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1. Isolation, identification and characterization of Bacillus amyloli.. [3305]
2. 滨海潮滩土壤中微塑料的分离及其表面微观特征 [2259]
3. 环境中微塑料研究进展与展望 [1831]
4. Effective uptake of submicrometre plastics by crop plants via a cr.. [1278]
5. 重视海岸及海洋微塑料污染加强防治科技监管研究工作 [1087]
6. Reductive dechlorination of polychlorinated biphenyls is coupled t.. [1087]
7. 土壤环境中微塑料污染:来源、过程及风险 [988]
8. Characteristics and distribution of microplastics in the coastal m.. [912]
9. 一种微颗粒塑料的连续流动分离浮选装置及方法 [858]
10. pH、离子强度及电解质种类对纳米氧化锌聚集和溶解的影响 [857]
11. Stabilizing effects on a Cd polluted coastal wetland soil using ca.. [814]
12. Characteristics of cadmium uptake and membrane transport in roots .. [808]
13. Phylogenetic beta diversity in bacterial assemblages across ecosys.. [794]
14. Levels, distributions and sources of veterinary antibiotics in the.. [758]
15. Sources and fate of organic carbon and nitrogen from land to ocean.. [746]
16. Abundance and morphology of microplastics in an agricultural soil .. [737]
17. 黄河三角洲内陆到潮滩土壤中碳、氮元素的梯度分布规律 [720]
18. Characteristics of residual organochlorine pesticides in soils und.. [717]
19. Microplastics in an agricultural soil following repeated applicati.. [696]
20. Biochar and bacteria inoculated biochar enhanced Cd and Cu immobil.. [672]
21. Biofilm formation and its influences on the properties of micropla.. [655]
22. Facilitated transport of titanium dioxide nanoparticles by humic s.. [637]
23. Distribution of heavy metals in soils of the Yellow River Delta: c.. [633]
24. 环渤海海岸大气微塑料污染时空分布特征与表面形貌 [621]
25. Black Carbon Contributes Substantially to Allochthonous Carbon Sto.. [614]
26. Limited Cu(II) binding to biochar DOM: Evidence from C K-edge NEXA.. [605]
27. Fabrication, characterization and evaluation of mesoporous activat.. [603]
28. PATHWAYS OF ROOT UPTAKE AND MEMBRANE TRANSPORT OF CD2+ IN THE ZINC.. [597]
29. 污染场地修复决策支持系统的设计与实现 [591]
30. Fenton法和类Fenton法降解土壤中的二苯砷酸 [580]
31. Occurrence of red clay horizon in soil profiles of the Yellow Rive.. [572]
32. Solid-solution partitioning and thionation of diphenylarsinic acid.. [569]
33. Phytotoxicity of ZnO nanoparticles and the released Zn(II) ion to .. [566]
34. Stocks and losses of soil organic carbon from Chinese vegetated co.. [560]
35. Carbon accumulation in the red clay layer of the subsoil in a majo.. [557]
36. Structural and Functional Characteristics of Microplastic Associat.. [554]
37. 基于四通道色谱分离仪快速检测土壤中的低浓度多氯联苯 [515]
38. 土壤中二苯砷酸的吸附解吸、结合形态与代谢转化研究进展 [508]
39. Whole genome analysis of halotolerant and alkalotolerant plant gro.. [481]
40. Simultaneous determination of diphenylarsinic and phenylarsinic ac.. [468]
41. Time to Safeguard the Future Generations from the Omnipresent Micr.. [464]
42. Coupling between Nitrogen Fixation and Tetrachlorobiphenyl Dechlor.. [459]
43. Changes in organic carbon fractions and sources in deltaic topsoil.. [458]
44. Assessing the effect of pyrolysis temperature on the molecular pro.. [453]
45. 食用蔬菜能吸收和积累微塑料 [429]
46. Speciation and sorption structure of diphenylarsinic acid in soil .. [423]
47. 海洋和海岸环境微塑料污染与治理 [415]
48. Pyrolysis Temperature-Dependent Changes in the Characteristics of .. [415]
49. 长江、珠江三角洲地区土壤及其环境 [403]
50. 滨海湿地环境中微塑料表面性质及形貌变化 [400]
51. Lead smelting alters wheat flour heavy metal concentrations and he.. [396]
52. 耕地和草地土壤健康研究进展与展望 [393]
53. Soil accumulation and chemical fractions of Cu in a large and long.. [386]
54. Anthropogenic, Direct Pressures on Coastal Wetlands [381]
55. Mechanisms of mobility and retention of nano-TiO2 in acidic porous.. [373]
56. 一种假单胞菌及其应用 [372]
57. Inhibition effect of polyvinyl chloride on ferrihydrite reduction .. [361]
58. Spatial interpolation of orchard soil pH using soil type and plant.. [344]
59. 见微知著塑战速决--面向可持续发展的环境微塑料研究 [330]
60. 禾本科作物小麦能吸收和积累聚苯乙烯塑料微球 [327]
61. Magnetic characterization of distinct soil layers and its implicat.. [323]
62. 土壤污染毒性、基准与风险管理 [322]
63. 禾本科作物小麦能吸收和积累聚苯乙烯塑料微球 [309]
64. 低密度聚乙烯薄膜微塑料在黄河口海岸带环境中的风化特征 [309]
65. 土壤弹尾目动物测量计数装置 [303]
66. 重金属污染土壤的修复机制与技术发展 [303]
67. 有机污染土壤的修复机制与技术发展 [296]
68. 柠檬酸对污染棕壤中镉的去除优化及结合形态影响 [295]
69. Stability and transport of titanium dioxide nanoparticles in three.. [289]
70. 环渤海海岸大气微塑料污染时空分布特征与表面形貌 [289]
71. Geostatistical interpolation of available copper in orchard soil a.. [288]
72. 黄海桑沟湾潮滩塑料垃圾与微塑料组成和来源研究 [285]
73. 腐殖酸作用下酸性多孔介质中纳米TiO_2的迁移与滞留机制 [269]
74. 小节肢类土壤动物定量收集箱 [268]
75. 一种污染地修复决策支持与在线评估平台的构建方法 [263]
76. 海岸环境中两类软质微塑料表面生物膜DNA的提取方法比较与优化 [260]
77. 中国土壤环境质量基准与标准制定的理论和方法 [254]
78. 不同性质农田土壤中铜的可提取性与生物有效性及毒性 [246]
79. 中国土壤环境管理支撑技术体系研究 [234]
80. 一种小节肢类土壤动物分离定量收集装置 [228]
81. 黄海桑沟湾水体及沉积物中微塑料污染特征研究 [228]
82. 重视土壤中微塑料污染研究 防范生态与食物链风险 [226]
83. 滨海河口潮滩中微塑料的表面风化和成分变化 [223]
84. Sorption mechanisms of diphenylarsinic acid on ferrihydrite, goeth.. [208]
85. 土壤污染特征、过程与有效性 [200]
86. As, Cd, and Pb relative bioavailability in contaminated soils: Cou.. [196]
87. Occurrences of organophosphorus esters and phthalates in the micro.. [194]
88. 黄海桑沟湾潮滩塑料垃圾与微塑料组成和来源研究 [193]
89. Biofilm enhances the copper (II) adsorption on microplastic surfac.. [188]
90. Sequential washing and eluent regeneration with agricultural waste.. [185]
91. 滨海河口潮滩中微塑料的表面风化和成分变化研究 [159]
92. Feasibility of a combined solubilization and eluent drainage syste.. [158]
93. Quantitative tracing of uptake and transport of submicrometre plas.. [157]
94. 紫金牛叶杆菌RC6b 及其诱变菌株对二苯砷酸的降解特征 [156]
95. 滨海苹果园土壤碳氮空间分布及动态变化研究 [155]
96. A red clay layer in soils of the Yellow River Delta: Occurrence, p.. [149]
97. 渤海表层沉积物中的生物硅 [141]
98. 黄河三角洲土壤及其环境 [141]
99. 基于WebGIS的污染场地修复决策支持系统 [140]
100. The limited facilitating effect of dissolved organic matter extrac.. [138]

Downloads

1. Isolation, identification and characterization of Bacillus amyloli.. [1153]
2. 滨海潮滩土壤中微塑料的分离及其表面微观特征 [885]
3. Effective uptake of submicrometre plastics by crop plants via a cr.. [816]
4. 环境中微塑料研究进展与展望 [703]
5. Characteristics and distribution of microplastics in the coastal m.. [556]
6. Biofilm formation and its influences on the properties of micropla.. [486]
7. Reductive dechlorination of polychlorinated biphenyls is coupled t.. [418]
8. Characteristics of cadmium uptake and membrane transport in roots .. [401]
9. Abundance and morphology of microplastics in an agricultural soil .. [392]
10. Levels, distributions and sources of veterinary antibiotics in the.. [384]
