还田秸秆碳在土壤中的转化分配及对土壤有机碳库影响的研究进展

doi:10.13287/j.1001-9332.201902.026

应用生态学报 ›› 2019, Vol. 30 ›› Issue (2): 668-676.doi: 10.13287/j.1001-9332.201902.026

还田秸秆碳在土壤中的转化分配及对土壤有机碳库影响的研究进展

杨艳华^1,2,苏瑶^2*,何振超²,喻曼²,陈喜靖²,沈阿林²

¹浙江农林大学环境与资源学院, 杭州 311300;
²浙江省农业科学院环境资源与土壤肥料研究所, 杭州 310021

收稿日期:2018-06-26 修回日期:2018-12-20 出版日期:2019-02-20 发布日期:2019-02-20
通讯作者: E-mail:stellasu@sina.com
作者简介:杨艳华,女,1993年生,硕士研究生.主要从事秸秆还田下的产地环境效应研究.E-mail:rose256789@163.com
基金资助:
本文由国家重点研发计划项目(2017YFD0800600)、浙江省自然科学基金项目(LQ18030001)、浙江省重点研发计划项目(2018C02036)和国家小麦产业技术体系项目(CARS-3)资助

Transformation and distribution of straw-derived carbon in soil and the effects on soil organic carbon pool: A review.

YANG Yan-hua^1,2, SU Yao^2*, HE Zhen-chao², YU Man², CHEN Xi-jing², SHEN A-lin²

¹College of Environment and Resources, Zhejiang A & F University, Hangzhou 311300, China;
²Environmental Resources and Soil Fertilizer Research Institute, Zhejiang Academy of Agricultural Sciences, Hangzhou 310021, China

Received:2018-06-26 Revised:2018-12-20 Online:2019-02-20 Published:2019-02-20
Supported by:
This work was supported by the National Key Research and Development Program of China (2017YFD0800600), the Zhejiang Natural Science Fund (LQ18030001), the Key Research and Development Program of Zhejiang Province (2018C02036) and the National Modern Agricultural Technology System of Wheat (CARS-3)

摘要/Abstract

摘要： 农田土壤有机碳库是全球碳循环的重要组成部分.随着秸秆还田技术的广泛应用,作物秸秆成为土壤外源碳的主要来源.秸秆碳在土壤中的转化与分配直接影响土壤有机碳组成与含量,进而改变土壤养分循环.基于近年来的相关研究,本文探讨了还田秸秆碳转化与分配过程的影响因子,详细介绍了参与秸秆碳同化过程的土壤微生物组成,归纳与阐述了秸秆碳对土壤有机碳组成、含量及其周转的影响.同时,就非生物因子对秸秆碳的生物转化效应的影响、秸秆碳转化过程中的生物和非生物因子的互作、秸秆碳氮和土壤碳氮循环的耦合作用、秸秆碳向土壤活性有机碳库或稳定性有机碳库转化的有效调控技术等主要研究方向进行了展望,以期为准确揭示秸秆还田条件下各类土壤有机碳的变化特征,进而为实现秸秆还田的高效培肥与固碳效应提供理论依据和技术支撑.

关键词: 土壤有机碳, 秸秆还田, 秸秆碳转化, 秸秆碳分配, 秸秆碳同化微生物

Abstract: Farmland soil organic carbon (SOC) pool is a crucial component of global carbon cycle. Due to the widely-implemented straw returning, crop straws have become the primary exogenous carbon source for agricultural soils. The conversion and distribution of straw-derived carbon in soil directly affect the composition and contents of SOC, with further influence on soil nutrient cycling. Based on recent studies, this review investigated the factors impacting the transformation and distribution of straw-carbon; introduced the microbial composition that contributes to the assimilation of carbon from straw; and summarized the effects of straw-carbon on the composition, content, and turnover of SOC. Additionally, we proposed the future research regarding the effects of abiotic factors on the bio-transformation of straw-carbon; the interaction between biotic and abiotic factors during the straw carbon transformation processes; the coupling of carbon and nitrogen from straws into the soil carbon and nitrogen cycles; and the effective control over the transformation of straw-carbon that enters the active or stable soil organic carbon pool. The purpose was to reveal variation characteristics of SOC during straw returning, and provide theoretical basis and technical support for the efficient fertilization and carbon sequestration of straw returning.

