N2O and CO2 emissions from South German arable soil after amendment of manures and composts

详细信息    查看全文

• 作者：Ambreen Shah ; Marc Lamers ; Thilo Streck
• 关键词：Organic residues ; N2O ; CO2 ; Arable soil
• 刊名：Environmental Earth Sciences
• 出版年：2016
• 出版时间：March 2016
• 年：2016
• 卷：75
• 期：5
• 全文大小：690 KB
• 参考文献：Alexander M (1977) Introduction to soil microbiology. Wiley, New York
  Andersen JK (2010) Composting of organic waste: quantification and assessment of greenhouse gas emissions. Dissertation, Environmental Engineering Department, Technical University of Denmark (DTU)
  Ano AO, Ubochi CI (2007) Neutralization of soil acidity by animal manures mechanism of reaction. Afr J Biotechnnol 6:364–368
  Baggs EM, Rees RM, Smith KA, Vinten AJA (2000) Nitrous oxide emission from soils after incorporating crop residues. Soil Use Manag 16:82–87CrossRef
  Baggs EM, Stevenson M, Pihlatie M, Regar A, Cook H, Cadisch G (2003) Nitrous oxide emissions following application of residues and fertilizer under zero and conventional tillage. Plant Soil 254:361–370CrossRef
  Bergsma TT, Robertson GP, Ostrom NE (2002) Influence of soil moisture and land use history on denitrification end-products. Environ Qual 31:711–717CrossRef
  Bernal MP, Alburquerque JA, Moral R (2009) Composting of animal manures and chemical criteria for compost maturity assessment. A review. Bioresour Technol 100:5444–5453CrossRef
  Biala J (2011) The benefits of using compost for mitigating climate change. A short report. Department of Environment, Climate Change and Water NSW
  BioAbfV (1998) Ordinance on the utilisation of bio-wastes on land used for agricultural and horticultural purposes 21 Sep 1998. (Federal Law Gazette BGBl. I p. 2955), amended by Article 5 of the Ordinance on the Implementation of the European Waste Catalogue of 10 December 2001 (Federal Law Gazette BGBl. I, p 3379)
  Boeckx P, Nieuland KV, Cleemput OV (2011) Short-term effect of tillage intensity on N2O and CO2 emissions. Agron Sustain Dev 31:453–461CrossRef
  Bot A, Benites J (2005) The importance of soil organic matter: key to drought-resistant soil and sustained food production. FAO SOILS BULLETIN, 80. Food and Agriculture Organization of the United Nations, Rome
  Cabrera ML, Chiang SC, Merka WC, Pancorbo OC, Thompson SA (1994) Nitrous oxide and carbon dioxide emissions from pelletized and non pelletized poultry litter incorporated into soil. Plant Soil 163:189–196CrossRef
  Cayuela ML, Kuikman PJ, Oenema OR, Bakker R, Groenige JW (2010) Bioenergy residues as soil amendments: climate-relevant C dynamics during decomposition. 19th world congress of soil science, soil solutions for a changing world, Brisbane, Australia. Published on DVD
  Danga BO, Mochoge B, Mugwe J, Getenga Z (2010) Soil properties effects and management of organic residues to improve C sequestration, reduce N losses and improve crop yields. Second RUFORUM Biennial Meeting 20–24 September, Entebbe, Uganda
  Deenik J (2006) Nitrogen mineralization potential in important agricultural soils of Hawai’i. Honolulu (HI): University of Hawaii. p 5 (Soil and Crop Management; SCM-15)
  Dennis A, Burke PE (2001) Dairy waste anaerobic digestion handbook. Environmental energy company. p 57
  Dong S, Shu H (2004) Sheep manure improves the nutrient retention capacity of apple orchard soils. ISHS Acta Horticulturae 638: XXVI international horticultural congress: sustainability of horticultural systems in the 21st century
  Dutta T, Stehouwer R (2010) N2O and CO2 emission from mine soil reclaimed with organic amendments (Incubation study). In: Proceedings of 19th world congress of soil science (WCSS) Aug 1–5, Brisbane, Australia
  Eghball B, Power JF, Gilley JE, Doran JW (1997) Nutrient, carbon, and mass loss of beef cattle feedlot manure during composting. J Environ Qual 26:189–193CrossRef
  Enzo F, Schleiss K (2009) The potential contribution of bio-waste to tackle climate change: issues related to life cycle benefits and relevance to policy-making. Summary of oral presentation for the DAKOFA/ISWA waste and climate conference 3–4 December
  European Commission (2010) Communication from the commission to the council and the European Parliament: On future steps in bio-waste management in the European Union. Brussels, May 18. COM. 235 (final)
  Fabrizio A, Tambone F, Genevini P (2009) Effect of compost application rate on carbon degradation and retention in soils. Waste Manag 29:174–179CrossRef
  FAO (1980) A manual of rural composting. FAO/UNDP Regional Project RAS/75/004 Field Document 15
