Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-27T23:39:20.640Z Has data issue: false hasContentIssue false

Present and potential impacts of waste from poultry production on the environment

Published online by Cambridge University Press:  27 December 2018

A.R. SEIDAVI*
Affiliation:
Department of Animal Science, Rasht Branch, Islamic Azad University, Rasht, Iran
H. ZAKER-ESTEGHAMATI
Affiliation:
Department of Animal Science, Rasht Branch, Islamic Azad University, Rasht, Iran
C.G. SCANES
Affiliation:
Center of Excellence in Poultry Science, University of Arkansas, Fayetteville, AR 72701, USA
*
Corresponding author: alirezaseidavi@iaurasht.ac.ir
Get access

Abstract

Poultry production is associated with greenhouse gas (GHG) emissions but at a much lower extent than other livestock. Global production of nitrogen from poultry excreta has been estimated at about 3.29 million metric tons for meat type chickens (the average of two estimates with different assumption of 2.65 and 3.94 million metric tons) and 2.36 million metric tons for laying hens. These estimates are markedly below earlier estimates, suggesting that the issues related to loading are of a markedly smaller magnitude than previously envisioned. However, if it is assumed that 2% of the nitrogen is lost as nitrous oxide with a global warming potential (GWP) of 298 CO2 equivalents (eq.) per unit as GHG, poultry waste is contributing 33.7 million metric tons of CO2 eq./year or 0.0337 gigatons (Gt) CO2 eq./yr. This represents only 0.64% of agricultural GHG emissions. The preferred method for the disposal of poultry excreta is land application as a fertiliser with the aggregate of livestock and poultry excreta being applied to 0.3 million hectares in the USA. The environmental consequences of excreta in litter include the release of ammonia and nitrous oxide (a GHG) together with contamination of ground and surface water with nitrate, phosphate and pathogens. Alternative approaches to utilise used litter are the following: combustion, gasification, digestion and feeding to ruminants. There is scope to reduce the environmental impact of poultry production on the environment.

Type
Review
Copyright
Copyright © World's Poultry Science Association 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

AGBEDE, T.M. and OJENIYI, S.O. (2009) Tillage and poultry manure effects on soil fertility and sorghum yield in southwestern Nigeria. Soil and Tillage Research 104: 74-81.Google Scholar
ALAM, M.S., KHAN, M.J., AKBER, M.A. and KAMRUZZAMAN, M. (2008) Broiler litter and layer manure in the diet of growing bull calves. Bangladesh Veterinarian 25: 62-67.Google Scholar
ATIDÉGLA, S.C., HUAT, J., AGBOSSOU, E.K., SAINT-MACARY, H. and KAKAI, R.G. (2016) Vegetable contamination by the fecal bacteria of poultry manure: case study of gardening sites in Southern Benin. International Journal of Food Science 2016: 4767453.Google Scholar
BAGGOTT, S.L., CARDENAS, L., GARNETT, E., HOBSON, M., JACKSON, J., MOBBS, D.C., MURRELLS, T., PASSANT, N., THOMSON, A. and WATTERSON, J.D. (2007) UK Greenhouse Gas Inventory, 1990-2005: Annual Report for submission under the Framework Convention on Climate Change. AEA Technology plc, Didcot, UK, April 2007.Google Scholar
BARNHART, B., BOSTIAN, M., FARE, R., GROSSKOPF, S., WHITTAKER, G., SINHA, E., MICHALAK, A. and PAPENFUS, M. (2016) Agricultural production and nutrient runoff in the Corn Belt: Assessing dynamic environmental performance. North American Productivity Workshop IX, Quebec City, CANADA, June 15 - 18, 2016.Google Scholar
BHATTACHARYA, A.N. and FONTENOT, J.P. (1965) Utilization of different levels of poultry litter nitrogen by sheep. Journal of Animal Science 24: 1174-1178.Google Scholar