Key words: straw-C distribution, straw return, straw-C conversion, assimilating straw-C microbes, soil organic carbon

杨艳华,苏瑶,何振超,喻曼,陈喜靖,沈阿林. 还田秸秆碳在土壤中的转化分配及对土壤有机碳库影响的研究进展[J]. 应用生态学报, 2019, 30(2): 668-676.

YANG Yan-hua, SU Yao, HE Zhen-chao, YU Man, CHEN Xi-jing, SHEN A-lin. Transformation and distribution of straw-derived carbon in soil and the effects on soil organic carbon pool: A review.[J]. Chinese Journal of Applied Ecology, 2019, 30(2): 668-676.

参考文献

[1] Bi Y-Y (毕于运), Wang Y-J (王亚静), Gao C-Y (高春雨). System constitution and general trend of straw resource comprehensive utilization in China. Chinese Journal of Agricultural Resources and Regional Planning (中国农业资源与区划), 2010, 31(4): 35-38 (in Chinese)
[2] Xie G-H (谢光辉), Wang X-Y (王晓玉), Ren L-T (任兰天). China’s crop residues resources evaluation. Chinese Journal of Biotechnology (生物工程学报), 2010, 26(7): 855-863 (in Chinese)
[3] Yan C (闫超). Studies on Decomposition Regularity of Returning Rice Straw and Soil Nutrient Properties. PhD Thesis. Harbin: Northeast Agricultural University, 2015 (in Chinese)
[4] Shi Z-L (石祖梁), Jia T (贾涛),Wang Y-J (王亚静), et al. Comprehensive utilization status of crop straw and estimation of carbon from burning in China. Chinese Journal of Agricultural Resources and Regional Planning (中国农业资源与区划), 2017, 38(9): 32-37 (in Chinese)
[5] Liu L (刘乐), Jiu M-T (鞠美庭), Li W-Z (李维尊), et al. Techniques and economy analysis on straw resources utilization. Modern Agricultural Sciences and Technology (现代农业科技), 2011(8): 243-245 (in Chinese)
[6] Zhang G (张国), Lu F (逯非), Zhao H (赵红), et al. Residue usage and farmers’ recognition and attitude toward residue retention in China’s croplands. Journal of Agro-Environment Science (农业环境科学学报), 2017, 36(5): 981-988 (in Chinese)
[7] Lu F, Wang XK, Han B, et al. Soil carbon sequestrations by nitrogen fertilizer application, straw return and no-tillage in China’s cropland. Global Change Biology, 2009, 15: 281-305
[8] Thuriès L, Pansu M, Feller C, et al. Kinetics of added organic matter decomposition in a Mediterranean sandy soil. Soil Biology and Biochemistry, 2001, 33: 997-1010
[9] Pei JB, Li H, Li SY, et al. Dynamics of maize carbon contribution to soil organic carbon in association with soil type and fertility level. PLoS One, 2015, 10(3): e0120825
[10] Peng X-H (彭新华), Zhang B (张斌), Zhao Q-G (赵其国). A review on relationship between soil organic carbon pool and soil structure stability. Acta Pedologica Sinica (土壤学报), 2004, 41(4): 618-623 (in Chinese)
[11] Li X-H (李新华), Guo H-H (郭洪海), Zhu Z-L (朱振林), et al. Effects of different straw return modes on contents of soil organic carbon and fractions of soil active carbon. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2016, 32(9): 130-135 (in Chinese)
[12] Lal R. Soil carbon sequestration impacts on global climate change and food security. Science, 2004, 304: 1623-1627
[13] Zhang G (张国), Cao Z-P (曹志平), Hu C-J (胡婵娟). Soil organic carbon fractionation methods and their applications in farmland ecosystem research: A review. Chinese Journal of Applied Ecology (应用生态学报), 2011, 22(7): 1921-1930 (in Chinese)
[14] Zhang L-M (张丽敏), Xu M-G (徐明岗), Lou Y-L (娄翼来), et al. Soil organic carbon fractionation methods. Soil and Fertilizer Sciences in China (中国土壤与肥料), 2014(4): 1-6 (in Chinese)
[15] Six J, Conant RT, Paul EA, et al. Stabilization mechanisms of soil organic matter: Implications for C-saturation of soils. Plant and Soil, 2002, 241: 155-176