  FAO (2003) On-farm composting methods. Land and water discussion paper. In: Misra RV, Roy RN, Hiraka H (eds). Food and Agriculture Organization of the United Nations, Rome. Retrieved from http://​www.​fao.​org/​organicag/​doc/​on_​farm_​comp_​methods.​pdf
  FAO-UNESCO (1997) Soil map of the world: revised legend. IRSIC, Wageningen
  Flessa H, Beese F (1995) Effect of sugar beet residues on soil redox potential and nitrous oxide emission. Soil Sci Soc Am J 59:1044–1051CrossRef
  Franzluebbers AJ, Stuedemann JA (2002) Particulate and non-particulate fractions of soil organic carbon under pastures in the Southern Piedmont USA. Environ Poll 116:53–62CrossRef
  Gee GW, Bauder JW (1986) Particle-size Analysis. P. 383-411. In Page AL (ed). Methods of soil analysis, Part1, Physical and mineralogical methods. Second Edition, Agronomy Monograph 9, American Society of Agronomy, Madison, WI
  Ginting D, Kessavalou A, Eghball B, Doran JW (2003) Greenhouse gas emissions and soil indicators 4 years after manure and compost applications. J Environ Qual 32:23–32CrossRef
  Harada Y (1992) Composting and land application of animal waste. Asian Australas J Anim Sci 5:113–121CrossRef
  Hills DJ (1979) Effects of carbon: nitrogen ratio on anaerobic digestion of dairy manure. Agric Wastes 1:267–278CrossRef
  Homan E, Shaw MD, Bartlett H, Persson S (2013) Biogas from manure. Penn State Extension, Pennsylvania Department of Agriculture, The Governor’s Energy Council, and the Department of Energy. Special Circular 260
  Huang Y, Zou J, Zheng X, Wang Y, Xu X (2004) Nitrous oxide emissions as influenced by amendment of plant residues with different C/N ratios. Soil Biol Biochem 36:973–981CrossRef
  IllINOIS ACES. University of Illinois Extention. http://​web.​extension.​illinois.​edu.​ Retrieved Jan 01, 2013
  IPCC [Metz B, Davidson, OR, Bosch PR, Dave R, Meyer LA (eds)] (2007) Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA
  Jianming L, Pute W, Behboudian MH, Zhirong WZZ, Morton A (2008) Responses of muskmelon to cattle or sheep manure compost mixed with sandy soil. J Org Sys 3(2):1177–4258
  Kariyapperuma KA, Furon A, Wager-Riddle C (2012) Non-growing season nirous oxide fluxes from an agricultural soil as affected by application of liquid and composted swine manure. Can J Soil Sci 92:315–327CrossRef
  Kaur K, Kapoor KK, Gupta AP (2005) Impact of organic manures with and without mineral fertilizers on soil chemical and biological properties under tropical conditions. J Plant Nutr Soil SC 168:117–122CrossRef
  Kawabata C, Ohta S, Ishizuka S, Wicaksono A, Heriyanto J (2010) Effect of DOM (dissolved organic matter) derived from litter of Acacia mangium and Eucalyptus pellita on soil N2O emissions. 19th world congress of soil science, soil solutions for a changing world, 1–6 August. Brisbane, Australia. Published on DVD
  Keeney DR, Nelson DW (1982) Nitrogen-inorganic forms. In: Page AL (eds) Methods of soil analysis. Part II. Chemical and microbiological properties. 2. ASA and SSSA; Madison, WI: pp 595–624. Agron Monogr 9
  Khan SA, Mulvaney RL, Ellsworth TR, Boast CW (2007) The myth of nitrogen fertilization for soil carbon sequestration. J Environ Qual 36:1821–1832CrossRef
  Lakha SS, Shannon KE, Henderson SL, Zebarth BJ, Burton DL, Goyer C, Trevors JT (2009) Effect of Nitrate and Acetylene on nirS, cnorB, and nosZ expression and denitrification activity in Pseudomonas mandelii. J Appl Environ Microbiol 75:5082–5087CrossRef
  Leifeld J, Siebert S, Kogel-Knabner I (2002) Changes in the chemical composition of soil organic matter after application of compost. Eur J Soil Sci 53:299–309CrossRef
  Livingston GP, Hutchinson GL (1995) Enclosure-based measurement of trace gas exchange: applications and sources of error. In: Matson PA, Harrison RC (eds) Biogenic trace gases: measuring emissions from soil and water. Blackwell Science Ltd., Oxford
  McCrady E (1991) The nature of lignin. Alkaline Pap Advocate 4:4
  Menzi H, Pain B, Smith K (1998) Solid manure in Europe: Results of the survey by the working group on solid manure of RAMIRAN. In: Proceedings of 8th international conference on the FAO ESCORENA network on recycling of agricultural, municipal and industrial residues in agriculture (RAMIRAN 98). [Martinez J, Maudet MN (eds)] vol. 2, Formerly animal waste management, Rennes, 26–29 May 1998
  Millar N, Baggs EM (2004) The chemical composition, or quality, of agroforestry residues influences N2O emissions after their addition to soil. Soil Biol Biochem 36:935–943CrossRef
  Millar N, Ndufa JK, Cadisch G, Baggs EM (2004) Nitrous oxide emissions following incorporation of improved-fallow residues in the humid tropics. Global Biogeochem Cycle 18:GB1032. doi:10.​1029/​2003GB002114
