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Bitki Artığı Yakmanın Yarı kurak Tarımsal Üretim Sistemlerinde Toprak Fiziksel ve Hidrolojik Özelliklerine Etkileri

Effects of Crop Residue Burning on Soil Physical and Hydrological Properties in Semi-Arid Agricultural Production Systems

Journal Name:

  • Gaziosmanpaşa Üniversitesi Ziraat Fakültesi Dergisi

Publication Year:

  • 2016
DOI: 
http://dx.doi.org/10.13002/jafag1105

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
The effect of wheat-stubble burning on soil physical and hydrological properties is under scrutiny to develop a sound soil and water management planning in agroecosystems. The objective of this study was to compare completely-burned, moderately-burned, and unburned soil conditions for responses of soil physical and hydrological properties. The persistence of fire-induced impacts were studied in 3 hectare land for both burned and unburned conditions for two years. Results showed that saturated hydraulic conductivity significantly increased in descending order 0.81, 0.36, and 0.23 cm h-1 for burned, moderately-burned, and unburned plots (P=0.000). Completely-burned treatments registered significantly higher Ksat (P=0.000) of 0.81 and 0.23 cmh-1, respectively from completely-burned and unburned treatments. Fire intensity significantly reduced the pore space volume, the highest for burned and the least for the moderately-burned treatments (P<0.001). Unburned treatments had 11.5 and 9.7 % more pore spaces than completely-burned and moderately-burned plots, respectively. Residue burning significantly changed pore size distributions between three levels of treatments (P<0.045). Storage pores decreased significantly from 37.3% (unburned) to 25.8% (burned), while significantly increasing residual pores from 8.07% to 13.5 % (burned) and 12.7% (moderately-burned). To conclude, residue-retaining soil management practices need implemented in the Plain.
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Abstract (Original Language): 
Tarım ekosistemlerinde etkin bir toprak ve su yönetim planı geliştirmek için buğday saplarının yakılmasının toprak fiziksel ve hidrolojik özelliklerine etkisi araştırılmaktadır. Bu çalışmanın amacı tam-yakılmış, ortalamayakılmış ve yakılmamış toprak şartlarında toprak fiziksel ve hidrolojik özelliklerinin durumunu karşılaştırmaktır. Yakmanın devam eden etkileri 3-ha alanda her iki yanmış ve yanmamış şartlarda 2-yıl çalışılmıştır. Sonuçlar göstermektedir ki: Suya doygunluk iletkenlik değerleri azalan sıralamayla, tam-yanmış (0.81), orta-derecedeyanmış (0.36) ve yanmamış (0.23 cm h-1) önemli derecede artmıştır (P=0.000). Yakma şiddeti gözenek boşluk hacmini en fazla tam-yanmış ve en az da orta-derecede-yanmış muamelelerde azaltmıştır (P=0.000). Yanmamış muameleler sırsıyla tam-yanmış ve orta-derecede-yanmış muamelelere kıyasla %11,5 ve %9,7 daha fazla gözenek hacmi içermiştir. Bitki artıklarının yakımı gözenek büyüklük dağılımlılarını muamelelerin üç seviyesi arasında önemli derecede değiştirmiştir (P<0.045). Tam-yanmış muameleler sırasıyla yanmamış (0.89) ve orta-derecedeyanmış (0.79 cm-1) muamelelerden önemli derecede yüksek Ksat farkları göstermiştir (P=0.000). Bitki artıklarının yakılması depo gözenek hacimlerini %37,3 (yanmamış) den %25,8 (tam-yanmış) değerine önemli derecede azaltırken, ölü gözenek hacmi %8.07 den %13,5 ‘e (tam-yanmış) ve %12,7’ ye (orta-derecede-yanmış) önemli derecede düşürmüştür. Bitki artıklarını toprakta tutan toprak yönetim uygulamaların ovada hayata geçirilmesine ihtiyaç vardır.
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  • Turkish

REFERENCES

References: 