BITZER, C.C. and SIMS, J.T. (1988) Estimating the availability of nitrogen in poultry manure through laboratory and field studies. Journal of Environmental Quality 17: 47-54.Google Scholar
BLAIR, R. and HERRON, K.M. (1982) Growth performance of broilers fed on diets containing processed poultry wastes. British Poultry Science 23: 279-287.Google Scholar
BOLAN, N.S., SZOGI, A.A., CHUASAVATHI, T., SESHADRI, B., ROTHROCK, M.J. (Jr) and PANNEERELVAM, P. (2010) Uses and management of poultry litter. World's Poultry Science Journal 66: 673-698.Google Scholar
BOLHAR-NORDENKAMP, M., GARTNAR, F., TSCHANUN, I. and KAISER, S. (2009) Combustion of poultry litter in bubbling fluidised beds - results from a new 120 MWth unit. Proceedings of 17th European Biomass Conference & Exhibition, 1-9.Google Scholar
BOND, T. and TEMPLETON, M.R. (2011) History and future of domestic biogas plants in the developing world. Energy for Sustainable Development 15: 347-354.Google Scholar
BOUWMAN, A.F., LEE, D.S., ASMAN, W.A.H., DENTENER, F.J., VAN DER HOEK, K.W. and OLIVIER, J.G.J. (1997) A global high-resolution emission inventory for ammonia, Global Biogeochemical Cycles 11: 561-587.Google Scholar
CHAMBLEE, T.N. and TODD, R.L. (2002) Mississippi broiler litter: fertilizer value and quantity produced. Research report 23. Mississippi Agricultural and Forestry Experiment Station, Mississippi State, MS.Google Scholar
CHASTAIN, J.P., COLOMA-DEL VALLE, A. and MOORE, K.P. (2012) Using broiler litter as an energy source: energy content and ash composition. Applied Engineering in Agriculture 28: 513-522.Google Scholar
CHEN, Z. and JIANG, X. (2014) Microbiological safety of chicken litter or chicken litter-based organic fertilizers: a review. Agriculture 4: 1-29.Google Scholar
CHISLOCK, M.F., DOSTER, E., ZITOMER, R.A. and WILSON, A.E. (2013) Eutrophication: Causes, Consequences, and Controls in Aquatic Ecosystems. Nature Education Knowledge 4: 10.Google Scholar
COUFAL, C.D., CHAVEZ, C., NIEMEYER, P.R. and CAREY, J.B. (2006a) Nitrogen emissions from broilers measured by mass balance over eighteen consecutive flocks. Poultry Science 85: 384-391.Google Scholar
COUFAL, C.D., CHAVEZ, C., NIEMEYER, P.R. and CAREY, J.B. (2006b) Measurement of broiler litter production rates and nutrient content using recycled litter. Poultry Science 85: 398-403.Google Scholar
COUFAL, C., HARMEL, D. and GENTRY, T. (2014) In-House Windrow Composting of Poultry Litter. Texas A & M Agrilife Extension, EPS-005.Google Scholar
CRESSMAN, M.D., YU, Z., NELSON, M.C., MOELLER, S.J., LILBURN, M.S. and ZERBY, H.N. (2010) Interrelations between the microbiotas in the litter and in the intestines of commercial broiler chickens. Applied and Environmental Microbiology 76: 6572-6582.Google Scholar
DAFWANG, I.I., COOK, M.E., PRINGLE, D.J. and SUNDE, M.L. (1986) Nutritional value of aerobically fermented poultry manure and offal (Fermway) for broiler chicks. Poultry Science 65: 1765-1770.Google Scholar
DAGNALL, S.P. (1993) Poultry litter as a fuel. World's Poultry Science Journal 49: 175-177.Google Scholar
DANIEL, J. and OLSON, K.C. (2005) Feeding poultry litter to beef cattle. University of Missouri Extension G2077.Google Scholar
DÁVALOS, J.Z., ROUX, M.V. and JIMÉNEZ, P. (2002) Evaluation of poultry litter as a feasible fuel. Thermochimica Acta 394: 261-266.Google Scholar
DAVIDSON, E.A. (2009) The contribution of manure and fertilizer nitrogen to atmospheric nitrous oxide since 1860. Nature Geosciences 2: 659-662.Google Scholar
DE CARVALHO, F.B., STRINGHINI, J.H., MATOS, M.S., FILHO, R.M.J., CAFÉ, M.B., LEANDRO, N.S.M. and ANDRADE, M.A. (2012) Performance and nitrogen balance of laying hens fed increasing levels of digestible lysine and arginine Revista Brasileira de Zootecnia 41: 2183-2188.Google Scholar
DIAZ, R.J. and ROSENBERG, R. (2008) Spreading dead zones and consequences for marine ecosystems. Science 321: 926-929.Google Scholar
DIMACHE, A., O'CONNER, J. and KEARNEY, D. (2013) Environmental analysis of the use of poultry manure as fuel for combustion on broiler farms: a case study. https://ec.europa.eu/environment/eco-innovation/projects/sites/eco-innovation-projects/files/projects/documents/af_-_supper.pdf. Accessed 10.12.18.Google Scholar
DUMAS, M.D., POLSON, S.W., RITTER, D., RAVEL, J., GELB, J. (Jr), MORGAN, R. and WOMMACK, K.E. (2011) Impacts of poultry house environment on poultry litter bacterial community composition. PLoS One 6: e24785.Google Scholar
EUROPEAN UNION COMMISSION (2017) Implementing decision 2017/302 establishing best available techniques (BAT) conclusions, under Directive 2010/75/EU of the European Parliament and of the Council, for the intensive rearing of poultry or pigs. http://www.prtr-es.es/Data/images/D2017302EUBATconclusions_Intensiverearingofpoultryorpigs.pdf. Accessed 10.14.18.Google Scholar
EUROPEAN COMMISSION -DIRECTORATE-GENERAL FOR ENVIRONMENT (2001) Properties of wastes relevant to agricultural benefit and environmental impact. http://ec.europa.eu/environment/waste/studies/compost/landspreading_4-6.pdf. Accessed 10.12.18.Google Scholar
FAO (2004) Feeding animal wastes. http://www.fao.org/docrep/004/X6518E/X6518E02.htm. Accessed 10.12.18.Google Scholar
FAOSTAT http://www.fao.org/faostat/en/#data/QL. Accessed November 24 and 2018.Google Scholar
FERGUSON, N.S., GATES, R.S., TARABA, J.L., CANTOR, A.H., PESCATORE, A.J., STRAW, M.L., FORD, M.J. and BURNHAM, D.J. (1998) The effect of dietary protein and phosphorus on ammonia concentration and litter composition in broilers. Poultry Science 77: 1085-1093.Google Scholar
FOWLER, D., PITCAIRN, C.E.R., SUTTON, M.A., FLECHARD, C., LOUBET, B., COYLE, M. and MUNRO, R.C. (1998) The mass budget of atmospheric ammonia in woodland within 1 km of livestock buildings. Environmental Pollution 102 (S1): 343-348.Google Scholar
GHALY, A.E. and MACDONALD, K.N. (2012) Drying of poultry manure for use as animal feed. American Journal of Agricultural and Biological Science 7: 239-254.Google Scholar
GOOD, A.G. and BEATTY, P.H. (2011) Fertilizing nature: a tragedy of excess in the commons. PLoS Biology 9: e1001124.Google Scholar
HE, Z., HONEYCUTT, C.W., TAZISONG, I.A., SENWO, Z.N. and ZHANG, D. (2009) Nitrogen and phosphorus accumulation in pasture soil from repeated poultry litter application. Communications in Soil Science and Plant Analysis 40: 587-598.Google Scholar
IPCC (Intergovernmental Panel on Climate Change) (2007) IPCC Fourth Assessment Report: Climate Change 2007. Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge.Google Scholar
JAYATHILAKAN, K., SULTANA, K., RADHAKRISHNA, K. and BAWA, A.S. (2012) Utilization of byproducts and waste materials from meat, poultry and fish processing industries: a review. Journal of Food Science and Technology 49: 278-293.Google Scholar
KELLEHER, B.P., LEAHY, J.J., HENIHAN, A.M., O'DWYER, T.F., SUTTON, D. and LEAHY, M.J. (2002) Advances in poultry litter disposal technology. Bioresource Technology 83: 27-36.Google Scholar
KIM, S.C., KIM, J.H., KIM, C.H., LEE, J.C. and KO, Y.D. (2000) Effects of whole crop corn ensiled with cage layer manure on nutritional quality and microbial protein synthesis in sheep. Asian-Australasian Journal of Animal Science 13: 1548-1553.Google Scholar
