模拟盐水入侵及Fe(III)浓度增强对河口感潮淡水沼泽湿地土壤反硝化速率及理化特征的影响
|
摘要
以闽江河口塔礁洲感潮淡水野慈姑(Sagittaria trifolia Linn.)湿地为研究对象,于2016年2、4、7和9月每月均在连续2个小潮日内向研究样地施加人造海水和Fe(OH)_3溶液,研究短期的盐水入侵及Fe(III)浓度增强对河口感潮淡水湿地土壤反硝化速率及理化特征的影响.结果表明,短期的盐水入侵、Fe(III)浓度增强对河口感潮淡水沼泽湿地土壤反硝化速率的影响不显著,然而,盐水和Fe(III)共同施加会显著提高湿地土壤反硝化速率,与对照(CK)相比,盐水和Fe(III)共同施加可使土壤反硝化速率提高270.9%.盐水入侵、盐水和Fe(III)共同施加均可显著提高湿地土壤、间隙水的电导率及Cl~-、SO_4~(2-)的含量;Fe(III)浓度增强可显著降低土壤和间隙水pH值,同时显著提高土壤三价铁含量.
The effects of short-term saltwater intrusion and Fe(III) amendament on the soil denitrification rates and soil environmental parameters of the tidal freshwater marsh dominated by Sagittaria trifolia in the Tajiaozhou of the Min River estuary were determined by the in situ additions of artificial sea salt and Fe(III) solution in continuous two neap tide days in February, April, July and September 2016. The results showed that the simulated short-term saltwater intrusion coupled with Fe(III) input significantly promoted the soil denitrification rates, and compared with the control treatments, the denitrification rate increased 270.9%, however, the soil denitrification rates did not significantly changed with the treatments of saltwater intrusion, and Fe(III) increase alone. The treatments of saltwater intrusion, and saltwater intrusion coupled with Fe(III) input significantly increased conductivity, the pore water SO_4~(2-) and Cl~- concentrations; and the Fe(III) amendament significantly decreased pH, and significantly increased soil Fe(III) contents.
The effects of short-term saltwater intrusion and Fe(III) amendament on the soil denitrification rates and soil environmental parameters of the tidal freshwater marsh dominated by Sagittaria trifolia in the Tajiaozhou of the Min River estuary were determined by the in situ additions of artificial sea salt and Fe(III) solution in continuous two neap tide days in February, April, July and September 2016. The results showed that the simulated short-term saltwater intrusion coupled with Fe(III) input significantly promoted the soil denitrification rates, and compared with the control treatments, the denitrification rate increased 270.9%, however, the soil denitrification rates did not significantly changed with the treatments of saltwater intrusion, and Fe(III) increase alone. The treatments of saltwater intrusion, and saltwater intrusion coupled with Fe(III) input significantly increased conductivity, the pore water SO_4~(2-) and Cl~- concentrations; and the Fe(III) amendament significantly decreased pH, and significantly increased soil Fe(III) contents.
引文
Allyson L,Bullock Ariana E,Sutton-Grier J,et al.2013.Anaerobic metabolism in tidal freshwater wetlands:III.Temperature regulation of iron cycling[J]. Estuaries and Coasts,36(3):482-490
白军红,王庆改.2003.中国湿地生态威胁及其对策[J].水土保持研究,10(4):247-249
Ballantine K A,Groffman P M,Lehmann J,et al.2014.Stimulating nitrate removal processes of restored setlands[J].Environmental Science & Technology,48(13):7365-7373
Bernhard A E,Donn T,Giblin A E,et al.2005.Loss of diversity of ammonia-oxidizing bacteria correlates with increasing salinity in an estuary system[J].Environmental Microbiology,7(9):1289-1297