Integrated model shows that atmospheric brown clouds
and greenhouse gases have reduced rice harvests in
India. Proceedings of the National Academy of
Sciences, 103 (52): 19668-19672.
Badı`a D and Martı´ C (2003). Plant ash and heat intensity
effects on chemical and physical properties of two
contrasting soils. Arid Land Res Manage., 17:23–41.
Baldock JA and Smernik RJ (2002). Chemical
composition and bioavailability of thermally altered
Pinus resinosa (red pine) wood. Organic
Geochemistry, 33: 1093-1109.
Bronick CJ and Lal R (2005). Soil structure and
management: a review. Geoderma, 124: 3–22.
Certini G (2005). Effects of fire on properties of forest
soils: a review. Oecologia, 143:1-10.
Cerit İ, Turkay MA, Saruhan H, Şen HM, Ülger AC,
Kirişçi V, Korucu T and Say S (2002). İkinci Ürün
Mısır Yetiştiriciliğinde Ekim Öncesi Buğday Anızının
Yakılmasına Alternatif Bazı Toprak İşleme
Metotlarının Belirlenmesi. Tarım ve Köyişleri
Bakanlığı Tarımsal Araştırmalar Genel Müdürlüğü,
Proje Kod No: TAGEM/TA/00/01/06/08. (in Turkish)
Clinnick PF and Willatt ST (1981). Soil physical and
chemical properties measured in an ashbed
following windrow burning. Australian Forestry, 44:
185-189.
Day P (1965). Particle fractionation and particle-size
analysis. In: Methods of Soil Analysis, Part 1, CA.
Black (ed), American Society of Agronomy Inc.,
Madison, Wisconsin, Number 9 Agronomy Series.
DeBano LF, Neary DG and Ffolliott PF (1998). Fire’s
effects on ecosystems. John Wiley and Sons. Inc.
Toronto, Canada. ISBN 0-471-16356-2.
Devlet Meteoroloji İşleri (DMI) (2016). İklim Verileri,
Ankara: Başbakanlık Devlet Meteoroloji İşleri Genel
Müdürlüğü. http://www.mgm.gov.tr/iklim/iklimsiniflandirmalari.
aspx?m=ANTAKYA (erişim tarihi:
05.10.2016).
DSI (1962). The Amik Project: The report of land
planning and classification of the Amik Plain.
Ministry of Public Works of the Republic of Turkey,
General Directorate of State Hydraulic works,
Department of Survey and Planning, Ankara, Turkey,
Project No: 1901, Survey report No. 17104.
Durgin PB and Vogelsang PJ (1984). Dispersion of
kaolinite by water extracts of Douglas-fir ash. Can J
Soil Sci., 64:439–443.
EIA (2008). Documentation for Emissions of Greenhouse
Gases in the United States 2006. Energy Information
Administration (EIA), Office of Integrated Analysis
and Forecasting, U.S. Department of Energy,
Washington, D.C, USA.
Eiland B (1998). Mechanical harvesting in Florida.
Elements of Sugarcane Production Short Course.
Gainesville, Florida: University of Florida
Cooperative Extension Service.
Fernandez, I, Cabaneiro A Carballas T (1997). Organic
matter changes immediately after a wildfire inan
Atlantic forest and comparison with laboratory soil
heating. Soil Biology and Biochemistry, 29:1-11.
Gadde B, Bonnet S, Menke C and Garivait S (2009). Air
pollutant emissions from rice straw open field burning
in India, Thailand and the Philippines. Environmental
Pollution, 157: 1554-1558.
Ghimire NP (2007). Impact of agricultural aggravation on
ecology. Journal of Agriculture and Environment, 8:
101-105.
Giovannini G, Lucchesi S and Giachetti M (1988). Effect
of heating on some physical and chemical parameters
related to soil aggregation and erodibility. Soil
Science, 146: 225-261.
Haider MZ (2013). Determinants of rice residue burning
in the field. Journal of Environmental Management,
128: 15-21.
Haverkamp R, Leij FJ, Fuentes C, Sciortino A and Ross
PJ (2005). Soil water retention: I. Introduction of a
shape index. Soil Science Society America Journal,
69: 1881–1890.