[16] Dou S (窦森). Soil Organic Matter: The Grouping of Soil Organic Matter. Beijing: Science Press, 2011 (in Chinese)
[17] Wang H (王虎), Wang X-D (王旭东), Tian X-H (田宵鸿). Effect of straw-returning on the storage and distribution of different active fractions of soil organic carbon. Chinese Journal of Applied Ecology (应用生态学报), 2014, 25(12): 3491-3498 (in Chinese)
[18] Stewart CE, Plante AF, Paustian K, et al. Soil carbon saturation: Linking concept and measurable carbon pools. Soil Science Society of America Journal, 2008, 72: 379-392
[19] Stewart CE, Paustian K, Conant RT, et al. Soil carbon saturation: Implications for measurable carbon pool dynamics in long-term incubations. Soil Biology and Biochemistry, 2009, 41: 357-366
[20] Dalal RC, Chan KY. Soil organic matter in rainfed cropping systems of the Australian cereal belt. Australian Journal of Soil Research, 2001, 39: 435-464
[21] Pei J-B (裴久渤). Transformation and Fixation of Maize Straw Carbon in the Dryland Soils of Northeast China. PhD Thesis. Shenyang: Shenyang Agricultural University, 2015 (in Chinese)
[22] 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: 80-99
[23] Yan DZ, Wang DJ, Yang LZ. Long-term effect of chemical fertilizer, straw, and manure on labile organic matter fractions in a paddy soil. Biology and Fertility of Soil, 2007, 44: 93-101
[24] Schulz E. Influence of site conditions and management on different soil organic matter (SOM) pools. Archives of Agronomy and Soil Science, 2004, 50: 33-48
[25] Zhang S-J (张仕吉), Xiang W-H (项文化). Research progress in effects of land use mode on soil active organic carbon. Journal of Central South University of Forestry and Technology (中南林业科技大学学报), 2012(5): 134-143 (in Chinese)
[26] Shi Y (史奕), Chen X (陈欣), Yang X-L (杨雪莲), et al. Review on study of the “slow” soil organic carbon pool. Chinese Journal of Ecology (生态学杂志), 2003, 22(5): 108-112 (in Chinese)
[27] Yu W-T (宇万太), Ma Q (马强), Zhao X (赵鑫), et al. Changes of soil active organic carbon pool under different land use types. Chinese Journal of Ecology (生态学杂志), 2007, 26(12): 2013-2016 (in Chinese)
[28] Wang Y-X (王义祥), Wang F (王峰), Ye J (叶菁), et al. Effect of edible fungus residues on aggregates associated carbon and resistant organic carbon in citrus orchard soils. Ecological Science (生态科学), 2016, 35(1): 27-33 (in Chinese)
[29] Marschner B, Brodowski S, Dreves A, et al. How relevant is recalcitrance for the stabilization of organic matter in soils? Journal of Plant Nutrition and Soil Science, 2008, 171: 91-110
[30] Koarashi J, Hockaday WC, Masiello CA, et al. Dynamics of decadally cycling carbon in subsurface soils. Biogeosciences, 2012, 117: 143-157
[31] Yu G-R (于贵瑞), Wang S-Q (王绍强), Chen P-Q (陈泮勤), et al. Isotope tracer approaches in soil organic carbon cycle research. Advances in Earth Science (地球科学进展), 2005, 20(5): 568-577 (in Chinese)
[32] Balesdent J, Mariotti A, Guillet B. Natural ¹³C abundance as a tracer for studies of soil organic matter dynamics. Soil Biology and Biochemistry, 1987, 19: 25-30
[33] Bernoux M, Cerri CC, Neill C, et al. The use of stable carbon isotopes for estimating soil organic matter turnover rates. Geoderma, 1998, 82: 43-58
[34] Kuzyakov Y. Sources of CO₂ efflux from soil and review of partitioning methods. Soil Biology and Biochemistry, 2006, 38: 425-448
[35] Bao C-P (暴春平), Guo Y-B (郭岩彬), Meng F-Q (孟凡乔), et al. Organic carbon change during decomposition of ¹³C labeled maize straw. The Fourth National Agriculture Proceedings of the Symposium on Environmental Science, Huhhot, 2011: 651-660 (in Chinese)