Carretero S, Rapaglia J,Bokuniewicz H, et al.2013.Impact of sea-level rise on saltwater intrusion length into the coastal aquifer,Partido de La Costa,Argentina[J].Continental Shelf Research,62(4):62-70
Chambers L G,Reddy K R,Osborne T Z.2011.Short-term response of carbon cycling to salinity pulses in a freshwater wetland[J].Soil Science Society of America Journal,75(5):2000-2007
陈娜,廖敏,张楠,等.2014.Fe2+对水稻生长及土壤微生物活性的影响[J].植物营养与肥料学报,20(3):651-660
Clément J C,Shrestha J,Ehrenfeld J G,et al.2005.Ammonium oxidation coupled to dissimilatory reduction of iron under anaerobic conditions in wetland soils[J].Soil Biology & Biochemistry,37(12):2323-2328
Deutsch B,Forster S,Wilhelm M,et al.2010.Denitrification in sediments as a major nitrogen sink in the Baltic Sea:an extrapolation using sediment characteristics[J].Biogeosciences Discussions,7(10):3259-3271
Edwards L,Küsel K,Drake H,et al.2007.Electron flow in acidic subsurface sediments co-contaminated with nitrate and uranium[J].Geochimica Et Cosmochimica Acta,71(3):643-654
Fear J M,Thompson S P,Gallo T E,et al.2005.Denitrification rates measured along a salinity gradient in the eutrophic Neuse River estuary,North Carolina,USA[J].Estuaries,28(4):608-619
付炳炳,潘建新,马景德,等.2018.采用含硫铁化学污泥作为反硝化电子供体进行焦化废水中总氮深度去除[J].环境科学,39(7):1-13
高建华,欧维新,杨桂山.2004.潮滩湿地N、P生物地球化学过程研究[J].湿地科学,2(3):220-227
Hou L J, Liu M, Xu S Y, et al.2007.The effects of semi-lunar spring and neap tidal change on nitrification, denitrification and N2O vertical distribution in the intertidal sediments of the Yangtze estuary,China[J].Estuarine, Coastal and Shelf Science,73(3): 607-616
胡敏杰,邹芳芳,仝川,等.2014.闽江河口湿地沉积物生源要素含量及生态风险评价[J].水土保持学报,28(3):119-124
胡松,朱建荣,傅得健,等.2003.河口环流和盐水入侵Ⅱ—径流量和海平面上升的影响[J].青岛海洋大学学报(自然科学版),33(3):337-342
Hu Y,Wang L,Tang Y,et al.2014.Variability in soil microbial community and activity between coastal and riparian wetlands in the Yangtze River estuary - Potential impacts on carbon sequestration[J].Soil Biology & Biochemistry,70:221-228
Huang B,Yu K,Gambrell R P.2009.Effects of ferric iron reduction and regeneration on nitrous oxide and methane emissions in a rice soil[J].Chemosphere,74(4):481-486
黄文丹.2013.长江河口水体有机胶体含量、来源及其对重金属行为影响的研究[D].上海:华东师范大学
Hou L J,Liu M,Xu S Y,et al.2007.The effects of semi-lunar spring and neap tidal change on nitrification,denitrification and N2O vertical distribution in the intertidal sediments of the Yangtze estuary,China[J].Estuarine Coastal & Shelf Science,73(3):607-616
IPCC.2013.Climate Change 2013:The Physical Science Basis.Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change[M].United Kingdom and New York,NY,USA:Cambridge University Press
Katz A,Kaplan I R.1981.Heavy metals behavior in coastal sediments of southern California:a critical review and synthesis[J].Marine Chemistry,10(4):261-299
李浩,闫玉洁,谢慧君,等.2015.Fe3+对同步硝化反硝化过程氮元素迁移转化及N2O释放的影响[J].环境科学,36(4):1392-1398
李鹤.2011.东南沿海残积土地区降雨型滑坡预警预报体系的研究与应用[D].杭州:浙江大学
李家兵,张宝珠,朱雨晨,等.2017.闽江河口短叶茳芏群落湿地沉积物反硝化强度对盐度的响应[J].生态学报,37 (1):177-183