Hemwong S, Cadisch G, Toomsan B, Limpinuntana V,
Vityakon P and Patanothai A (2008). Dynamics of
residue decomposition and N2 fixation of rain legumes
upon sugarcane residue retention as an alternative to
burning. Soil and Tillage Research, 99: 84-97.
Imeson AC, Verstraten JM, van Mulligen EJ and Sevink J
(1992). The effects of fire and water repellency on
infiltration and runoff under Mediterranean type
forest. Catena, 19: 345–361.
Kılıç Ş, Ağca N, Karanlık S, Şenol S, Aydın M, Yalçın M,
Özelik İ, Evrendilek F, Uygur V, Doğan K, Aslan S
and Çullu MA (2008). Amik Ovası’nın detaylı toprak
etütleri, verimlilik çalışması ve arazi kullanım
planlaması. Mustafa Kemal Üniversitesi, Ziraat
Fakültesi, Toprak Bölümü. Bilimsel Araştırma
Projeleri Komisyonu, Proje No: DPT2002K120480. (
In Turkish)
Klute A and Dirksen C (1986). Hydraulic conductivity and
diffusivity: Laboratory methods. In Methods of Soil
Analysis: Part 1—Physical and Mineralogical
Methods; American Society of Agronomy, Madison,
WI, USA, pp. 687–734.
Korkmaz H (2005). Amik Gölü’nün kurutulmasının yöre
iklimine etkileri. T.C. Mustafa Kemal Üniversitesi
Bilimsel Araştırma Projeleri Fonu. Araştırma Projesi
Sonuç Raporu. Proje No: 03 F 0701ç Antakya/Hatay. (
In Turkish)
Lal MM (2008). An overview to agricultural waste
burning. Indian Journal of Air Pollution Control, 8
(1): 48-50.
Mackay SM, Long AC and Chambers RW (1985). Erosion
pin estimates of soil movement after intensive logging
and wildfire. In: R.J. Loughran (Editor), Drainage
Basin Erosion and Sedimentation. University of
Newcastle, UK.
Malhi SS and Kutcher HR (2007). Small grains stubble
burning and tillage effects on soil organic C and N,
and aggregation in northeastern Saskatchewan. Soil
and Tillage Research, 94: 353–361.
Marcos E, Tarrega R and Luis-Calabuig E (2000).
Comparative analysis of runoff and sediment yield
with a rainfall simulator after experimental fire. Arid
Soil Res Rehab., 14:293–307.
Mataix-Solera J and Doerr SH (2004). Hydrophobicity and
aggregate stability in calcareous topsoils from fireaffected
pine forests in southeastern Spain. Geoderma,
118:77–88.
234
AKIŞ/ JAFAG (2016) 33 (3), 223-235
McCarty JL, Korontzi S, Justice CO and Loboda T (2009).
The spatial and temporal distribution of crop residue
burning in the contiguous United States. Science of the
Total Environment, 40: 5701-5712.
McLean EO (1982). Methods of Soil Analysis, Part 2.
Chemical and Microbiological Properties-Agronomy
Monograph no. 9 (2nd. Ed). ASA-ASSS.
McNabb DH, Gaweda F and Froehlich HA (1989).
Infiltration, water repellency, and soil moisture
content after broadcast burning a forest site in
southwest Oregon. Journal of Soil Water
Conservation, 44: 87-90.
Mermut AR, Luk SH, Romkens MJM and Poesen JWA
(1997). Soil loss by splash and wash during rainfall
from two loess soils. Geoderma, 75:203–214.
Moody JA, Kinner DA and Ubeda X (2009). Linking
hydraulic properties of fire affected soils to infiltration
and water repellency. Journal of Hydrology, 379: 291–
303.
Mualem Y (1976). A new model for predicting the
hydraulic conductivity of unsaturated porous media.
Water Resource Research, 12: 513–522.
Nyman P, Sheridan G and Lane PNJ (2010). Synergistic
effects of water repellency and macropore flow on the
hydraulic conductivity of a burned forest soil, southeast
Australia. Hydrological Processes, 24: 2871–
2887.
Oswald BP, Davenport D and Neuenschwander LF
(1999). Effects of slash pile burning on the physical
and chemical soil properties of Vassar soils. J
