Soil Carbon Emission Sources Differ Under Litter and Nutrient Addition During Secondary Succession: Evidence from a Mesocosm Study Using a Three-Transfer-Pool Model
暂无分享,去创建一个
[1] Guangyu Zhu,et al. Differential microbial assembly processes and co‐occurrence networks in the soil‐root continuum along an environmental gradient , 2022, iMeta.
[2] M. Torn,et al. Response of soil greenhouse gas fluxes to warming: A global meta‐analysis of field studies , 2022, Geoderma.
[3] S. Dong,et al. Stabilization of soil organic carbon in the alpine meadow is dependent on the nitrogen deposition level on the Qinghai-Tibetan Plateau , 2021 .
[4] A. Duan,et al. Impacts of Irrigation Managements on Soil CO2 Emission and Soil CH4 Uptake of Winter Wheat Field in the North China Plain , 2021, Water.
[5] B. Zhu,et al. Nitrogen addition stimulates priming effect in a subtropical forest soil , 2021 .
[6] J. Alatalo,et al. Climate Warming Consistently Reduces Grassland Ecosystem Productivity , 2021, Earth's Future.
[7] C. Castanha,et al. Five years of whole-soil warming led to loss of subsoil carbon stocks and increased CO2 efflux , 2021, Science Advances.
[8] Yingjun Zhang,et al. Transformation of litter carbon to stable soil organic matter is facilitated by ungulate trampling , 2021 .
[9] Zhongkui Luo,et al. Long-term litter type treatments alter soil carbon composition but not microbial carbon utilization in a mixed pine-oak forest , 2021, Biogeochemistry.
[10] James T. Anderson,et al. Decomposition and nutrient dynamics responses of plant litter to interactive effects of flooding and salinity in Yellow River Delta wetland in northeastern China , 2021 .
[11] Shuaifeng Li,et al. Effects of plant diversity and soil properties on soil fungal community structure with secondary succession in the Pinus yunnanensis forest , 2020 .
[12] J. Peñuelas,et al. Phosphorus addition decreases microbial residual contribution to soil organic carbon pool in a tropical coastal forest , 2020, Global change biology.
[13] Yusheng Yang,et al. N addition increased microbial residual carbon by altering soil P availability and microbial composition in a subtropical Castanopsis forest , 2020 .
[14] Z. Shi,et al. Distinct controls over the temporal dynamics of soil carbon fractions after land use change , 2020, Global change biology.
[15] Jingyun Fang,et al. Effects of seven-year nitrogen and phosphorus additions on soil microbial community structures and residues in a tropical forest in Hainan Island, China , 2020 .
[16] Guangyu Zhu,et al. Nutrient limitation of litter decomposition with long-term secondary succession: evidence from controlled laboratory experiments , 2020, Journal of Soils and Sediments.
[17] Shucun Sun,et al. Priming effect of litter mineralization: the role of root exudate depends on its interactions with litter quality and soil condition , 2019, Plant and Soil.
[18] C. Kucharik,et al. Litter quantity, litter chemistry, and soil texture control changes in soil organic carbon fractions under bioenergy cropping systems of the North Central U.S. , 2019, Biogeochemistry.
[19] C. Liang,et al. Reforestation accelerates soil organic carbon accumulation: Evidence from microbial biomarkers , 2019, Soil Biology and Biochemistry.
[20] J. Bremner. Nitrogen-Total , 2018, SSSA Book Series.
[21] Kerong Zhang,et al. Linking soil bacterial and fungal communities to vegetation succession following agricultural abandonment , 2018, Plant and Soil.
[22] B. Moore,et al. Model structures amplify uncertainty in predicted soil carbon responses to climate change , 2018, Nature Communications.
[23] D. W. Nelson,et al. Total Carbon, Organic Carbon, and Organic Matter , 1983, SSSA Book Series.
[24] Willem Bouten,et al. Probing the limits of predictability: data assimilation of chaotic dynamics in complex food webs. , 2018, Ecology letters.
[25] P. Marquet,et al. Microbial communities in soil chronosequences with distinct parent material: the effect of soil pH and litter quality , 2017 .
[26] Z. Shangguan,et al. Differential responses of litter decomposition to nutrient addition and soil water availability with long-term vegetation recovery , 2017, Biology and Fertility of Soils.
[27] Yusheng Yang,et al. Litter decomposition, residue chemistry and microbial community structure under two subtropical forest plantations: A reciprocal litter transplant study , 2016 .
[28] Yiqi Luo,et al. Differential responses of ecosystem respiration components to experimental warming in a meadow grassland on the Tibetan Plateau , 2016 .
[29] Jizhong Zhou,et al. Soil properties control decomposition of soil organic carbon: Results from data-assimilation analysis , 2016 .