李家兵,张党玉,吴春山,等.2017.pH对闽江河口湿地沉积物氮素转化关键过程的影响[J].水土保持学报,31(1):272-278
李佳霖.2009.典型河口区沉积物的硝化和反硝化过程[D].青岛:中国海洋大学
李建兵,黄冠华.2008.盐分对粉壤土氮转化的影响[J].环境科学研究,21(5):98-103
刘晴晴,曾从盛,张林海,等.2016.氮输入条件下闽江河口沼泽土壤的反硝化速率[J].湿地科学,14(3):361-367
Magalhães C M, Joye S B, Moreira R M, et al. 2005. Effect of salinity and inorganic nitrogen concentrations on nitrification and denitrification rates in intertidal sediments and rocky biofilms of the Douro River estuary, Portugal[J]. Water Research,39(9): 1783-1794
Marton J M,Herbert E R,Craft C B.2012.Effects of salinity on denitrification and greenhouse gas production from laboratory-incubated tidal forest soils[J].Wetlands,32:347-357
Morrissey E M,Gillespie J L,Morina J C,et al.2014.Salinity affects microbial activity and soil organic matter content in tidal wetlands.[J].Global Change Biology,20(4):1351-1362
牟晓杰.2013.闽江河口湿地碳氮循环关键过程对氮输入的响应[D].长春:中国科学院东北地理与农业生态研究所
Nakata H,Yasufumi S,Takashi M A,et al.2003.Bioaccumulation and toxic potencies of polychlorinated biphenyls and polycyclic aromatic hydrocarbons in tidal flat and coastal ecosystems of the Ariake Sea,Japan[J].Environmental Science & Technology,37(16):3513-3521
Park W,Nam Y K,Lee M J,et al.2009.Anaerobic ammonia-oxidation coupled with Fe3+,reduction by an anaerobic culture from a piggery wastewater acclimated to NH+4/Fe3+,medium[J].Biotechnology & Bioprocess Engineering,14(5):680-685
裘诚.2014.长江河口盐水入侵对气候变化和重大工程的响应[D].上海:华东师范大学
Rysgaard S,Thastum P,Dalsgaard T,et al.1999.Effects of salinity on NH+4 adsorption capacity,nitrification,and denitrification in danish estuarine sediments[J].Estuaries,22(1):21-30
Seitzinger S P,Nielsen L P,Caffrey J,et al.1993.Denitrification measurements inaquatic sediments:a comparison of three methods[J].Biogeochemistry 23:147-167
Seitzinger S P,Spratt A K.1991.The effect of salinity on ammonium sorption in aquatic sediments:Implications for benthic nutrient recycling[J].Estuaries,14(2):167-174
Simas T,Nunes J P,Ferreira J G.2001.Effects of global climate change on coastal salt marshes[J].Ecological Modelling,139(1):1-15
孙东耀,仝川,陈坤龙,等.2017.台风“杜鹃”对闽江河口区沼泽土壤间隙水和潮水中营养盐含量的影响[J].湿地科学,15(6):809-817
仝川,黄佳芳,王维奇,等.2012.闽江口半咸水芦苇潮汐沼泽湿地甲烷动态[J].地理学报,67(9):1165-1180
童亮,刘涛.2017.浅析东南沿海地区花岗岩球状风化体发育特征及对桩基工程的影响[J].资源信息与工程,32(1):137-139,141
Wall L G,Tank J L,Royer T V,et al.2005.Spatial and temporal variability in sediment denitrification within an agriculturally influenced reservoir[J].Biogeochemistry 76:85-111
Wang D,Chen Z,Xu S,et al.2006.Denitrification in Chongming east tidal flat sediment,Yangtze estuary,China[J].Science in China,49(10):1090-1097
王树功,周永章,黎夏,等.2005.干扰对河口湿地生态系统的影响分析[J].中山大学学报(自然科学版),(1):107-111
Wang W,Sardans J,Lai D Y F,et al.2015.Effects of steel slag application on greenhouse gas emissions and crop yield over multiple growing seasons in a subtropical paddy field in China[J].Field Crops Research,171:146-156
王小红,杨智杰,刘小飞,等.2016.中亚热带山区土壤不同形态铁铝氧化物对团聚体稳定性的影响[J].生态学报,36(9):2588-2596
Wu S,Kuschk P,Wiessner A,et al.2013.Sulphur transformations in constructed wetlands for wastewater treatment:A review[J].Ecological Engineering,52(2):278-289.
