Influence of Tillage Systems and Selective Herbicides on Weed Management and Productivity of Direct-Seeded Rice (<i>Oryza sativa</i>)

ABBAS, A.; KHALIQ, A.; SAQIB, M.; MAJEED, M.Z.; ULLAH, S.; HAROON, M.

doi:10.1590/S0100-83582019370100083

ABSTRACT:

Weeds cause considerable damage to rice crop. To ascertain the influence of different weed management practices under different tillage systems, a field experiment was conducted during 2014-15. Experimental design was RCB with split-plot arrangement and with a net plot size of 6 x 2 m. Three tillage systems viz; zero tillage with glyphosate application and conventional tillage with and without stale seed bed, and seven weed management treatments viz; weedy check, manual weeding, oxadiargyl as pre-emergence, pyrazosulfuron as pre-emergence, pyrazosulfuron as post-emergence, fenoxaprop-ethyle + sodium fluoride as post-emergence and fenoxaprop-ethyle + sodium fluoride as post-emergence. Results revealed that all treatments including tillage systems and herbicides significantly (p<0.05) affected weed density and weed dry biomass. Minimum weed density (229.22, 159.22 and 127.77 m-2) and weed dry biomass (68.01, 49.29 and 41.08 g m-2) at 30, 45 and 60 DAS (days after sowing) were recorded for pyrazosulfuron (as pre-emergence), respectively, followed by fenoxaprop-ethyle + sodium fluoride (as post-emergence). Maximum 1000-kernel weight and kernel yield (19.15 g and 3.45 ton ha-1) were recorded for weed free treatments and it was 12 and 57% higher than weedy check. Maximum net benefit and benefit to cost ratio (USD$ 817 ha-1 and 1.76, respectively) were recorded for pyrazosulfuron applied at either pre- or post-emergence stage under zero tillage system. Conclusively, pyrazosulfuron (as pre-emergence) and fenoxaprop-ethyle + sodium fluoride (as post-emergence) gave the best weed control under conventional tillage with stale seed bed system, while pyrazosulfuron exhibited maximum benefit-cost ratio under zero tillage system.

Keywords:
Oryza sativa L.; direct-seeded rice; tillage systems; herbicides; integrated weed management

RESUMO:

Plantas daninhas causam dano considerável à colheita de arroz. Para averiguar a influência de diferentes práticas de manejo de plantas daninhas sob diferentes sistemas de cultivo, um teste de campo foi conduzido durante 2014 -15. Como desenho experimental foram utilizados blocos inteiramente casualizados com parcelas subdivididas, cada uma de 6 x 2 m. Foram testados três sistemas de culitivo: plantio direto com aplicação de glifosato, cultivo convencional com pré-germinação de plantas daninhas (“stale seedbed tecnique”) e cultivo convencional sem pré-germinação de plantas daninhas. Sete tratamentos de manejo de plantas daninhas foram aplicados: “weedy check (controle com ervas daninhas)”, controle manual, oxidiargil pre-emergência, pyrazosulfuron pré-emergência, pyrazosulfuron pós-emergência, fenaxapropetil + sódio fluorido pós-emergência. Resultados revelaram que todos os tratamentos inclusive sistemas cultivo e herbicidas afetaram significativamente (p<0.05) a densidade e a biomassa seca de plantas daninhas. A menor densidade (i.e. 229.22, 159.22 e 127.77 m-2) e menor biomassa seca (i.e. 68.01, 49.29 e 41.08 g m-2) de plantas daninhas foram registradas em 30, 45 e 60 (dias após semeadura) para pyrazosulfuron (como pré-emergência), respectivamente, seguido por fenoxapropetil + sódio fluoreto (como pós-emergência). O peso máximo de 1000 grãos e máxima produção (i.e. 19.15 g e 3.45 t ha-1) foram registrados para tratamentos livres de plantas daninhas, que produziram 12 e 57% mais do que “weedy check”. Máximo benefício líquido e maior relação benef)cio/custo (i.e. USD 817 ha-1 e 1.76, respectivamente) foram registrados para pirazosulfuron aplicado tanto em pré como em pós-emergência sob plantio direto. Finalmente, pirazosulfuron (pré-emergência) e fenoxapropetil + fluoreto de sódio (pós-emergência) foram os tratamentos mais eficientes para controle de plantas danihas sob cultivo convencional com pré-germinação de plantas daninhas, enquanto pirazosulfuron proprocionou o melhor benef)cio/custo sob plantio direto.