  Millar J, Robertson GP, Grace PR, Gehl RJ, Hoben JP (2010) Nitrogen fertilizer management for nitrous oxide (N2O) mitigation in intensive corn (Maize) production: an emissions reduction protocol for US Midwest agriculture. Mitig Adapt Strateg Glob Change 15:185–204CrossRef
  Mondini C, Tania A, Sinicco A, Cayuela ML (2010) Organic residues application is an effective strategy for sustainable management of soil organic matter. 19th world congress of soil science, soil solutions for a changing world 1–6 August. Brisbane, Australia. Published on DVD
  Mørkved PIT, Dörsch P, Bakken LR (2007) The N2O product ratio of nitrification and its dependence on long-term changes in soil pH. Soil Biol Biochem 39:2048–2057CrossRef
  Nahm KH (2003) Evaluation of the nitrogen content in poultry manure. World Poultry Sci J 59:77–88CrossRef
  Nemeth DD (2012) Nitrous oxide emission and abundance of N-cycling microorganisms in corn-based biofuel cropping systems. Masteral Thesis, Guleph, Ontario, Canada
  Pal P, Clough TJ, Kelliher FM, Sherlock RR (2010) N2O and CO2 emissions following clover and cellulose incorporation into a New Zealand pastoral soil. 19th world congress of soil science, soil solutions for a changing world 1–6 August. Brisbane, Australia. Published on DVD
  Pattey E, Trzcinski MK, Desjardins RL (2005) Quantifying the reduction of greenhouse gas emissions as a result of composting dairy and beef cattle manure. Nutr Cycl Agroecosys 72:173–187CrossRef
  Philippot L, Hallin S, Börjesson G, Baggs EM (2009) Bio-chemical cycling in the rhizosphere having an impact on global change. J Plant Soil 321:61–81CrossRef
  Rahman MM (2010) Assessment of household waste, poultry manure and cow dung in rice cultivation. Agriculturists 8:117–125
  Rastogi M, Singh S, Pathak H (2002) Emission of carbon dioxide from soil. Curr Sci 82:510–517
  Risse JM, DF, Well C, Humenik FJ (eds) (2006) 283–316 in animal agriculture and environment: National center for manure and animal waste management white papers. St. Joseph, Michigan: ASABE, 913c0306
  Roberson T, Reddy KC, Reddy SS, Nyakatawa EZ, Raper RL, Reeves DW, Lemunyon J (2008) Carbon dioxide efflux from soil with poultry litter applications in conventional and conservation tillage systems in northern Alabama. J Environ Qual 37:535–541CrossRef
  Rosen CJ, Bierman PM (2005) Using manure and compost as nutrient sources for vegetable crops. University of Minnesota Extension Services
  Rynk R (1992) On-farm composting handbook (NRAES-54). Cooperative Extension, Ithaca
  Saad OAL, Conrad L (1993) Temperature dependence of nitrification, denitrification, and turnover of nitric oxide in different soils. Biol Fertil Soil 15:21–27CrossRef
  Shaojun Q, Xiaotang J, Ingwersen J, Guo Z, Stange CF, Bisharat R, Streck T, Christie P, Zhang F (2009) Role of added Carbon in the transformation of surplus soil nitrate-nitrogen to organic forms in an intensively managed calcareous soil. The proceedings of International Plant Nutrition Colloquium XVI UC Davis
  Smith KA, Clayton H, McTaggart IP, Thomson PE, Arah JRM, Scott A (1995) The measurement of nitrous oxide emission from soil by using chambers. Phil Trans R Soc Lond Ser A 351:327–338CrossRef
  Tarre S, Beliavski M, Denekamp N, Gieseke A, de Beer D, Green M (2004) High nitrification rate at low pH in a fluidized bed reactor with chalk as the biofilm carrier. Water Sci Technol 49:99–105
  Tuomela M, Vikman M, Hatakka A, Itävaara M (2000) Biodegradation of lignin in a compost environment: a review. Bioresour Technol 72:169–183CrossRef
  Upendra M, Sainju Z, Senwo N, Nyakatawa ZE, Tazisong A, Reddy KC (2010) Poultry litter application increases nitrogen cycling compared with inorganic nitrogen fertilization. Agron J 102:917–925CrossRef
  USDA (2011) Carbon to nitrogen ratios in cropping systems. East National Technology Support Center, Greensboro, NC, in cooperation with North Dakota NRCS
  Velthof GL, Nelemansb JA, Oenemaa O, Kuikman PJ (2005) Gaseous nitrogen and carbon losses from pig manure derived from different diets. J Environ Qual 34:698–706CrossRef
  Wang X, Li X, Hu Y, Lv J, Sun J, Li Z, Wu Z (2010) Effect of temperature and moisture on soil organic carbon mineralization of pre-dominantly permafrost peatland in the Great Hing’an Mountains, northeastern China. J Environ Sci (China) 22:1057–1066CrossRef
  Watson CJ, Kilpatrick DJ, Cooper JE (1995) The effect of increasing application rate of granular calcium ammonium nitrate on net nitrification in a laboratory study of grassland soils. Nutr Cycle Agroecosys 40:155–161
  Whalen JK, Chang C, Clayton GW, Carefoot JP (2000) Cattle Manure Amendments Can Increase the pH of Acid Soils. Soil Sci Soc Am J 64:962–966CrossRef
  