吴晓燕.2007.黄河入海过程中重金属的变化特征研究[D].青岛:中国海洋大学
徐皓.2013.长江口营养盐的收支平衡及迁移模式[D].上海:华东师范大学
闫玉洁.2013.Fe3+对同步硝化反硝化污水处理过程中温室气体释放的影响[D].济南:山东大学
杨麒,李小明,曾光明,等.2004.同步硝化反硝化的形成机理及影响因素[J].环境科学与技术,27(3):102-104,120
Yang W H,Weber K A,Silver W L.2012.Nitrogen loss from soil through anaerobic ammonium oxidation coupled to iron reduction[J].Nature Geoscience,5(8):538-541
Yeh C C,Sinclair J B.2005.Effect of salinity and inorganic nitrogen concentrations on nitrification and denitrification rates in intertidal sediments and rocky biofilms of the Douro River estuary,Portugal[J].Water Research,39(9):1783-1794
Yu J B,Liu J S,Sun Z G,et al.2010.The fluxes and controlling factors of N2O and CH4,emissions from freshwater marsh in Northeast China[J].Science China Earth Sciences,53(5):700-709
Yu K C,Tsai L J,Chen S H,et al.2001.Correlation analyses on binding behavior of heavy metals with sediment matrices[J].Water Research,35(10):2417-2428
张林海,刘荣芳,仝川,等.2015.盐度对闽江河口淡水洲滩土壤潜在反硝化速率及脱氮效率的影响[J].湿地科学,13(5):528-534
张逸飞,刘小慧,杨平,等.2018.模拟SO【math123z】沉降对闽江口淡水感潮野慈姑湿地甲烷排放通量的影响[J].生态学报,38(13):1-8
张子川,杨平,仝川.2015.盐分对河口淡水、微咸水沼泽湿地土壤甲烷产生潜力的影响[J].生态学报,35(24):8075-8084
赵娜,李鹏飞,林德华,等.2010.炉渣对调节稻田土壤pH和盐度的有效性分析[J].亚热带农业研究,6(4):264-266
朱文凤,仝川,罗敏,等.模拟Fe(III)和盐水输入对闽江河口潮汐湿地沉积物及间隙水Fe和S形态和含量的影响[J].环境科学学报,DOI:10.13671/j.hjkxxb.2018.0214
朱永官,王晓辉,杨小茹,等.2014.农田土壤N2O产生的关键微生物过程及减排措施[J].环境科学,35(2):792-800
邹航.2014.珠江河口湿地沉积物和上覆水中氮的迁移转化过程研究[D].广州:暨南大学
白军红,王庆改.2003.中国湿地生态威胁及其对策[J].水土保持研究,10(4):247-249
Ballantine K A,Groffman P M,Lehmann J,et al.2014.Stimulating nitrate removal processes of restored setlands[J].Environmental Science & Technology,48(13):7365-7373
Bernhard A E,Donn T,Giblin A E,et al.2005.Loss of diversity of ammonia-oxidizing bacteria correlates with increasing salinity in an estuary system[J].Environmental Microbiology,7(9):1289-1297
Carretero S, Rapaglia J,Bokuniewicz H, et al.2013.Impact of sea-level rise on saltwater intrusion length into the coastal aquifer,Partido de La Costa,Argentina[J].Continental Shelf Research,62(4):62-70
Chambers L G,Reddy K R,Osborne T Z.2011.Short-term response of carbon cycling to salinity pulses in a freshwater wetland[J].Soil Science Society of America Journal,75(5):2000-2007
陈娜,廖敏,张楠,等.2014.Fe2+对水稻生长及土壤微生物活性的影响[J].植物营养与肥料学报,20(3):651-660
Clément J C,Shrestha J,Ehrenfeld J G,et al.2005.Ammonium oxidation coupled to dissimilatory reduction of iron under anaerobic conditions in wetland soils[J].Soil Biology & Biochemistry,37(12):2323-2328
Deutsch B,Forster S,Wilhelm M,et al.2010.Denitrification in sediments as a major nitrogen sink in the Baltic Sea:an extrapolation using sediment characteristics[J].Biogeosciences Discussions,7(10):3259-3271
Edwards L,Küsel K,Drake H,et al.2007.Electron flow in acidic subsurface sediments co-contaminated with nitrate and uranium[J].Geochimica Et Cosmochimica Acta,71(3):643-654
Fear J M,Thompson S P,Gallo T E,et al.2005.Denitrification rates measured along a salinity gradient in the eutrophic Neuse River estuary,North Carolina,USA[J].Estuaries,28(4):608-619
付炳炳,潘建新,马景德,等.2018.采用含硫铁化学污泥作为反硝化电子供体进行焦化废水中总氮深度去除[J].环境科学,39(7):1-13