[36] Kristiansen SM, Brandt M, Hansen EM. ¹³C signature of CO₂ evolved from incubated maize residues and maize-derived sheep faeces. Soil Biology and Biochemistry, 2004, 36: 99-105
[37] Cogle AL, Saffigna PG, Strong WM. Carbon transformation during wheat straw decomposition. Soil Biology and Biochemistry, 1989, 21: 367-372
[38] Guan G-H (关桂红). Study on Carbon Turnover during Decomposition of ¹⁴C Labeled Winter Wheat Straw. Master Thesis. Beijing: China Agricultural University, 2006 (in Chinese)
[39] Wang Z-M (王志明), Zhu P-L (朱培立), Huang D-M (黄东迈). Carbon transformation and balance of ¹⁴C-labelled straw in submerged soils. Jiangsu Journal of Agricultural Sciences (江苏农业学报), 1998, 14(2): 112-117 (in Chinese)
[40] Blaud A, Lerch TZ, Chevallier T, et al. Dynamics of soil aggregation and carbon distribution among aggregates. Applied Soil Ecology, 2012, 53: 1-9
[41] Wang X, Sun B, Mao J, et al. Structural convergence of maize and wheat straw during two-year decomposition under different climate conditions. Environmental Science and Technology, 2012, 46: 7159-7165
[42] Wang J-Z (王金洲). Soil Organic Carbon Turnover under Straw Return. PhD Thesis. Beijing: China Agricultural University, 2015 (in Chinese)
[43] De Troyer I, Amery F, Van Moorleghem C. Tracing the source and fate of dissolved organic matter in soil after incorporation of a ¹³C labelled residue: A batch incubation study. Soil Biology and Biochemistry, 2011, 43: 513-519
[44] Poll C, Marhan S, Ingwersen J, et al. Dynamics of litter carbon turnover and microbial abundance in a rye detritusphere. Soil Biology and Biochemistry, 2008, 40: 1306-1321
[45] An TT, Schaeffer S, Zhuang J, et al. 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, 2015, 51: 605-613
[46] Angers DA, Recous S, Aita C. Fate of carbon and nitrogen in water-stable aggregates during decomposition of ¹³C¹⁵N-labelled wheat straw in situ. European Journal of Soil Biology, 1997, 48: 295-300
[47] Six J, Bossuyt H, Degryze S, et al. A history of research on the link between (micro)aggregates, soil biota, and soil organic matter dynamics. Soil and Tillage Research, 2004, 79: 7-31
[48] Gu X (顾鑫), An T-T (安婷婷), Li S-Y (李双异), et al. Effects of application of straw on organic carbon in brown soil aggregates by δ¹³C method. Journal of Soil and Water Conservation (水土保持学报), 2014, 28(2): 243-247 (in Chinese)
[49] Li SY, Gu X, Zhuang J, et al. Distribution and storage of crop residue carbon in aggregates and its contribution to organic carbon of soil with low fertility. Soil and Tillage Research, 2016, 155: 199-206
[50] Liu Z (刘哲), Han J-C (韩霁昌), Sun Z-H (孙增慧), et al. Change law of organic carbon in lime concretion black soil aggregates with application of straw by δ¹³C method. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2017, 33(14): 179-187 (in Chinese)
[51] Beyaert RP, Paul Voroney RE. Estimation of decay constants for crop residues measured over 15 years in conventional and reduced tillage systems in a coarse-textured soil in southern Ontario. Canadian Journal of Soil Science, 2011, 91: 785-995
[52] Wang X-D (王旭东), Chen X-N (陈鲜妮), Wang C-X (王彩霞), et al. Decomposition of corn stalk in cropland with different fertility. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2009, 25(10): 252-257 (in Chinese)
