agricultural soils. Science of the Total Environment, 536, 1045–1051.

Wiesmeier M, Hübner R, Spörlein P, Geuss U, Hangen E, Reischl A, Schilling B, vov Lützow M, Kögel-Knabner I. 2014. Carbon sequestration potential of soils in southeast Germay derived from stable soil organic carbon saturation. Global Chang Biology, 20, 653–665.

Wiesmeier M, Poeplau C, Sierra C A, Maier H, Frühauf C, Hübner R, Kühnel A, Spörlein P, Geuss U, Hangen E, Schilling B, von Lützow M, Kögel-Knabner I. 2016. Projected loss of soil organic carbon in temperate agricultural soils in the 21st century: Effects of climate change and carbon input trends. Scientific Reports, 6, 1–17.

Yan D, Wang D, Yang L. 2007. Long-term effect of chemical fertilizer, straw, and manure on labile organic matter fractions in a paddy soil. Biology and Fertility of Soils, 44, 93–101.

Yu G, Fang H, Gao L, Zhang W. 2006. Soil organic carbon budget and fertility variation of black soils in Northeast China. Ecological Research, 21, 855–867.

Zhang J, Hu K, Li K, Zheng C, Li B. 2017. Simulating the effects of long-term discontinuous and continuous fertilization with straw return on crop yields and soil organic carbon dynamics using the DNDC model. Soil Tillage Research, 165, 302–314.

Zhang W, Wang X, Xu M, Huang S, Liu H, Peng C. 2010. soil organic carbon dynamics under long-term fertilizations in arable land of northern China. Biogeosciences, 7, 409–425.

Zhang W, Xu M, Wang X, Huang Q, Nie J, Li Z, Li S, Hwang S W, Lee K B. 2012. Effects of organic amendments on soil carbon sequestration in paddy fields of subtropical China. Journal of Soils and Sediments, 12, 457–470.

Zhang X, Sui Y, Song C. 2013. Degradation process of arable Mollisols. Soil Crop, 2, 1–6.

Zheng L, Xie H, Zhang W, Zhang X. 2006. Effects of different ways of returning straw to the soils on soluble organic carbon. Ecological Research, 15, 80–83.

The efficiency of long-term straw return to sequester organic carbon in Northeast China's cropland

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics