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Productivity of alley farming with the help of Leucaena leucocephala (ipil ipil) and Penniseteum purpurium (napier grass) in rain-fed condition of Potohar, Pakistan

By: Gulnaz Akhtar, Mohammad Umar Farooq, Rukhsana Tariq, Imtiaz Ahmad Qamar, Tahir Zahoor Chohan, Rifat Ullah Khan

Key Words: Integrated farming systems, Leucaena leucocephala, Pennisteum purpureum, Phytomass and Carbon stock.

Int. J. Biosci. 15(3), 219-228, September 2019.

DOI: http://dx.doi.org/10.12692/ijb/15.3.219-228

Certification: ijb 2019 0133 [Generate Certificate]

Abstract

The aim of this study is to assess good quality forage, firewood and carbon stock on sustainable basis by agro-forestry intervention with the help of alley cropping on rain fed areas, and to improve the livelihood of the poor farmer at their door steps. The agro-forestry is one of the promising techniques to overcome food shortage problem and to provide the forage, fire and fuel wood supply on sustainable basis to the resilient farmer Rahman et al. (2016). The introduction of alley farming in agro-forestry enhance the biomass productivity, improve soil health, have more ability of conserving water and create balance in atmosphere Baig et al. (2013). The livestock mainly depends on the natural pasture lands not only in the Potohar region but all around Pakistan. The livestock are greatly suffered from insufficient and less nutritive feed during the dry summer and winter months. Therefore, the introduction of alley cropping practice in agro-forestry leguminous trees with nutritious grass species is the only solution for sustainable supply of good quality forages to improve the livelihood of the resilient farmers for their livestock at their door steps.   Alley cropping experiment was conducted in the rain-fed area of Range land Research Institute (RRI), National Agricultural Research Centre (NARC), Islamabad. L. leucocephala (iple iple) plant and Pennisteum purpureum (Elephant grass) grass were selected for this study. There were three treatments and three replications in this research study. An area of one ha was selected and divided into four equal parts. There were four lines (contour) of plants and three plots were allocated for grasses. On the contour lines L. leucocephala (iple iple) plants were planted at one foot apart from each other. Space between two contour linesi.e called alley, the grass tufts on (1×1) feet was planted and alley to alley distance was retained to twenty feet. Biomass production for grasses, fodder (leaves), firewoods and their carbon stock were determined after every three month’s interval. Soil samples were collected at the four different depths (0-20, 20-40, 40-60, 60-80 cm) for soil in-organic carbon determination. The study was conducted in Completely Randomized Block Design (CRBD) under field conditions without irrigation and fertilizer. The result indicated that maximum biomass production (kg/ha) of grasses and plants were higher during May-August (Grass: 5.10 kg/ha, Tree: Leaves: 4.8 kg/ha, and fire wood: 5.7 tons/ha). The amount of carbon in grass dry weight was also maximum during May-August, i.e. 0.65 (Mg C ha-1 ).Similarly, in Leucaena leucocephala (iple iple) leaves and firewood  showed that dry weight of leaves contained maximum carbon in May-August 0.57 (Mg C ha-1) and high carbon content in firewood during September-October 0.85 (Mg C ha-1). The data for soil in-organic content showed that as their depth increases from surface i.e. 0 to 80 cm the soil in-organic content also increases gradually with the depth. The soil organic contents were only significant at the depth of 0-20 cm 2.10 (Mg C ha-1) and gradually decreasing as the depth increases from 20 to 80 cm. This study showed maximum biomass production of grasses and trees which can improve the cattle production, firewood/timber shortage issues and significant role of trees in mitigating rampant climate change issues  It can recover the soil fertility status  regarding nitrogen simultaneously, it will provide forage in smallholder farming systems.

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Productivity of alley farming with the help of Leucaena leucocephala (ipil ipil) and Penniseteum purpurium (napier grass) in rain-fed condition of Potohar, Pakistan

Aalde H, Gonzalez P, Gytarsky M, Krug T, Kurz W. 2006. Forest land. IPCC Guidelines for National Greenhouse Gas Inventories,(Agriculture, Forestry and Other Land Use). IPCC, Published by the Institute for Global Environmental Strategies (IGES), Hayama, Japan, on behalf of the IPCC, 1–4.