[30] Z. Shangguan,et al. Impact of long-term N additions upon coupling between soil microbial community structure and activity, and nutrient-use efficiencies , 2015 .
[31] Yiqi Luo,et al. Application of a two‐pool model to soil carbon dynamics under elevated CO2 , 2015, Global change biology.
[32] Lauren C. Cline,et al. Soil microbial communities are shaped by plant-driven changes in resource availability during secondary succession. , 2015, Ecology.
[33] M. Kleber,et al. The contentious nature of soil organic matter , 2015, Nature.
[34] E. Kuramae,et al. Land-use system shapes soil bacterial communities in Southeastern Amazon region , 2015 .
[35] S. K. Schmidt,et al. Fire severity shapes plant colonization effects on bacterial community structure, microbial biomass, and soil enzyme activity in secondary succession of a burned forest , 2015 .
[36] Jinsheng Xie,et al. Forest conversion stimulated deep soil C losses and decreased C recalcitrance through priming effect in subtropical China , 2015, Biology and Fertility of Soils.
[37] Matthew J. Smith,et al. Microbial models with data‐driven parameters predict stronger soil carbon responses to climate change , 2015, Global change biology.
[38] Guoyi Zhou,et al. Increased litter input increases litter decomposition and soil respiration but has minor effects on soil organic carbon in subtropical forests , 2015, Plant and Soil.
[39] Jizhong Zhou,et al. Methods for estimating temperature sensitivity of soil organic matter based on incubation data: A comparative evaluation , 2015 .
[40] Gang Zhang,et al. Nitrogen and phosphorus leaching losses from intensively managed paddy fields with straw retention , 2014 .
[41] B. Elberling,et al. Circumpolar assessment of permafrost C quality and its vulnerability over time using long‐term incubation data , 2014, Global change biology.
[42] Shan Xu,et al. Variability of above-ground litter inputs alters soil physicochemical and biological processes: a meta-analysis of litterfall-manipulation experiments , 2013 .
[43] Lei Deng,et al. Soil organic carbon storage capacity positively related to forest succession on the Loess Plateau, China , 2013 .
[44] M. Rahman. Carbon Dioxide Emission from Soil , 2013, Agricultural Research.
[45] K. Denef,et al. The Microbial Efficiency‐Matrix Stabilization (MEMS) framework integrates plant litter decomposition with soil organic matter stabilization: do labile plant inputs form stable soil organic matter? , 2013, Global change biology.
[46] S. Hart,et al. Evaluation of mechanisms controlling the priming of soil carbon along a substrate age gradient , 2013 .
[47] Kerong Zhang,et al. Linking litter production, quality and decomposition to vegetation succession following agricultural abandonment , 2013 .
[48] H. Richnow,et al. Can the labile carbon contribute to carbon immobilization in semiarid soils? Priming effects and microbial community dynamics , 2013 .
[49] Axel Don,et al. Sensitivity of soil organic carbon stocks and fractions to different land-use changes across Europe , 2013 .
[50] Sukartiningsih,et al. Fluxes of dissolved organic carbon and nitrogen in cropland and adjacent forests in a clay-rich Ultisol of Thailand and a sandy Ultisol of Indonesia , 2013 .
[51] Rob Knight,et al. Comparative metagenomic, phylogenetic and physiological analyses of soil microbial communities across nitrogen gradients , 2011, The ISME Journal.
[52] H. Epstein,et al. Estimating carbon source-sink transition during secondary succession in a Virginia valley , 2012, Plant and Soil.
[53] S. Sohi,et al. The priming potential of biochar products in relation to labile carbon contents and soil organic matter status , 2011 .
[54] T. Marthews,et al. Soil carbon release enhanced by increased tropical forest litterfall , 2011 .
[55] A. Desai,et al. A primer for data assimilation with ecological models using Markov Chain Monte Carlo (MCMC) , 2011, Oecologia.
[56] Shenfeng Fei,et al. Ecological forecasting and data assimilation in a data-rich era. , 2011, Ecological applications : a publication of the Ecological Society of America.
[57] S. Reed,et al. Estimating phosphorus availability for microbial growth in an emerging landscape , 2011 .
[58] Yiqi Luo,et al. Dynamic disequilibrium of the terrestrial carbon cycle under global change. , 2011, Trends in ecology & evolution.
[59] H. Wickham. ggplot2 , 2011 .
[60] B. Mary,et al. Fungi mediate long term sequestration of carbon and nitrogen in soil through their priming effect , 2011 .
[61] N. Fierer,et al. Widespread coupling between the rate and temperature sensitivity of organic matter decay , 2010 .