[53] Wang Z-M (王志明), Zhu P-L (朱培立), Huang D-M (黄东迈), et al. Straw carbon decomposition in situ in field and characteristics of soil biomass carbon turnover. Acta Pedologica Sinica (土壤学报), 2003, 40(3): 446-453 (in Chinese)
[54] Chen R, Senbayram M, Blagodatsky S, et al. Soil C and N availability determine the priming effect: Microbial N mining and stoichiometric decomposition theories. Global Change Biology, 2014, 20: 2356-2367
[55] Poirier V, Angers DA, Rochette P. Initial soil organic carbon concentration influences the short-term retention of crop-residue carbon in the fine fraction of a heavy clay soil. Biology and Fertility of Soils, 2013, 49: 527-535
[56] Dou S (窦森). Black earth conservation and corn stover deep incorporation to subsoil. Journal of Jilin Agricultural University (吉林农业大学学报), 2016, 38(5): 511-516 (in Chinese)
[57] Dou S (窦森). Improving subsoil fertility through a new technology of continuous in belt and deep incorporation of corn stover. Journal of Plant Nutrition and Fertili-zer (植物营养与肥料学报), 2017, 23(6): 1670-1675 (in Chinese)
[58] Zuo Y-P (左玉萍), Jia Z-K (贾志宽). Suitable soil water content and critical value for straw decomposing. Acta Agriculturae Boreali-Occidentalis Sinica (西北农业学报), 2003, 12(3): 73-75 (in Chinese)
[59] Zuo Y-P (左玉萍), Jia Z-K (贾志宽). Effect of soil moisture content on straw decomposing and its dynamic changes. Journal of Northwest A&F University (西北农林科技大学学报), 2004, 32(5): 61-63 (in Chinese)
[60] Chen HQ, Hou RX, Gong YS, et al. Effects of 11 years of conservation tillage on soil organic matter fractions in wheat monoculture in Loess Plateau of China. Soil and Tillage Research, 2009, 106: 85-94
[61] Marschner P, Umar S, Baumann K. The microbial community composition changes rapidly in the early stages of decomposition of wheat residue. Soil Biology and Biochemistry, 2011, 43: 445-451
[62] Bernard L, Mougel C, Maron PA, et al. Dynamics and identification of soil microbial populations actively assimilating carbon from ¹³C-labelled wheat residue as estimated by DNA- and RNA-SIP techniques. Environmental Microbiology, 2007, 9: 752-764
[63] Fan FL, Yin C, Tang YJ, et al. Probing potential microbial coupling of carbon and nitrogen cycling during decomposition of maize residue by ¹³C-DNA-SIP. Soil Biology and Biochemistry, 2014, 70: 12-21
[64] Schellenberger S, Kolb S, Drake HL. Metabolic responses of novel cellulolytic and saccharolytic agricultural soil bacteria to oxygen. Environmental Microbiology, 2010, 12: 845-861
[65] Espaa M, Rasche F, Kandeler E. Assessing the effect of organic residue quality on active decomposing fungi in a tropical Vertisol using ¹⁵N-DNA stable isotope probing. Fungal Ecology, 2011, 4: 115-119
[66] Eichorst SA, Kuske CR. Identification of cellulose-responsive bacterial and fungal communities in geographically and edaphically different soils by using stable isotope probing. Applied and Environmental Microbiology, 2012, 78: 2316-2327
[67] Semenov AV, Pereira E, Silva MC, et al. Impact of incorporated fresh ¹³C potato tissues on the bacterial and fungal community composition of soil. Soil Biology and Biochemistry, 2012, 49: 88-95
[68] Shrestha M, Shrestha PM, Conrad R. Bacterial and archaeal communities involved in the in situ degradation of ¹³C-labelled straw in the rice rhizosphere. Environmental Microbiology Reports, 2011, 3: 587-596
[69] Kirkby CA, Richardson AE, Wade LJ, et al. Nutrient availability limits carbon sequestration in arable soil. Soil Biology and Biochemistry, 2014, 68: 402-409