11. Sources and fate of organic carbon and nitrogen from land to ocean.. [382]
12. 重视海岸及海洋微塑料污染加强防治科技监管研究工作 [373]
13. pH、离子强度及电解质种类对纳米氧化锌聚集和溶解的影响 [341]
14. Limited Cu(II) binding to biochar DOM: Evidence from C K-edge NEXA.. [330]
15. Black Carbon Contributes Substantially to Allochthonous Carbon Sto.. [328]
16. Stabilizing effects on a Cd polluted coastal wetland soil using ca.. [307]
17. Microplastics in an agricultural soil following repeated applicati.. [305]
18. Characteristics of residual organochlorine pesticides in soils und.. [301]
19. Structural and Functional Characteristics of Microplastic Associat.. [285]
20. Solid-solution partitioning and thionation of diphenylarsinic acid.. [283]
21. 污染场地修复决策支持系统的设计与实现 [266]
22. Carbon accumulation in the red clay layer of the subsoil in a majo.. [266]
23. Distribution of heavy metals in soils of the Yellow River Delta: c.. [265]
24. Phytotoxicity of ZnO nanoparticles and the released Zn(II) ion to .. [263]
25. Stocks and losses of soil organic carbon from Chinese vegetated co.. [262]
26. Facilitated transport of titanium dioxide nanoparticles by humic s.. [257]
27. Assessing the effect of pyrolysis temperature on the molecular pro.. [255]
28. Occurrence of red clay horizon in soil profiles of the Yellow Rive.. [249]
29. Fenton法和类Fenton法降解土壤中的二苯砷酸 [247]
30. Time to Safeguard the Future Generations from the Omnipresent Micr.. [242]
31. 土壤环境中微塑料污染:来源、过程及风险 [241]
32. Biochar and bacteria inoculated biochar enhanced Cd and Cu immobil.. [239]
33. Pyrolysis Temperature-Dependent Changes in the Characteristics of .. [237]
34. Whole genome analysis of halotolerant and alkalotolerant plant gro.. [230]
35. Simultaneous determination of diphenylarsinic and phenylarsinic ac.. [223]
36. 环渤海海岸大气微塑料污染时空分布特征与表面形貌 [201]
37. Speciation and sorption structure of diphenylarsinic acid in soil .. [199]
38. 土壤中二苯砷酸的吸附解吸、结合形态与代谢转化研究进展 [198]
39. Phylogenetic beta diversity in bacterial assemblages across ecosys.. [181]
40. 黄河三角洲内陆到潮滩土壤中碳、氮元素的梯度分布规律 [181]
41. PATHWAYS OF ROOT UPTAKE AND MEMBRANE TRANSPORT OF CD2+ IN THE ZINC.. [180]
42. Fabrication, characterization and evaluation of mesoporous activat.. [178]
43. Lead smelting alters wheat flour heavy metal concentrations and he.. [172]
44. Mechanisms of mobility and retention of nano-TiO2 in acidic porous.. [170]
45. 基于四通道色谱分离仪快速检测土壤中的低浓度多氯联苯 [166]
46. Changes in organic carbon fractions and sources in deltaic topsoil.. [155]
47. Anthropogenic, Direct Pressures on Coastal Wetlands [154]
48. 环渤海海岸大气微塑料污染时空分布特征与表面形貌 [143]
49. 耕地和草地土壤健康研究进展与展望 [143]
50. 腐殖酸作用下酸性多孔介质中纳米TiO_2的迁移与滞留机制 [138]
51. Spatial interpolation of orchard soil pH using soil type and plant.. [131]
52. Inhibition effect of polyvinyl chloride on ferrihydrite reduction .. [129]
53. Stability and transport of titanium dioxide nanoparticles in three.. [129]
54. Soil accumulation and chemical fractions of Cu in a large and long.. [128]
55. 禾本科作物小麦能吸收和积累聚苯乙烯塑料微球 [125]
56. 禾本科作物小麦能吸收和积累聚苯乙烯塑料微球 [122]
57. 低密度聚乙烯薄膜微塑料在黄河口海岸带环境中的风化特征 [120]
58. 柠檬酸对污染棕壤中镉的去除优化及结合形态影响 [118]
59. 见微知著塑战速决--面向可持续发展的环境微塑料研究 [118]
60. 不同性质农田土壤中铜的可提取性与生物有效性及毒性 [108]
61. 滨海湿地环境中微塑料表面性质及形貌变化 [97]
62. 黄海桑沟湾潮滩塑料垃圾与微塑料组成和来源研究 [89]
63. 黄海桑沟湾潮滩塑料垃圾与微塑料组成和来源研究 [89]