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1. Stimulation of long-term ammonium nitrogen deposition on methanoge.. [1033]
2. In situ electrochemical synthesis of graphene-poly(arginine) compo.. [831]
3. Proteomics reveal biomethane production process induced by carbon .. [684]
4. 加强电微生物学研究持续利用海岸带新型微生物资源 [646]
5. Augmentation of chloramphenicol degradation by Geobacter-based bio.. [625]
6. Simultaneous intensification of direct acetate cleavage and CO2 re.. [536]
7. Methane production by acetate dismutation stimulated by Shewanella.. [521]
8. Methylobacter accounts for strong aerobic methane oxidation in the.. [508]
9. A practical soil management to improve soil quality by applying mi.. [500]
10. 固相萃取/气相色谱-质谱法测定海水中16种除草剂 [469]
11. Inhibition effect of polyvinyl chloride on ferrihydrite reduction .. [457]
12. 铁锰氧化物提高巴斯德梭菌电子输出率 [455]
13. Biochar promotes methane production during anaerobic digestion of .. [452]
14. The selective expression of carbonic anhydrase genes of Aspergillu.. [434]
15. Effect of Antibiotics on the Microbial Efficiency of Anaerobic Dig.. [419]
16. A potential contribution of a Fe(III)-rich red clay horizon to met.. [398]
17. Reductive degradation of chloramphenicol by Geobacter metallireduc.. [394]
18. A new insight into the strategy for methane production affected by.. [389]
19. Nano-Fe3O4 particles accelerating electromethanogenesis on an hour.. [387]
20. Promotion of methane production by magnetite via increasing acetog.. [385]
21. Biochar promotes methane production at high acetate concentrations.. [381]
22. 异化铁还原梭菌Clostridium bifermentans EZ-1产氢与电化学特性 [379]
23. Extraction of electrons by magnetite and ferrihydrite from hydroge.. [352]
24. A Global View of Gene Expression of Aspergillus nidulans on Respon.. [351]
25. Target-oriented recruitment of Clostridium to promote biohydrogen .. [351]
26. Carbon nanotubes accelerate acetoclastic methanogenesis: From pure.. [345]
27. Stimulation of ferrihydrite nanorods on fermentative hydrogen prod.. [342]
28. 含钾岩石微生物转化的分子机制及其碳汇效应 [329]
29. Impacts of the rhizosphere effect and plant species on organic car.. [323]
30. Rhizosphere processes induce changes in dissimilatory iron reducti.. [322]
31. Ferrihydrite Reduction Exclusively Stimulated Hydrogen Production .. [309]
32. Salt-tolerant plant moderates the effect of salinity on soil organ.. [285]
33. Production of biochar from crop residues and its application for a.. [279]
34. Insight into the Variability of the Nitrogen Isotope Composition o.. [274]
35. Progress in the production of hydrogen energy from food waste: A b.. [257]
36. Comparative transcriptomic insights into the mechanisms of electro.. [254]
37. Rapid removal of chloramphenicol via the synergy of Geobacter and .. [245]
38. Advanced catalysts and effect of operating parameters in ethanol d.. [233]
39. Advantage of conductive materials on interspecies electron transfe.. [229]
40. 设施种植模式对土壤细菌多样性及群落结构的影响 [227]
41. 铁锰氧化物提高巴斯德梭菌电子输出率 [219]
42. A critical review on the two-stage biohythane production and its v.. [219]
43. Production of hydrogen and value-added carbon materials by catalyt.. [214]
44. 含钾岩石微生物转化的分子机制及其碳汇效应 [212]
45. Alizarin-graphene nanocomposite for calibration-free and online pH.. [212]
46. Enhanced methane production by granular activated carbon: A review [196]
47. Inundation depth stimulates plant-mediated CH4 emissions by increa.. [192]