Amadi CC, Van Rees KC, Farrell RE. 2016. Soil–atmosphere exchange of carbon dioxide, methane and nitrous oxide in shelterbelts compared with adjacent cropped fields. Agric. Ecosyst. Environ. 223, 23–134.

Anderson SH, Udawatta RP, Seobi T, Garrett HE. 2009 Soil water content and infiltration in agroforestry buffer strips. Agroforestry Systems. 75(1), 5–16.

Angers DA, Arrouays D, Saby NPA, Walter C. 2011.Estimating and mapping the carbon saturation deficit of French agricultural topsoils. Soil Use Manag 27, 448–452.

Baah-Acheamfour M, Carlyle CN, Bork EW, Chang SX. 2014. Trees increase soil carbon and its stability in three agroforestry systems in central Alberta, Canada. For. Ecol Manage 328, 131–139.

Baah-Acheamfour M, Carlyle CN, Lim SS, Bork EW, Chang SX. 2016. Forest and grassland cover types reduce net greenhouse gas emissions from agricultural soils. Sci. Science of The Total Environment 571, 1115-1127.

Baah-Acheamfour M, Scott SX, Carlyle CN, Bork EW. 2015. Carbon pool size and stability are affected by trees and grassland cover types within agroforestry systems of western Canada. Agric. Ecosyst. Environ 213 105–113.

Baig MB, Shahid SA, Straquadine GS. 2013. Making rainfed agriculture sustainable through environmental friendly technologies in Pakistan: A review International Soil and Water Conservation Research. 36-52.

Bergeron M, Lacombe S, Bradley RL, Whalen J, Cogliastro A, Jutras M, Arp P. 2011. Reduced soil nutrient leaching following the establishment of tree-based intercropping systems in eastern Canada. Agrofor. Syst, 83, 321–330.

Cardinael R, Chevallier T, Cambou A, Béral C, Barthès BG, Dupraz C, Durand C, Kouakoua E, Chenu C. 2016. Increase of soil organic carbon stock under agroforestry: A Survey of different sites in France, 3rd European Agroforestry Conference – Montpellier, 23-25.

Cardinael R, Chevalliera T, Barthèsa BG, Sabyb NPA, Parenta T, Duprazc C, Bernouxa M, Chenu C. 2015. Impact of alley cropping agroforestry on stocks, forms and spatial distribution of soil organic carbon. A case study in a Mediterranean context. Geoderma, 259–260.

Chaves MM, Pereira JS, Maroco J, Rodrigues MLRicardo CPOsório MLCarvalho IFaria T, Pinheiro C. 2002. How plants cope with water stress in the field. Photosynthesis and growth. Annals of Botany 89(7), 907–916.

Dixin Y, Huabing T, Qing Z, Yurong L, Dengmei L, Dachao L. 2002.Research on Alley Cropping Technology on Sloping Land of Guizhou Province.12th ISCO Conference Beijing, China.

Dougherty MC, Thevathasan NV, Gordon AM, Lee L, Kort J. 2009. Nitrate and Escherichia coli NAR analysis in tile drain effluent from a mixed tree intercrop and monocrop system. Agricultural Ecosystem and Environment 131, 77–84.

Dubeux JCB, Muir JP, Apolinário VXdeO, Nair PKR, Lira Mde A, Sollenberger LE. 2017. Invited Review Tree legumes: an underexploited resource in warm-climate silvopastures. Brazillian Journal of Animal Science 46(8), 689-703.

Evers AK, Bambrick A, Lacombe S, Dougherty MC, Peichl M, Thevathasan NV, Whalen J,  Bradley RL. 2010, Potential greenhouse gas mitigation through temperate tree-based intercropping systems. Open Agricultural Journal 4, 49–57.

Jose S, Gold MA, Garrett HE. 2012. The future of temperate agroforestry in the United States. In: Nair, P.K.R.; Garrity, D., eds. Agroforestry: the future of global land use. Advances in Agroforestry. Dordrecht, Netherlands: Springer 9, 217–245.

Jose S. 2009. Agroforestry for ecosystem services and environmental benefits: An overview. Agroforest System 76, 1–10.

Kang BT, Atta-Krah AN, Reynolds L. 1999. Alley Farming; Macmillan Education: Basingstoke, UK:53.

Kim DG, Kirschbaum MU, Beedy TL. 2016. Carbon sequestration and net emissions of CH4 and N2O under agroforestry: Synthesizing available data and suggestions for future studies. Agricultural Ecosystem Environment 226, 65–78.

Kumar BM. 2006. Agroforestry: the new old paradigm for Asian food security. Journal of Tropical Agriculture 44, 1-14.

Laganiere J, Paré D, Bergeron Y, Chen HY, Brassard BW, Cavard X. 2013. Stability of soil carbon stocks varies with forest composition in the Canadian boreal biome. Ecosystems 16, 852–865.

Marin RA. 2016. Jatropha based alley cropping system’s contribution to carbon sequestration, International Journal of Agronomy and Agricultural Research (IJAAR), 81, 1-9.

Montagnini F, Nair PKR. 2004. Carbon sequestration: An underexploited environmental benefit of agroforestry systems. Agroforestry System. 61-2, 281–295.

Mulia R, Dupraz C. 2006. Unusual fine root distributions of two deciduous tree species in southern France: What consequences for modelling of tree root dynamics? Plant Soil 281, 71–85.

Mutuo PK, Cadisch G, Albrecht A, Palm CA Verchot L. 2005. Potential of agroforestry for carbon sequestration and mitigation of greenhouse gas emissions from soils in the tropics. Nutrient Cycling in Agroecosystems 71, 43-54.

Nair PKR, Kumar BM, Nair VD. 2009. Agroforestry as a strategy for carbon sequestration. Journal Plant Nutritious Soil Science 172, 10.

Nair PKR. 2011. Agroforestry systems and environmental quality: Introduction. Journal Environmental Qualilty 40, 784–790.

Rahman AG, Bhabha SH, Gandhi AR, Murthy NR, Anand AK. 2016. Effect of spacing and fertility levels on growth and yield of wheat (Triticum aestivum L.) under different tree species in Terai region. International Journal of Agro forestry and Silviculture 3(4), 171-178.

Schoeneberger M, Bentrup G, de Gooijer H,Soolanayakanahally   R,  Sauer T, Brandle J, Zhou X, Current D. 2012. Branching out: agroforestry as a climate change mitigation and adaptation tool for agriculture. Journal of Soil and Water Conservation 67(5), 128A–136A.

Thorvaldsson G, Björnsson H, Hermannsson J. 2005.The influence of weather on early growth rate of grasses, 28512 Búvísindi, 65.

Treydte AC, van Beeck FAL, Ludwig F, Heitkoenig IMA. 2008. Improved quality of beneath‐canopy grass in South African savannas: local and seasonal variation. Journal of Vegetation Science 19, 663–670.

Udawatta RP, Krstansky JJ, Henderson GS, Garrett HE. 2002 Agroforestry practices, runoff, and nutrient loss: a paired watershed comparison. Journal of Environmental Quality 31(4), 1214–1225.

Verchot LV, Van Noordwijk M, Kandji S. 2007. Palm C. Climate change: linking adaptation and mitigation through agroforestry. Mitigation and Adaptation Strategies for Global Change 12(5), 901–918.

Yamoah CF, Agboola AA, Wilson GF, Mulongoy K. 1986. Soil properties as affected by the use of leguminous shrubs for alley cropping with maize Agriculture. Ecosystems & Environment 18, 167-177.

Gulnaz Akhtar, Mohammad Umar Farooq, Rukhsana Tariq, Imtiaz Ahmad Qamar, Tahir Zahoor Chohan, Rifat Ullah Khan.
Productivity of alley farming with the help of Leucaena leucocephala (ipil ipil) and Penniseteum purpurium (napier grass) in rain-fed condition of Potohar, Pakistan.
Int. J. Biosci. 15(3), 219-228, September 2019.
https://innspub.net/ijb/productivity-alley-farming-help-leucaena-leucocephala-ipil-ipil-penniseteum-purpurium-napier-grass-rain-fed-condition-potohar-pakistan/
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