[70] Xu Y-D (徐英德), Sun L-J (孙良杰), Wang J-K (汪景宽), et al. Nitrogen transformation of returned straw in soil and its effect on soil nitrogen transformation. Acta Agriculturae Universitatis Jiangxiensis (江西农业大学学报), 2017, 39(5): 859-870 (in Chinese)
[71] Lehtinen T, Schlatter N, Baumgarten A, et al. Effect of crop residue incorporation on soil organic carbon and greenhouse gas emissions in European agricultural soils. Soil Use and Management, 2014, 30: 524-538
[72] Lu F. How can straw incorporation management impact on soil carbon storage? A meta-analysis. Mitigation and Adaptation Strategies for Global Change, 2015, 20: 1545-1568
[73] Powlson DS, Glendining MJ, Coleman K, et al. Implications for soil properties of removing cereal straw: Results from long-term studies. Agronomy Journal, 2011, 103: 279-287
[74] Liu C, Lu M, Cui J, et al. Effects of straw carbon input on carbon dynamics in agricultural soils: A meta-analysis. Global Change Biology, 2014, 20: 1366-1381
[75] Chen X-N (陈鲜妮), Yue X-J (岳西杰), Ge X-Z (葛玺祖), et al. Effect of long-term residue return on soil organic carbon storage. Journal of Natural Resources (自然资源学报), 2012, 27(1): 25-32 (in Chinese)
[76] Zhu LQ, Hu NJ, Zhang ZW, et al. Short-term responses of soil organic carbon and carbon pool management index to different annual straw return rates in a rice-wheat cropping system. Catena, 2015, 135: 283-289
[77] Poeplau C, Ktterer T, Bolinder MA. Low stabilization of aboveground crop residue carbon in sandy soils of Swedish long-term experiments. Geoderma, 2015, 237: 246-255
[78] Lei D (雷达), Xi L-W (席来旺), Li W-Z (李文政), et al. Study of comprehensive utilization of straw abroad. Modern Agricultural Equipments (现代农业装备), 2007(7): 67-68 (in Chinese)
[79] Cui T-T (崔婷婷), Dou S (窦森), Yang Y-N (杨轶囡), et al. Effect of deep applied corn stalks on composition of soil humus and structure of humic acid. Acta Pedologica Sinica (土壤学报), 2014, 51(4): 718-725 (in Chinese)
[80] Lemke RL, Vandenbygaart AJ, Campbell CA, et al. Crop residue removal and fertilizer N: Effects on soil organic carbon in a long-term crop rotation experiment on a Udic Boroll. Agriculture, Ecosystems and Environment, 2010, 135: 42-51
[81] Saffih-Hdad K, Mary B. Modeling consequences of straw residues export on soil organic carbon. Soil Biology and Biochemistry, 2008, 40: 594-607
[82] Campbel CA, Selles F, Lafond GP, et al. Adopting zero tillage management: Impact on soil C and N under long-term crop rotations in a thin Black Chernozem. Canadian Journal of Soil Science, 2001, 81: 139-148
[83] Curtin D, Fraser PM. Soil organic matter as influenced by straw management practices and inclusion of grass and clover seed crops in cereal rotations. Australian Journal of Soil Research, 2003, 41: 95-106
[84] Powlson DS, Glendining MJ, Coleman K, et al. Implications for soil properties of removing cereal straw: Result from long-term studies. Agronomy Journal, 2011, 103: 279-287
[85] Yi Y-F (伊云峰), Cai Z-C (蔡祖聪). Decomposition rates of organic carbon in whole soil and heavy fraction of red soil incorporated with maize stalks using carbon-13 natural abundance. Acta Pedologica Sinica (土壤学报), 2007, 44(6): 1022-1027 (in Chinese)
[86] Blagodatskaya E, Kuzyakov Y. Mechanisms of real and apparent priming effects and their dependence on soil microbial biomass and community structure: Critical review. Biology and Fertility of Soils, 2008, 45: 115-131