高建华,欧维新,杨桂山.2004.潮滩湿地N、P生物地球化学过程研究[J].湿地科学,2(3):220-227
Hou L J, Liu M, Xu S Y, et al.2007.The effects of semi-lunar spring and neap tidal change on nitrification, denitrification and N2O vertical distribution in the intertidal sediments of the Yangtze estuary,China[J].Estuarine, Coastal and Shelf Science,73(3): 607-616
胡敏杰,邹芳芳,仝川,等.2014.闽江河口湿地沉积物生源要素含量及生态风险评价[J].水土保持学报,28(3):119-124
胡松,朱建荣,傅得健,等.2003.河口环流和盐水入侵Ⅱ—径流量和海平面上升的影响[J].青岛海洋大学学报(自然科学版),33(3):337-342
Hu Y,Wang L,Tang Y,et al.2014.Variability in soil microbial community and activity between coastal and riparian wetlands in the Yangtze River estuary - Potential impacts on carbon sequestration[J].Soil Biology & Biochemistry,70:221-228
Huang B,Yu K,Gambrell R P.2009.Effects of ferric iron reduction and regeneration on nitrous oxide and methane emissions in a rice soil[J].Chemosphere,74(4):481-486
黄文丹.2013.长江河口水体有机胶体含量、来源及其对重金属行为影响的研究[D].上海:华东师范大学
Hou L J,Liu M,Xu S Y,et al.2007.The effects of semi-lunar spring and neap tidal change on nitrification,denitrification and N2O vertical distribution in the intertidal sediments of the Yangtze estuary,China[J].Estuarine Coastal & Shelf Science,73(3):607-616
IPCC.2013.Climate Change 2013:The Physical Science Basis.Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change[M].United Kingdom and New York,NY,USA:Cambridge University Press
Katz A,Kaplan I R.1981.Heavy metals behavior in coastal sediments of southern California:a critical review and synthesis[J].Marine Chemistry,10(4):261-299
李浩,闫玉洁,谢慧君,等.2015.Fe3+对同步硝化反硝化过程氮元素迁移转化及N2O释放的影响[J].环境科学,36(4):1392-1398
李鹤.2011.东南沿海残积土地区降雨型滑坡预警预报体系的研究与应用[D].杭州:浙江大学
李家兵,张宝珠,朱雨晨,等.2017.闽江河口短叶茳芏群落湿地沉积物反硝化强度对盐度的响应[J].生态学报,37 (1):177-183
李家兵,张党玉,吴春山,等.2017.pH对闽江河口湿地沉积物氮素转化关键过程的影响[J].水土保持学报,31(1):272-278
李佳霖.2009.典型河口区沉积物的硝化和反硝化过程[D].青岛:中国海洋大学
李建兵,黄冠华.2008.盐分对粉壤土氮转化的影响[J].环境科学研究,21(5):98-103
刘晴晴,曾从盛,张林海,等.2016.氮输入条件下闽江河口沼泽土壤的反硝化速率[J].湿地科学,14(3):361-367
Magalhães C M, Joye S B, Moreira R M, et al. 2005. Effect of salinity and inorganic nitrogen concentrations on nitrification and denitrification rates in intertidal sediments and rocky biofilms of the Douro River estuary, Portugal[J]. Water Research,39(9): 1783-1794
Marton J M,Herbert E R,Craft C B.2012.Effects of salinity on denitrification and greenhouse gas production from laboratory-incubated tidal forest soils[J].Wetlands,32:347-357
Morrissey E M,Gillespie J L,Morina J C,et al.2014.Salinity affects microbial activity and soil organic matter content in tidal wetlands.[J].Global Change Biology,20(4):1351-1362
牟晓杰.2013.闽江河口湿地碳氮循环关键过程对氮输入的响应[D].长春:中国科学院东北地理与农业生态研究所
Nakata H,Yasufumi S,Takashi M A,et al.2003.Bioaccumulation and toxic potencies of polychlorinated biphenyls and polycyclic aromatic hydrocarbons in tidal flat and coastal ecosystems of the Ariake Sea,Japan[J].Environmental Science & Technology,37(16):3513-3521
Park W,Nam Y K,Lee M J,et al.2009.Anaerobic ammonia-oxidation coupled with Fe3+,reduction by an anaerobic culture from a piggery wastewater acclimated to NH+4/Fe3+,medium[J].Biotechnology & Bioprocess Engineering,14(5):680-685
裘诚.2014.长江河口盐水入侵对气候变化和重大工程的响应[D].上海:华东师范大学