48. Production Potential of Greenhouse Gases Affected by Microplastics.. [183]
49. Iron Reduction Controls Carbon Mineralization in Aquaculture Shrim.. [172]
50. Increased Soil Aggregate Stability by Altering Contents and Chemic.. [141]
51. Methylobacter couples methane oxidation and N2O production in hypo.. [126]
52. Aquaculture drastically increases methane production by favoring a.. [112]
53. 海岸带蓝碳增汇:理念、技术与未来建议 [80]
54. Biomethane is produced by acetate cleavage, not direct interspecie.. [65]
55. Warming-dominated climate change impacts on soil organic carbon fr.. [62]
56. 一种高效定向富集分离产氢菌的方法 [50]
57. A review on pretreatment methods, photobioreactor design and metab.. [48]
58. 一种经济便捷的微生物辅助防火制剂 [43]
59. 多功能双酶梭菌及其应用 [40]
60. 一种调控厌氧污泥降解产乙酸和丁酸的方法 [36]
61. 一种提高产氢菌氢产量的方法 [34]
62. Climate and mineral accretion as drivers of mineral-associated and.. [15]
63. Moderate increase of precipitation stimulates CO2 produ.. [14]
64. 加强电微生物学研究 持续利用海岸带新型微生物资源 [1]

Downloads

1. Stimulation of long-term ammonium nitrogen deposition on methanoge.. [487]
2. In situ electrochemical synthesis of graphene-poly(arginine) compo.. [290]
3. A practical soil management to improve soil quality by applying mi.. [278]
4. Augmentation of chloramphenicol degradation by Geobacter-based bio.. [234]
5. Proteomics reveal biomethane production process induced by carbon .. [218]
6. Methylobacter accounts for strong aerobic methane oxidation in the.. [161]
7. Simultaneous intensification of direct acetate cleavage and CO2 re.. [148]
8. Methane production by acetate dismutation stimulated by Shewanella.. [142]
9. Inhibition effect of polyvinyl chloride on ferrihydrite reduction .. [129]
10. 加强电微生物学研究持续利用海岸带新型微生物资源 [127]
11. A new insight into the strategy for methane production affected by.. [125]
12. 铁锰氧化物提高巴斯德梭菌电子输出率 [124]
13. Reductive degradation of chloramphenicol by Geobacter metallireduc.. [120]
14. 固相萃取/气相色谱-质谱法测定海水中16种除草剂 [113]
15. Nano-Fe3O4 particles accelerating electromethanogenesis on an hour.. [112]
16. The selective expression of carbonic anhydrase genes of Aspergillu.. [110]
17. Stimulation of ferrihydrite nanorods on fermentative hydrogen prod.. [110]
18. Extraction of electrons by magnetite and ferrihydrite from hydroge.. [105]
19. Biochar promotes methane production at high acetate concentrations.. [102]
20. A potential contribution of a Fe(III)-rich red clay horizon to met.. [89]
21. 异化铁还原梭菌Clostridium bifermentans EZ-1产氢与电化学特性 [86]
22. Biochar promotes methane production during anaerobic digestion of .. [83]
23. A Global View of Gene Expression of Aspergillus nidulans on Respon.. [78]
24. Insight into the Variability of the Nitrogen Isotope Composition o.. [71]
25. Rhizosphere processes induce changes in dissimilatory iron reducti.. [69]
26. Target-oriented recruitment of Clostridium to promote biohydrogen .. [45]
27. Carbon nanotubes accelerate acetoclastic methanogenesis: From pure.. [44]
28. Ferrihydrite Reduction Exclusively Stimulated Hydrogen Production .. [44]
29. Impacts of the rhizosphere effect and plant species on organic car.. [42]
30. 含钾岩石微生物转化的分子机制及其碳汇效应 [35]
31. Effect of Antibiotics on the Microbial Efficiency of Anaerobic Dig.. [33]
32. 铁锰氧化物提高巴斯德梭菌电子输出率 [23]
33. 含钾岩石微生物转化的分子机制及其碳汇效应 [22]
34. Comparative transcriptomic insights into the mechanisms of electro.. [15]