Impact of combined application of sorghum and mulberry water extractson broad leaf weeds and yield attributes of wheat

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Research Paper 01/11/2017
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Impact of combined application of sorghum and mulberry water extractson broad leaf weeds and yield attributes of wheat

Shahbaz Khan, Sohail Irshad, Jamilur Rehman, Saeed Ahmad, Muhammad Atif Ghafoor, Ali Hassan
Int. J. Biosci.11( 5), 245-252, November 2017.
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Abstract

Wheat has prime importance being a staple food of the region. Its production is hindered by a number of factors; the most important is weed infestation. Allelopathy is an organic and environment friendly approach to control the weed infestation in agronomic crops. A field experiment was conducted to evaluate the allelopathic potential of mulberry and sorghum water extracts at different concentrations against noxious broad leaf winter weeds like Chenopodium album L. and Convolvulus arvensis L. in wheat crop. Sorghum and mulberry water extracts in different concentrations were applied 30 days after sowing (DAS) of wheat. Weedy check plot was considered as control for comparison. All the treatments significantly reduced the weed infestation but maximum C. arvensis L. density was reduced by combine application of SWE and MWE @ 18 L ha-1 of each by 49% and 56% at 45 and 60 DAS respectively. Application of sorghum water extract (SWE) @ 36 L ha-1 reduced maximum C. album density by 48% and 52% at 45 and 60 DAS respectively as compared to control. Similarly combine application of SWE and MWE @ 18 L ha-1 of each showed fairly better results regarding number of grains per spike (45) and grain weight (35.79) as compared to control. Results showed that combined application of SWE and MWE @ 18 L ha-1 of each had maximum allelopathic potential with highest net benefits while herbicide and hand weeding were uneconomical due to higher cost and lower net benefits.

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Asalam V,  Kebapci W,  Gucel S, Cetin E,  Altundag E. 2014. Land degradation in the lower Euphrates sub region of Turkey.Journal of Environmental Biology 75, 371-363.

Bhowmik PC, Inderjit J. 2003. Challenges and opportunities in implementing allelopathy for natural weed management. Crop Protection 22, 661-671.

Blackshaw RE, Odonovan JT, Harker KN, Clayton GW, Stougaard RN. 2006. Reduced herbicide doses in field crops: A review. Weed Biology & Management 6, 10-17.

Cheema ZA, Khaliq A, Akhtar S. 2001. Use of Sorgaab (Sorghum Water Extract) as a Natural Weed Inhibitor in Spring Mungbean. International Journal of Agricultureand Biology 3, 515-518.

Cheema ZA, Khaliq A, Tariq M. 2002. Evaluation of concentrated Sorghum sorgaab alone and in combination with reduced rates of three pre-emergence herbicides for weed control in cotton (Gossypium hirsutum L.) International Journal of Agriculture and Biology 4, 549–552.

Cheema ZA, Khaliq A. 2000. Use of sorghum allelopathic properties to control weeds in irrigated wheat in a semi-arid region of Punjab. Agriculture and Ecology Environment 79, 105-112.

Cheema ZA. 1988. Weed Control in wheat through sorghum allelochemicals. Ph.D. Thesis, Department of Agronomy, University of Agriculture, Faisalabad, Pakistan.

Crouzet O, Batisson I, Hoggan PB, Bonnemoy FEE, Bardot C, Poly F, Bohatier J, Mallet C. 2010. Response of soil microbial communities to the herbicide mesotrione: A dose-effect microcosm approach. Soil Biology and Biochemistry42, 193-202.

Farooq M, Jabran K, Rehman H, Hussain M. 2008. Allelopathic effects of rice on seedling development in wheat, oat, barley and berseem. Allelopathy Journal 22, 385-390.

Haq RA, Hussain M, Cheema ZA, Mushtaq MN, Farooq M. 2010. Mulberry leafwater extract inhibits bermuda grass and promotes wheat growth. Weed Biology and Management 10, 234-240.

Hassan G, Khan AI. 2007. Yield and yield components of wheat affected by wild oat Avena fatua L densities under irrigated conditions in: African crop science proceedings 8, 33-36.

Heap I. 2008. The international survey of herbicide resistant weeds. Online Internet. Available   from URL: Accessed August 2011. www.weedscience.com

Jabran K, Cheema ZA, Farooq M, Hussain M. 2010a. Lower doses of pendimethalin mixed with allelopathic crop water extracts for weed management in canola (Brassica napus). International Journal of Agriculture and Biology12, 335-340.

Kordali S, Cakir A, Akcin TA, Mete E, Akcin A. 2009. Antifungal and herbicidal properties of essential oils and n-hexane extracts of Achillea gypsicola Hub Mor. and Achillea biebersteiniiafan Asteraceae). Indian journal of Crop Production 29, 562-570.

Kudsk P, Streibig JC. 2003. Herbicides – a two-edged sword. Weed Research 43, 90-102.

Marwat KB, Saeed M, Hussain Z, Gul B, Rashid H. 2008. Study of various herbicides for weed control in wheat under irrigated conditions. Pakistan Journal of Weed Science and Research 14, 1-8.

Ozturk M, Kebapci U, Gucel S, Cetin E, Altundag E. 2012. Biodiversity and land degradation in the lower Euphrates sub region of Turkey. Journal of Environmental Biology33, 311-323.

Purvis CE, Jessop RS, Lovett JV. 1985. Selective regulation of germination and growth of annual weeds by crop residues. Weed Research 25, 415-421.

Putman AR, Defranck J. 1979. Use of phytotoxic  Plant residues for selective weed control. Crop Protection 2, 173-181.

Steel RGD, Torrie JH, Dickey D. 1997. Principles and Procedures of Statistics: A Biometrical Approach. 3rd Ed. McGraw Hill Book Co. Inc. New York, USA. 172-177.

USDA. 2017. GAIN Report Number PK1704. USDA Foreign Agricultural Service.