Linking soil organic carbon mineralization to soil physicochemical properties and bacterial alpha diversity at different depths following land use changes

[1]  Y. Liao,et al.  Microbial functional genes within soil aggregates drive organic carbon mineralization under contrasting tillage practices , 2023, Land Degradation & Development.

[2]  Youping Li,et al.  New insights into carbon mineralization in tropical paddy soil under land use conversion: Coupled roles of soil microbial community, metabolism, and dissolved organic matter chemodiversity , 2023, Geoderma.

[3]  Xiaodong Wu,et al.  Linking soil organic carbon mineralization with soil variables and bacterial communities in a permafrost-affected tussock wetland during laboratory incubation , 2023, CATENA.

[4]  Zhongkui Luo,et al.  Global soil profiles indicate depth-dependent soil carbon losses under a warmer climate , 2022, Nature Communications.

[5]  E. Blagodatskaya,et al.  Land use impact on carbon mineralization in well aerated soils is mainly explained by variations of particulate organic matter rather than of soil structure , 2022, SOIL.

[6]  C. P. Whitby,et al.  The regulators of soil organic carbon mineralization upon lime and/or phosphate addition vary with depth. , 2022, The Science of the total environment.

[7]  Nicholas D. Youngblut,et al.  Bacterial community dynamics explain carbon mineralization and assimilation in soils of different land-use history , 2022, bioRxiv.

[8]  E. Cammeraat,et al.  Soil organic carbon content and mineralization controlled by the composition, origin and molecular diversity of organic matter: A study in tropical alpine grasslands , 2022, Soil and Tillage Research.

[9]  D. Berre,et al.  A global overview of studies about land management, land‐use change, and climate change effects on soil organic carbon , 2021, Global change biology.

[10]  Yaqiong Wu,et al.  Soil bacterial community composition and diversity response to land conversion is depth-dependent , 2021, Global Ecology and Conservation.

[11]  A. K. Biswas,et al.  Impact of Varied Levels of N, P, and S Stoichiometry on C Mineralization from three Contrasting Soils with or Without Wheat Straw Amendment: a Laboratory Study , 2021, Journal of Soil Science and Plant Nutrition.

[12]  L. Bramer,et al.  Spatial access and resource limitations control carbon mineralization in soils , 2021, Soil Biology and Biochemistry.

[13]  Xiaorong Wei,et al.  Long-term afforestation accelerated soil organic carbon accumulation but decreased its mineralization loss and temperature sensitivity in the bulk soils and aggregates , 2021 .

[14]  L. Zwieten,et al.  Abiotic and biotic regulation on carbon mineralization and stabilization in paddy soils along iron oxide gradients , 2021 .

[15]  Yixiang Wang,et al.  Linking soil carbon availability, microbial community composition and enzyme activities to organic carbon mineralization of a bamboo forest soil amended with pyrogenic and fresh organic matter. , 2021, The Science of the total environment.

[16]  Xiaorong Wei,et al.  Changes in soil organic carbon and nitrogen mineralization and their temperature sensitivity in response to afforestation across China’s Loess Plateau , 2021, CATENA.

[17]  Shikha,et al.  Carbon Mineralization Rates and Kinetics of Surface-Applied and Incorporated Rice and Maize Residues in Entisol and Inceptisol Soil Types , 2021, Sustainability.

[18]  M. L. Mora,et al.  Carbon Mineralization Controls in Top- and Subsoil Horizons of Two Andisols Under Temperate Old-Growth Rain Forest , 2021 .

[19]  Yuting Liang,et al.  Organic amendments drive shifts in microbial community structure and keystone taxa which increase C mineralization across aggregate size classes , 2021 .

[20]  L. Ping,et al.  Systematic relationship between soil properties and organic carbon mineralization based on structural equation modeling analysis , 2020 .

[21]  Atul K. Jain,et al.  Global Carbon Budget 2020 , 2020, Earth System Science Data.

[22]  C. Chenu,et al.  Similar specific mineralization rates of organic carbon and nitrogen in incubated soils under contrasted arable cropping systems , 2020 .

[23]  P. Millard,et al.  Temperature sensitivity of decomposition: Discrepancy between field and laboratory estimates is not due to sieving the soil , 2020 .

[24]  Andreas Richter,et al.  C:N:P stoichiometry regulates soil organic carbon mineralization and concomitant shifts in microbial community composition in paddy soil , 2020, Biology and Fertility of Soils.

[25]  W. Wanek,et al.  Direct measurement of the in situ decomposition of microbial-derived soil organic matter , 2020 .

[26]  Nicholas D. Youngblut,et al.  Soil characteristics and land-use drive bacterial community assembly patterns. , 2019, FEMS microbiology ecology.

[27]  L. Sallustio,et al.  Soil organic carbon in Italian forests and agroecosystems: Estimating current stock and future changes with a spatial modelling approach , 2019, Agricultural and Forest Meteorology.

[28]  G. Pan,et al.  The responses of soil organic carbon mineralization and microbial communities to fresh and aged biochar soil amendments , 2019, GCB Bioenergy.

[29]  M. L. Thompson,et al.  Linking chemical structure of dissolved organic carbon and microbial community composition with submergence-induced soil organic carbon mineralization. , 2019, The Science of the total environment.

[30]  Jinsheng Xie,et al.  Organic carbon mineralization in soils of a natural forest and a forest plantation of southeastern China , 2019, Geoderma.

[31]  B. Singh,et al.  Responses of soil greenhouse gas emissions to different application rates of biochar in a subtropical Chinese chestnut plantation , 2019, Agricultural and Forest Meteorology.

[32]  Robert B. Litterman,et al.  Natural climate solutions are not enough , 2019, Science.

[33]  Heleen de Coninck,et al.  Technical Summary. In: Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways , 2018 .

[34]  Yaqiong Wu,et al.  Vertical and seasonal variations of soil carbon pools in ginkgo agroforestry systems in eastern China , 2018, CATENA.

[35]  Loiy Al‐Ghussain Global warming: review on driving forces and mitigation , 2018, Environmental Progress & Sustainable Energy.

[36]  L. Elsgaard,et al.  Carbon mineralization and microbial activity in agricultural topsoil and subsoil as regulated by root nitrogen and recalcitrant carbon concentrations , 2018, Plant and Soil.

[37]  A. Andriulo,et al.  Response of soil microbial communities to agroecological versus conventional systems of extensive agriculture , 2018, Agriculture, Ecosystems & Environment.

[38]  M. Shahid,et al.  Dynamics of soil organic carbon mineralization and C fractions in paddy soil on application of rice husk biochar , 2018, Biomass and Bioenergy.

[39]  W. Guo,et al.  Differential responses of carbon‐degrading enzyme activities to warming: Implications for soil respiration , 2018, Global change biology.

[40]  Yaqiong Wu,et al.  Decomposition of tree leaf litter and crop residues from ginkgo agroforestry systems in Eastern China: an in situ study , 2018, Journal of Soils and Sediments.

[41]  Zhongkui Luo,et al.  Effects of temperature, soil substrate, and microbial community on carbon mineralization across three climatically contrasting forest sites , 2017, Ecology and evolution.

[42]  Wenjuan Huang,et al.  Elevated moisture stimulates carbon loss from mineral soils by releasing protected organic matter , 2017, Nature Communications.

[43]  L. Vesterdal,et al.  Tree species and time since afforestation drive soil C and N mineralization on former cropland , 2017 .

[44]  X. Chang,et al.  Soil erosion-related dynamics of soil bacterial communities and microbial respiration , 2017 .

[45]  Enli Wang,et al.  Soil organic carbon dynamics jointly controlled by climate, carbon inputs, soil properties and soil carbon fractions , 2017, Global change biology.