LATSHAW, J.D. and ZHAO, L. (2011) Dietary protein effects on hen performance and nitrogen excretion. Poultry Science 90: 99-106.Google Scholar
MARTINS, R.S., HÖTZEL, M.J. and POLETTO, R. (2013) Influence of in-house composting of reused litter on litter quality, ammonia volatilisation and incidence of broiler foot pad dermatitis. British Poultry Science 54: 669-676.Google Scholar
MCDONALD, J.M., RIBAUDO, M.O., LIVINGSTON, M.J., BECKMAN, J. and WANG, H. (2009) Manure Use for Fertilizer and for Energy – Report to Congress. Economic Research Service, U.S. Department of Agriculture, Washington, D.C.Google Scholar
MCDOUGAL, T. (2018) Chicken litter as animal feed becoming trade issue. https://www.poultryworld.net/UK/Articles/2018/1/Chicken-litter-as-animal-feed-becoming-trade-issue-235059E/. Accessed 10.12.18.Google Scholar
MOLINA, M., WHELAN, G., FITZGERALD, C. and STEVENS, C. (2013) Aged manures as sources of pathogens in agricultural runoff. Presented at American Society for Microbiology, Denver, CO, May 18-21, 2013.Google Scholar
MUELLER, D.K. and HELSEL, D.R. (2017) Nutrients in the nation's waters--too much of a good thing? USGS. https://pubs.usgs.gov/circ/circ1136/circ1136_map.html. Accessed January 15, 2018.Google Scholar
OBEIDAT, B.S., AWAWDEH, M.S., ABDULLA, A.Y., MUWULLA, M.M., ABU ISHMAIS, M.A., TELFAH, B.T., AYROUT, A.J., MATARNEH, S.K., SUBIH, H.S. and OSAILI, T.O. (2011) Effects of feeding broiler litter on performance of Awassi lambs fed finishing diets. Animal Feed Science and Technology 165: 15-22.Google Scholar
ODHUBA, E.K. (2009) Towards efficient utilization of poultry waste by ruminants. http://www.fao.org/wairdocs/ILRI/x5490E/x5490e09.htm. Accessed 12.15.17.Google Scholar
OKEUDO, N.J. and ADEGBOLA, A.A. (1993) Utilisation of dried caged-hen manure and cassava peels for intensive sheep production. Tropical Animal Health and Production 25: 234-238.Google Scholar
PIMENTEL, D., WILLIAMSON, S., ALEXANDER, C.E., GONZALEZ-PAGAN, O., KONTAK, C. and MULKEY, S.E. (2008) Reducing Energy Inputs in the U.S. Food System. Human Ecology 36: 459-471.Google Scholar
POWELL, S., JOHNSTON, S., GASTON, L. and SOUTHERN, L.L. (2008) The effect of dietary phosphorus level and phytase supplementation on growth performance, bone-breaking strength, and litter phosphorus concentration in broilers. Poultry Science 87: 949-957.Google Scholar
RANKINS, R., RUFFIN, B.G. and VAN DYKE, N.J. (2000) Feeding Broiler Litter to Beef Cattle. Alabama Cooperative Extension System ANR-557 http://www.aces.edu/pubs/docs/A/ANR-0557/ANR-0557.pdf. Accessed 12.6.17.Google Scholar
REN, T., WANG, J., CHEN, Q., ZHANG, F. and LU, S. (2014) The Effects of Manure and Nitrogen Fertilizer Applications on Soil Organic Carbon and Nitrogen in a High-Input Cropping System. PLoS One 9: e97732.Google Scholar
ROLL, V.F., DAI PRÁ, M.A. and ROLL, A.P. (2011) Research on Salmonella in broiler litter reused for up to 14 consecutive flocks. Poultry Science 90: 2257-2262.Google Scholar
RUDDY, B.C., LORENZ, D.L. and and MUELLER, D.K. (2006) County-level estimates of nutrient inputs to the land surface of the contiguous United States, 1982-2001. U.S. Geological Survey Scientific Investigations Report 2006-5012, 17 p.Google Scholar
SHARPE, R.R., SCHOMBERG, H.H., HARPER, L.A., ENDALE, D.M., JENKINS, M.B. and FRANZLUEBBERS, A.J. (2004) Ammonia volatilization from surface-applied poultry litter under conservation tillage management practices. Journal of Environmental Quality 33: 1183-1188.Google Scholar
SCHROEDER, P.D., RADCLIFFE, D.E. and CABRERA, M.L. (2004) Rainfall timing and poultry litter application rate effects on phosphorus loss in surface runoff. Journal of Environmental Quality 33: 2201-2209.Google Scholar