[62] J. Etchevers,et al. Nutrient Addition Differentially Affects Soil Carbon Sequestration in Secondary Tropical Dry Forests: Early‐ versus Late‐Succession Stages , 2010 .
[63] Shiwei Zhao,et al. Quantitative analysis of soil pores under natural vegetation successions on the Loess Plateau , 2010 .
[64] Z. Shangguan,et al. Changes in species richness and community productivity during succession on the Loess Plateau (China) , 2010 .
[65] B. Hungate,et al. Priming depletes soil carbon and releases nitrogen in a scrub-oak ecosystem exposed to elevated CO2 , 2009 .
[66] Sandra Díaz,et al. Plant species traits are the predominant control on litter decomposition rates within biomes worldwide. , 2008, Ecology letters.
[67] S. Allison,et al. Microbial activity and soil respiration under nitrogen addition in Alaskan boreal forest , 2008 .
[68] Qingkui Wang,et al. Comparisons of litterfall, litter decomposition and nutrient return in a monoculture Cunninghamia lanceolata and a mixed stand in southern China , 2008 .
[69] Richard J. Hobbs,et al. Linking restoration and ecological succession , 2007 .
[70] P. Jarvis,et al. Modelling the effect of temperature on carbon mineralization rates across a network of European forest sites (FORCAST) , 2006 .
[71] W. Schlesinger,et al. The turnover of carbon pools contributing to soil CO2 and soil respiration in a temperate forest exposed to elevated CO2 concentration , 2006 .
[72] L. White,et al. Probabilistic inversion of a terrestrial ecosystem model: Analysis of uncertainty in parameter estimation and model prediction , 2006 .
[73] C. Williams,et al. Carbon dioxide exchange and early oldfield succession , 2006 .
[74] Chunyan Wang,et al. Microbial biomass and nutrients in soil at the different stages of secondary forest succession in Ziwulin, northwest China , 2005 .
[75] Michael J. Rogers,et al. Long-term sensitivity of soil carbon turnover to warming , 2005, Nature.
[76] Andrea Ricca,et al. Carbon and nitrogen dynamics along the decay continuum: Plant litter to soil organic matter , 1989, Plant and Soil.
[77] G. Asner,et al. Nitrogen Cycles: Past, Present, and Future , 2004 .
[78] Luc Abbadie,et al. Carbon input to soil may decrease soil carbon content , 2004 .
[79] E. Ceccon,et al. Effects of nitrogen and phosphorus fertilization on the survival and recruitment of seedlings of dominant tree species in two abandoned tropical dry forests in Yucatán, Mexico , 2003 .
[80] E. Matzner,et al. Biodegradation of soil-derived dissolved organic matter as related to its properties , 2003 .
[81] Josep G. Canadell,et al. Sustainability of terrestrial carbon sequestration: A case study in Duke Forest with inversion approach , 2003 .
[82] W. Dazhong,et al. Review on study of the "slow" soil organic carbon pool , 2003 .
[83] V. Gulis,et al. Leaf litter decomposition and microbial activity in nutrient‐enriched and unaltered reaches of a headwater stream , 2003 .
[84] A. Townsend,et al. Phosphorus Limitation of Microbial Processes in Moist Tropical Forests: Evidence from Short-term Laboratory Incubations and Field Studies , 2002, Ecosystems.
[85] E. Boyle,et al. The global carbon cycle: a test of our knowledge of earth as a system. , 2000, Science.
[86] G. Guggenberger,et al. The role of DOM sorption to mineral surfaces in the preservation of organic matter in soils. , 2000 .
[87] William H. McDowell,et al. Long-Term Nitrogen Additions and Nitrogen Saturation in Two Temperate Forests , 2000, Ecosystems.
[88] Richard A. Houghton,et al. Changes in terrestrial carbon storage in the United States. 1: The roles of agriculture and forestry. , 2000 .
[89] A. C. Kennedy. Bacterial diversity in agroecosystems , 1999 .
[90] S. Trumbore,et al. Potential responses of soil organic carbon to global environmental change. , 1997, Proceedings of the National Academy of Sciences of the United States of America.
[91] D. Rubin,et al. Inference from Iterative Simulation Using Multiple Sequences , 1992 .
[92] Jinshui Wu,et al. Measurement of soil microbial biomass C by fumigation-extraction—an automated procedure , 1990 .
[93] W. Parton,et al. Analysis of factors controlling soil organic matter levels in Great Plains grasslands , 1987 .
[94] W. K. Hastings,et al. Monte Carlo Sampling Methods Using Markov Chains and Their Applications , 1970 .
[95] N. Metropolis,et al. Equation of State Calculations by Fast Computing Machines , 1953, Resonance.