• 作者单位：Ambreen Shah (1) (2)
  Marc Lamers (1)
  Thilo Streck (1)
  
  1. Biogeophysics Section, Institute of Soil Science and Land Evaluation, University of Hohenheim, 70593, Stuttgart, Germany
  2. Sindh Agriculture Research Institute, Tando Jam, Pakistan
  
• 刊物类别：Earth and Environmental Science
• 刊物主题：None Assigned
• 出版者：Springer Berlin Heidelberg
• ISSN：1866-6299

文摘

Organic residues can be a major source of nutrients and are valuable fertilizers. But their benefits with regard to soil quality are undisputed. However, only few studies have focused on emissions of greenhouse gases from soil enriched with organic residues. A microcosom approach was employed to investigate the influence of the origin and composition of various organic residues on mineralization and N₂O and CO₂ emissions in an arable soil. In total, we set up six treatments: control, poultry manure, bio-waste compost, sheep and wheat straw compost, cow manure (CM) and for further comparison, the mineral fertilizer calcium ammonium nitrate. 500 g of sieved and homogenized soil was mixed with the amendments and packed into microcosms. After a pre-incubation period of 10 days, gas concentrations were measured periodically from the headspace of the microcosm by means of an airtight surgical syringe. The measurement period continued for 32 days. Soil amended with CM showed a significantly (α = 0.05) higher cumulative CO₂ emission (914 mg kg−1) followed by bio-waste compost than poultry manure, sheep waste compost, control and calcium ammonium nitrate. Amending soil with cow manure and poultry manure led to the highest N₂O-N emissions (110 µg kg−1). However, poultry manure and calcium ammonium nitrate significantly enhanced mineralization and net nitrification. Amendment of sheep and wheat straw compost and cow manure led to C sequestration and reduced N₂O emission. Soil pH greatly decreased with poultry manure, sheep and wheat straw compost and bio-waste compost. Summing up, the application of organic residues to soil has some disadvantageous environmental effects calling for further research.