[46]  F. Yimer,et al.  Can afforestation with Cupressus lusitanica restore soil C and N stocks depleted by crop cultivation to levels observed under native systems , 2017 .

[47]  S. Zlatanović,et al.  Fungal–bacterial dynamics and their contribution to terrigenous carbon turnover in relation to organic matter quality , 2016, The ISME Journal.

[48]  G. Bonan,et al.  Managing uncertainty in soil carbon feedbacks to climate change , 2016 .

[49]  R. Espejo,et al.  Aggregate size distribution and associated organic C and N under different tillage systems and Ca-amendment in a degraded Ultisol , 2016 .

[50]  Jinsheng Xie,et al.  Large amounts of easily decomposable carbon stored in subtropical forest subsoil are associated with r-strategy-dominated soil microbes , 2016 .

[51]  Qianxi Li,et al.  Microbial community mediated response of organic carbon mineralization to labile carbon and nitrogen addition in topsoil and subsoil , 2016, Biogeochemistry.

[52]  Qingkui Wang,et al.  Soil Moisture Alters the Response of Soil Organic Carbon Mineralization to Litter Addition , 2016, Ecosystems.

[53]  I. Bertrand,et al.  Aboveground litter quality is a better predictor than belowground microbial communities when estimating carbon mineralization along a land-use gradient , 2016 .

[54]  O. Sun,et al.  Differential controls on soil carbon density and mineralization among contrasting forest types in a temperate forest ecosystem , 2016, Scientific Reports.

[55]  O. Mathieu,et al.  Shifts in microbial diversity through land use intensity as drivers of carbon mineralization in soil , 2015 .

[56]  Shirong Liu,et al.  Relating microbial community structure to functioning in forest soil organic carbon transformation and turnover , 2014, Ecology and evolution.

[57]  Roland Hiederer,et al.  Global soil carbon: understanding and managing the largest terrestrial carbon pool , 2014 .

[58]  Jingyun Fang,et al.  Temperature and substrate availability regulate soil respiration in the tropical mountain rainforests, Hainan Island, China , 2013 .

[59]  Xingliang Xu,et al.  Competition between roots and microorganisms for nitrogen: mechanisms and ecological relevance. , 2013, The New phytologist.

[60]  Quanqin Shao,et al.  Carbon sequestration by forestation across China: Past, present, and future , 2012 .

[61]  D. Manning,et al.  Persistence of soil organic matter as an ecosystem property , 2011, Nature.

[62]  A. Don,et al.  Impact of tropical land‐use change on soil organic carbon stocks – a meta‐analysis , 2011 .

[63]  F. Han,et al.  Organic C and N mineralization as affected by dissolved organic matter in paddy soils of subtropical China , 2010 .

[64]  C. Huguet,et al.  Factors regulating carbon mineralization in the surface and subsurface soils of Pyrenean mountain grasslands , 2008 .

[65]  Y. Kuzyakov,et al.  Mechanisms of real and apparent priming effects and their dependence on soil microbial biomass and community structure: critical review , 2008, Biology and Fertility of Soils.

[66]  P. Nair,et al.  Carbon sequestration: An underexploited environmental benefit of agroforestry systems , 2004, Agroforestry Systems.

[67]  T. Letcher Why do we have global warming? , 2019, Managing Global Warming.

[68]  N. Nakicenovic,et al.  Biophysical and economic limits to negative CO2 emissions , 2016 .

[69]  Axel Don,et al.  Sensitivity of soil organic carbon stocks and fractions to different land-use changes across Europe , 2013 .

[70]  Hilde van der Togt,et al.  Publisher's Note , 2003, J. Netw. Comput. Appl..

[71]  R. Dudal,et al.  World Reference Base For Soil Resources , 1994 .

[72]  E. Pérez-Cardiel,et al.  UvA-DARE (Digital Academic Repository) Effects of secondary succession and afforestation practices on soil properties after cropland abandonment in humid Mediterranean mountain areas , 2022 .