编辑推荐 0

Metrics

阅读次数

全文

362

HTML			PDF

最新录用	在线预览	正式出版	最新录用	在线预览	正式出版
0	0	0	0	0	362

来源	本网站	其他网站

次数	254	108
比例	70%	30%

摘要

768

最新录用	在线预览	正式出版

0	0	768

来源	本网站	其他网站

次数	532	236
比例	69%	31%

还田秸秆碳在土壤中的转化分配及对土壤有机碳库影响的研究进展

Transformation and distribution of straw-derived carbon in soil and the effects on soil organic carbon pool: A review.

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐 0

Metrics

本文评价

[1]	张羽涵, 李瑶, 周玥, 陈圆佳, 安韶山. 宁南山区不同恢复年限柠条林土壤养分及有机碳组分变化特征 [J]. 应用生态学报, 2024, 35(3): 639-647.
[2]	杨阳, 王宝荣, 窦艳星, 薛志婧, 孙慧, 王云强, 梁超, 安韶山. 植物源和微生物源土壤有机碳转化与稳定研究进展 [J]. 应用生态学报, 2024, 35(1): 111-123.
[3]	申继凯, 黄懿梅, 黄倩, 徐凤璟. 黄土高原不同植被类型土壤微生物残体碳的积累及其对有机碳的贡献 [J]. 应用生态学报, 2024, 35(1): 124-132.
[4]	贾娟, 李星奇, 冯晓娟. 排水对我国两种典型湿地土壤有机碳微生物转化过程的影响 [J]. 应用生态学报, 2024, 35(1): 133-140.
[5]	胡建文, 刘常富, 勾蒙蒙, 陈会玲, 雷蕾, 肖文发, 朱粟锋, 斛如媛. 林龄对马尾松人工林微生物残体碳积累的影响机制 [J]. 应用生态学报, 2024, 35(1): 153-160.
[6]	张羽涵, 李瑶, 周玥, 刘春晖, 安韶山. 宁南山区不同恢复年限柠条林地土壤微生物残体碳沿剖面分布特征 [J]. 应用生态学报, 2024, 35(1): 161-168.
[7]	井艳丽, 李旭华, 张袁, 张馨月, 刘美, 冯秋红. 间伐对川西亚高山云杉人工林土壤微生物残体碳积累的影响 [J]. 应用生态学报, 2024, 35(1): 169-176.
[8]	王翠娟, 刘小飞, 杨柳明, 贾淑娴. 中亚热带米槠人工林土壤微生物残体碳对凋落物和根系碳输入的响应 [J]. 应用生态学报, 2024, 35(1): 177-185.
[9]	薛志婧, 屈婷婷, 刘春晖, 刘小槺, 王蕊, 王宁, 周正朝, 董治宝. 培养条件下枯落物分解过程中微生物残体对土壤有机碳形成的贡献 [J]. 应用生态学报, 2023, 34(7): 1845-1852.
[10]	苗贺, 袁磊, 杨淼茵, 胡艳宇, 陈欣, 何红波, 张旭东, 解宏图, 鲁彩艳. 基于¹⁵N示踪的东北黑土地保护性耕作农田减氮增产调控机制 [J]. 应用生态学报, 2023, 34(4): 876-882.
[11]	吕付泽, 杨雅丽, 鲍雪莲, 张常仁, 郑甜甜, 何红波, 张旭东, 解宏图. 免耕不同秸秆覆盖量对黑土微生物群落及其残留物的影响 [J]. 应用生态学报, 2023, 34(4): 903-912.
[12]	高燕, 梁爱珍, 黄丹丹, 张延, 张旸, 王阳, 张士秀, 陈学文. 长期免耕对黑土氮磷硫循环微生物功能潜力的影响 [J]. 应用生态学报, 2023, 34(4): 913-920.
[13]	李文慧, 林妍敏, 南雄雄, 王芳, 朱丽珍. 果树-覆盖作物可持续种植体系土壤碳氮固存及其影响因素 [J]. 应用生态学报, 2023, 34(2): 471-480.
[14]	裴亚楠, 吕卫光, 郭涛, 白娜玲, 李双喜, 张娟琴, 张海韵, 张翰林. 秸秆还田配施促腐菌剂对土壤团聚体及其养分的影响 [J]. 应用生态学报, 2023, 34(12): 3357-3363.
[15]	龚政, 文天翼, 靳闯, 赵堃, 苏敏. 江苏中部潮滩湿地土壤有机碳分布特征及影响因子 [J]. 应用生态学报, 2023, 34(11): 2978-2984.