Sustainable For., 8:75–86.
Philip JR (1969). Theory of infiltration. P.216-296. In
V.T. Chow (ed.) Advences in hydroscience. Academic
Press, New York.
Rab MA, Baker TG and King M (1994). Quantification of
the degree and extent of soil disturbance on cleufelW
coupes of mountain ash in the Victorian Central
Highlands. VSP -Intern. Rep. No. 27. Department of
Conservation and Natural Resources, Victoria,
Australia, 22 pp.
Rab MA (1996). Soil physical and hydrological properties
following logging and slash burning in the Eucalyptus
regnans forest of southern Austalian Forest Ecology
and Management, 84:159-176.
Robichaud PR (2000). Fire effects on infiltration rates
after prescribed fire in Northern Rocky Mountain
forests, USA. Journal of Hydrology, 231–232: 220–
229.
Schwertmann U and Taylor RM (1989). Iron oxides. In:
J.B, Dixon and S.B. Weed (editors), Minerals in Soil
Environments, Second edition. Soil Science Society
of America, Madison, Wisconsin, pp. 379-438.
Shakesby RA, Coelho de COA, Ferreira AD, Terry JP and
Walsh RPD (1993). Wildfire impacts on soil erosion
and hydrology in wet Mediterranean forest, Portugal.
International Journal of Wildland Fire, 3: 95–110.
Šimůnek J, van Genuchten MT and Sejna M (2005). The
hydrus-1d software package for simulating the onedimensional
movement of water, heat, and multiple
solutes in variably-saturated media. Univ. Calif. -
Riverside Res. Rep., 3: 1–240.
Tanant RF (1956). Effects of slash burning on some soils
of the Douglas-fir region. Soil Science Society of
America Proceedings, 20: 408-411.
Temel M (2012). Biçerdöver ve Anız Yangınları, Türkiye
Ziraat Odası Yayınları, sayı:42.
Uygur V, Irvem A, Karanlik S and Akis R (2010).
Mapping of total nitrogen, available phosphorus and
potassium in Amik Plain, Turkey. Environmental
Earth Sciences, 59: 1129-1138.
van Genuchten MT (1980). A closed-form equation for
predicting the hydraulic conductivity of unsaturated
soils. Soil Science Society of America Journal, 44:
892–898.
van Genuchten MTh, Leij FJ and Yates SR (1991). The
RETC code for quantifying the hydraulic functions
of unsaturated soils, EPA/600/2-91/065, US
Environmental Protection Agency, Ada, OK.
Vermeire LT, Mitchell RB, Fuhlendorf SD and Gillen R
(2004). Patch burning effects on grazing distribution.
Journal of Range Management, 57: 248–52.
Wang Y, Xu J, Shen J, Luo Y, Scheu S and Ke X
(2010).Tillage, residue burning and crop rotation alter
soil fungal community and water-stable aggregation in
arable fields. Soil Tillage and Research, 107: 71-79.
Webb J, Hutchings N and Amon B (2009). Field Burning
of Agricultural Wastes. European Environment
Agency (EEA), Copenhagen, pp. 1-14. EMEP/EEA
Emission. Inventory Guidebook.
Wright H and Bailey AW (1982). Fire ecology, United
States and southern Canada. John Wiley and Sons. 501
p. New York.
Yates DN, Warner TT and Leavesley GH (2000).
Prediction of a flash flood in complex terrain. Part II: a
comparison of flood discharge simulations using
rainfall input from radar, a dynamic model, and an
automated algorithmic system. Journal of Applied
Meteorology, 39: 815–825.
Yılmaz G, Bilgili AV, Toprak D, Almaca A and Mermut
AR (2014). Anız yakmanın karbondioksit salınımına
etkisi. Harran Tarım ve Gıda Bilimleri Dergisi, 18(1):
25-31.
Zhang H, Ye X, Cheng T, Chen J, Yang X, Wang L and
Zhang R (2008). A laboratory study of agricultural
crop residue combustion in China: emission factors
and emission inventory. Atmospheric Environment,
42: 8432-8441.

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