SIRRI, F. and MELUZZI, A. (2012) Effect of sequential feeding on nitrogen excretion, productivity, and meat quality of broiler chickens. Poultry Science 91: 316-321.Google Scholar
SHEN, J., CHEN, D., BAI, M., SUN, J., COATES, T., LAM, S.K. and LI, Y. (2016) Ammonia deposition in the neighbourhood of an intensive cattle feedlot in Victoria, Australia. Scientific Reports 6: 32793.Google Scholar
STEINFELD, H., GERBER, P., WASSENAAR, T., CASTEL, V., ROSALES, M. and DE HAAN, C. (2006) Livestock's long shadow; environmental issues and options. Food and Agriculture Organization of the United Nations, Rome.Google Scholar
STINGONE, J.A. and WING, S. (2011) Poultry litter incineration as a source of energy: reviewing the potential for impacts on environmental health. New Solution 21: 27-42.Google Scholar
THOMAS, J.W., YU, Y., TINNIMITT, P. and ZINDEL, H.C. (1972) Dehydrated poultry waste as a feed for milking cows and growing sheep. Journal of Dairy Science 55: 1261-1265.Google Scholar
USDA NRCS (National Resources Conservation Service) (1995) Animal Manure Management. https://www.nrcs.usda.gov/wps/portal/nrcs/detail/null/?cid=nrcs143_014211. Accessed 12.13.17.Google Scholar
UNECE (United Nations Economic Commission for Europe) (2012) Guidance document for preventing and abating ammonia emissions from agricultural sources. http://www.unece.org/environmental-policy/conventions/air/guidance-documents-and-other-methodological-materials/gothenburg-protocol.html. Accessed 10.14.18.Google Scholar
USEPA (U.S. Environmental Protection Agency) (1975) Development document for proposed effluent limitations guidelines and new source performance standards for the poultry segment of the meat product and rendering process, point source category. EPA/440/1-75/031-B, Washington, DC (DCN 00140).Google Scholar
USGS (United States Geological Survey) (2017) Major findings. https://pubs.usgs.gov/circ/circ1210/major_findings.htm. Accessed January 15, 2018.Google Scholar
VAN RYSSEN, J.B.J. (2001) Poultry litter as a feedstuff for ruminants: A South African scene. South African Animal Science 2: http://www.sasas.co.za/Popular/Popular.html. Accessed 10.12.18.Google Scholar
WANG, S., NAN, J., SHI, C., FU, Q., GAO, S., WANG, D., CUI, H., SAIZ-LOPEZ, A. and ZHOU, B. (2015) Atmospheric ammonia and its impacts on regional air quality over the megacity of Shanghai, China. Scientific Reports 5: 15842.Google Scholar
WATTS, D.B., TORBERT, H.A., PRIOR, S.A. and HULUKA, G. (2010) Long-term tillage and poultry litter impacts soil carbon and nitrogen mineralization and fertility. Soil Science Society of America Journal 74: 1239-1247.Google Scholar
WIEDEMANN, S.G. (2015) Litter reuse: an evidence-based guide to reusing litter. RIRDC Publication No. 14/095. Rural Industries Research and Development Corporation, Australia.Google Scholar
WILLIAMS, C.M. (2010) Poultry waste management in developing countries. Poultry development review. FAO, Roma, Italy.Google Scholar
WONGA, J.T., DE BRUYNA, J., BAGNOLA, B., GRIEVED, H., M.LIE, M., PYM, R. and and ALDERSA, R.G. (2017) Small-scale poultry and food security in resource-poor settings: A review. Global Food Security 15: 43-52.Google Scholar
ZHANG, W. and LAU, A. (2007) Reducing ammonia emission from poultry manure composting via struvite formation. Journal of Chemical Technology and Biotechnology 82: 598-602.Google Scholar
ZINN, R.A., BARAJAS, R., MONTANO, M. and SHEN, Y. (1996) Protein and energy value of dehydrated poultry excreta in diets for feedlot cattle. Journal of Animal Science 74: 2331-2335.Google Scholar