Rysgaard S,Thastum P,Dalsgaard T,et al.1999.Effects of salinity on NH+4 adsorption capacity,nitrification,and denitrification in danish estuarine sediments[J].Estuaries,22(1):21-30
Seitzinger S P,Nielsen L P,Caffrey J,et al.1993.Denitrification measurements inaquatic sediments:a comparison of three methods[J].Biogeochemistry 23:147-167
Seitzinger S P,Spratt A K.1991.The effect of salinity on ammonium sorption in aquatic sediments:Implications for benthic nutrient recycling[J].Estuaries,14(2):167-174
Simas T,Nunes J P,Ferreira J G.2001.Effects of global climate change on coastal salt marshes[J].Ecological Modelling,139(1):1-15
孙东耀,仝川,陈坤龙,等.2017.台风“杜鹃”对闽江河口区沼泽土壤间隙水和潮水中营养盐含量的影响[J].湿地科学,15(6):809-817
仝川,黄佳芳,王维奇,等.2012.闽江口半咸水芦苇潮汐沼泽湿地甲烷动态[J].地理学报,67(9):1165-1180
童亮,刘涛.2017.浅析东南沿海地区花岗岩球状风化体发育特征及对桩基工程的影响[J].资源信息与工程,32(1):137-139,141
Wall L G,Tank J L,Royer T V,et al.2005.Spatial and temporal variability in sediment denitrification within an agriculturally influenced reservoir[J].Biogeochemistry 76:85-111
Wang D,Chen Z,Xu S,et al.2006.Denitrification in Chongming east tidal flat sediment,Yangtze estuary,China[J].Science in China,49(10):1090-1097
王树功,周永章,黎夏,等.2005.干扰对河口湿地生态系统的影响分析[J].中山大学学报(自然科学版),(1):107-111
Wang W,Sardans J,Lai D Y F,et al.2015.Effects of steel slag application on greenhouse gas emissions and crop yield over multiple growing seasons in a subtropical paddy field in China[J].Field Crops Research,171:146-156
王小红,杨智杰,刘小飞,等.2016.中亚热带山区土壤不同形态铁铝氧化物对团聚体稳定性的影响[J].生态学报,36(9):2588-2596
Wu S,Kuschk P,Wiessner A,et al.2013.Sulphur transformations in constructed wetlands for wastewater treatment:A review[J].Ecological Engineering,52(2):278-289.
吴晓燕.2007.黄河入海过程中重金属的变化特征研究[D].青岛:中国海洋大学
徐皓.2013.长江口营养盐的收支平衡及迁移模式[D].上海:华东师范大学
闫玉洁.2013.Fe3+对同步硝化反硝化污水处理过程中温室气体释放的影响[D].济南:山东大学
杨麒,李小明,曾光明,等.2004.同步硝化反硝化的形成机理及影响因素[J].环境科学与技术,27(3):102-104,120
Yang W H,Weber K A,Silver W L.2012.Nitrogen loss from soil through anaerobic ammonium oxidation coupled to iron reduction[J].Nature Geoscience,5(8):538-541
Yeh C C,Sinclair J B.2005.Effect of salinity and inorganic nitrogen concentrations on nitrification and denitrification rates in intertidal sediments and rocky biofilms of the Douro River estuary,Portugal[J].Water Research,39(9):1783-1794
Yu J B,Liu J S,Sun Z G,et al.2010.The fluxes and controlling factors of N2O and CH4,emissions from freshwater marsh in Northeast China[J].Science China Earth Sciences,53(5):700-709
Yu K C,Tsai L J,Chen S H,et al.2001.Correlation analyses on binding behavior of heavy metals with sediment matrices[J].Water Research,35(10):2417-2428
张林海,刘荣芳,仝川,等.2015.盐度对闽江河口淡水洲滩土壤潜在反硝化速率及脱氮效率的影响[J].湿地科学,13(5):528-534
张逸飞,刘小慧,杨平,等.2018.模拟SO【math123z】沉降对闽江口淡水感潮野慈姑湿地甲烷排放通量的影响[J].生态学报,38(13):1-8
张子川,杨平,仝川.2015.盐分对河口淡水、微咸水沼泽湿地土壤甲烷产生潜力的影响[J].生态学报,35(24):8075-8084
赵娜,李鹏飞,林德华,等.2010.炉渣对调节稻田土壤pH和盐度的有效性分析[J].亚热带农业研究,6(4):264-266
朱文凤,仝川,罗敏,等.模拟Fe(III)和盐水输入对闽江河口潮汐湿地沉积物及间隙水Fe和S形态和含量的影响[J].环境科学学报,DOI:10.13671/j.hjkxxb.2018.0214
朱永官,王晓辉,杨小茹,等.2014.农田土壤N2O产生的关键微生物过程及减排措施[J].环境科学,35(2):792-800
邹航.2014.珠江河口湿地沉积物和上覆水中氮的迁移转化过程研究[D].广州:暨南大学
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |