Changes in profile distribution and chemical properties of natural nanoparticles in paddy soils as affected by long-term rice cultivation

[1]  K. Hayano,et al.  Long-term submergence of non-methanogenic oxic upland field soils helps to develop the methanogenic archaeal community as revealed by pot and field experiments , 2020 .

[2]  B. Hungate,et al.  Lower‐than‐expected CH4 emissions from rice paddies with rising CO2 concentrations , 2020, Global change biology.

[3]  Q. Hussain,et al.  Distribution of methane production and methanogenic archaeal community structure across soil particle size fractions along a rice chronosequence , 2019, Journal of Soil and Water Conservation.

[4]  G. Guggenberger,et al.  Distinct pattern of nitrogen functional gene abundances in top- and subsoils along a 120,000-year ecosystem development gradient , 2019, Soil Biology and Biochemistry.

[5]  Fei Liu,et al.  Sorption of pentachlorophenol and phenanthrene by humic acid-coated hematite nanoparticles. , 2019, Environmental pollution.

[6]  Shuo Wang,et al.  Heteroaggregation of soil particulate organic matter and biogenic selenium nanoparticles for remediation of elemental mercury contamination. , 2019, Chemosphere.

[7]  Michael F. Hochella,et al.  Natural, incidental, and engineered nanomaterials and their impacts on the Earth system , 2019, Science.

[8]  Fei Liu,et al.  Co-transport of phenanthrene and pentachlorophenol by natural soil nanoparticles through saturated sand columns. , 2019, Environmental pollution.

[9]  Hua Xu,et al.  Effects of Straw Incorporation Methods on Nitrous Oxide and Methane Emissions from a Wheat-Rice Rotation System , 2017, Pedosphere.

[10]  W. R. Whalley,et al.  Shrinkage Characteristics of Lime Concretion Black Soil as Affected by Biochar Amendment , 2018, Pedosphere.

[11]  P. Brookes,et al.  Differences in transport behavior of natural soil colloids of contrasting sizes from nanometer to micron and the environmental implications. , 2018, The Science of the total environment.

[12]  J. Chun,et al.  Effect of chemical and physical heterogeneities on colloid-facilitated cesium transport. , 2018, Journal of contaminant hydrology.

[13]  M. Jalali,et al.  Heavy metal release from some industrial wastes: influence of organic and inorganic acids, clay minerals, and nanoparticles. , 2018 .

[14]  Y. Kuzyakov,et al.  Rice rhizodeposits affect organic matter priming in paddy soil: The role of N fertilization and plant growth for enzyme activities, CO 2 and CH 4 emissions , 2018 .

[15]  F. Wang,et al.  Effects of biochar on dechlorination of hexachlorobenzene and the bacterial community in paddy soil. , 2017, Chemosphere.

[16]  C. Pan,et al.  Local human activities overwhelm decreased sediment supply from the Changjiang River: Continued rapid accumulation in the Hangzhou Bay-Qiantang Estuary system , 2017 .

[17]  Zhaoxia Dai,et al.  Evaluation of ferrolysis in arsenate adsorption on the paddy soil derived from an Oxisol. , 2017, Chemosphere.

[18]  Qiaoyi Huang,et al.  Influence of rice cultivation on the abundance and fractionation of Fe, Mn, Zn, Cu, and Al in acid sulfate paddy soils in the Pearl River Delta , 2017 .

[19]  Yanji Jiang,et al.  Transport of natural soil nanoparticles in saturated porous media: effects of pH and ionic strength , 2017 .

[20]  P. Brookes,et al.  Evaluation of the stability of soil nanoparticles: the effect of natural organic matter in electrolyte solutions , 2017 .

[21]  C. Chrysikopoulos,et al.  Heteroaggregation of graphene oxide nanoparticles and kaolinite colloids. , 2016, The Science of the total environment.

[22]  Xiangyu Tang,et al.  A field study of colloid transport in surface and subsurface flows , 2016 .

[23]  S. Mooney,et al.  Effects of long-term inorganic and organic fertilizations on the soil micro and macro structures of rice paddies , 2016 .

[24]  Dale J. Hoff,et al.  Impact of natural organic matter on particle behavior and phototoxicity of titanium dioxide nanoparticles. , 2016, The Science of the total environment.

[25]  Zhenli He,et al.  Natural Nanoparticles: Implications for Environment and Human Health , 2015 .

[26]  Michael F. Hochella,et al.  Nanotechnology: nature's gift or scientists' brainchild? , 2015 .

[27]  Gan Zhang,et al.  The use of chronosequences in studies of paddy soil evolution: A review , 2015 .

[28]  J. Labille,et al.  Aggregation and Dispersion Behavior in the 0‐ to 2‐ µm Fraction of Luvisols , 2015 .

[29]  Peifang Wang,et al.  Effects of pH and natural organic matter (NOM) on the adsorptive removal of CuO nanoparticles by periphyton , 2015, Environmental Science and Pollution Research.

[30]  Gan Zhang,et al.  Pedogenetic evolution of clay minerals and agricultural implications in three paddy soil chronosequences of south China derived from different parent materials , 2015, Journal of Soils and Sediments.

[31]  I. Kögel‐Knabner,et al.  Organic carbon accumulation on soil mineral surfaces in paddy soils derived from tidal wetlands , 2014 .

[32]  M. Schloter,et al.  Accelerated soil formation due to paddy management on marshlands (Zhejiang Province, China) , 2014 .

[33]  Y. Kuzyakov,et al.  Sorption affects amino acid pathways in soil: Implications from position-specific labeling of alanine , 2014 .

[34]  P. Brookes,et al.  Aggregation kinetics of natural soil nanoparticles in different electrolytes , 2014 .

[35]  Zhenli He,et al.  A new method for separation, characterization, and quantification of natural nanoparticles from soils , 2014, Journal of Nanoparticle Research.

[36]  I. Kögel‐Knabner,et al.  Management-induced organic carbon accumulation in paddy soils: The role of organo-mineral associations , 2013 .

[37]  Jianming Xu,et al.  Extraction and characterization of natural soil nanoparticles from Chinese soils , 2012 .

[38]  Jisheng Zhang,et al.  Numerical simulation of the tidal flow and suspended sediment transport in the Qiantang Estuary , 2012 .

[39]  P. Schjønning,et al.  Colloid Release from Soil Aggregates: Application of Laser Diffraction , 2012 .

[40]  Gan‐Lin Zhang,et al.  Soil characteristic response times and pedogenic thresholds during the 1000-year evolution of a paddy soil chronosequence , 2011 .

[41]  L. Cang,et al.  Transport and re-entrainment of soil colloids in saturated packed column: effects of pH and ionic strength , 2011 .

[42]  Anònim Anònim Keys to Soil Taxonomy , 2010 .

[43]  Dongfeng Xie,et al.  Modeling the tidal channel morphodynamics in a macro-tidal embayment, Hangzhou Bay, China. , 2009 .

[44]  Mathieu Bastian,et al.  Gephi: An Open Source Software for Exploring and Manipulating Networks , 2009, ICWSM.

[45]  Guodong Yuan,et al.  Nanoparticles in the Soil Environment , 2008 .

[46]  D. Sparks,et al.  Nanominerals, Mineral Nanoparticles, and Earth Systems , 2008, Science.

[47]  Hua Zhang,et al.  Colloid mobilization and arsenite transport in soil columns: effect of ionic strength. , 2007, Journal of environmental quality.

[48]  E. Tombácz,et al.  Colloidal behavior of aqueous montmorillonite suspensions: The specific role of pH in the presence of indifferent electrolytes , 2004 .

[49]  Navin Ramankutty,et al.  Geographic distribution of major crops across the world , 2004 .

[50]  Gan Zhang,et al.  Pedogenic evolution of paddy soils in different soil landscapes , 2003 .

[51]  K. Sahrawat Organic matter accumulation in submerged soils , 2003 .

[52]  J. Rhoades,et al.  Effect of Low Electrolyte Concentration on Clay Dispersion and Hydraulic Conductivity of a Sodic Soil1 , 1981 .