Palavras-chaves:
Oryza sativa L.; arroz em semeadura direta; sistemas de cultivo; herbicidas; manejo integrado de plantas daninhas

INTRODUCTION

Rice is consumed as a staple food by more than half of the world population (Chauhan and Johnson, 2011Chauhan BS, Johnson DE. Growth response of direct-seeded rice to oxadiazon and bispyribac-sodium in aerobic and saturated soils. Weed Sci. 2011;59:119-22.). It is the primary source of revenue and livelihood for more than 100 million families in Asia and Africa (FAO, 2004Food and Agriculture Organization of the United Nations - FAO. Rice and us. 2004. [accessed on: 20 Oct. 2015]. Available at: Available at: http://www.fao.org/ rice2004/en/aboutrice.htm .
http://www.fao.org/ rice2004/en/aboutric... ). Conventionally, using transplanting technique for rice cultivation in which first rice nursery is growing on beds and then nursery seedling are transplanted after 30-40 days and flooded field (Ehsanullah et al., 2007Ehsanullah N, Akbar N, Jabran k, Habib T. Comparison of different planting methods for optimization of plant population of rice (Oryza sativa L.) in Punjab (Pakistan). Pak J Agric Sci. 2007;44:597-99.; Chauhan, 2012). This method not only suppresses weeds but also provides an enhanced growing environment to the rice plants. However, this transplanting method usually needs a large quantity of water available to the crop for the entire growth period (Bhushan et al., 2007Bhushan L, Ladha JK, Gupta RK, Singh S, Tirol-Padre A, Saharawat YS, et al. Saving of water and labour in a rice-wheat system with no-tillage and direct seeding technologies. Agron J. 2007;99:1288-96.; Rao et al., 2007; Chauhan and Johnson, 2011; Sartori et al., 2013Sartori GMS, Marchesan E, Azevedo CF, Roso R, Coelho LL, Oliveira ML. Effects of irrigated rice sowing season and imazapyr+ imazapic time of application on rice grain yield and red rice management. Planta Daninha. 2013;31(3):631-44.). Resource conservation technologies are becoming important in rice-wheat systems because these help to reduce the cost of production (Singh et al., 2006Singh S, Bhushan L, Ladha JK, Gupta RK, Rao AN, Sivaprasad B. Weed management in dry-seeded rice (Oryza sativa) cultivated in the furrow-irrigated raised-bed planting systemergence Crop Protect. 2006;25:487-95.). Among rice growing systems, direct-seeded rice (DSR) is an alternate strategy to tackle the issues of water scarcity and labour shortage (Ladha et al., 2003Ladha JK, Dawe D, Pathak H, Padre AT, Yadav RL, Singh B, et al. How extensive are yield declines in long term rice-wheat experiments in Asia. Field Crop Res. 2003;81:159-80.; Bhushan et al., 2007; Weerakoon et al., 2011Weerakoon WMW, Mutunayake MMP, Bandara C, Rao AN, Bhandari DC, Ladha JK. Direct-seeded rice culture in Sri Lanka: lessons from farmers. Field Crop Res. 2011;121:53-63.). The yield of direct-seeded rice crop is usually at par with transplanting and the net return is higher (Singh et al., 2005).

However, in direct-seeded rice weed plants pose serious problem and cause yield loss both in terms of quantity and quality (Chauhan and Johnson, 2009Chauhan BS, Johnson DE. Influence of tillage systems on weed seedling emergence pattern in rainfed rice. Soil Till Res. 2009;106:15-21.; Chauhan and Opena, 2012Chauhan BS, Opena DJ. Effect of tillage systems and herbicides on weed emergence, weed growth, and grain yield in dry-seeded rice systems. Field Crop Res. 2012;137:56-69.; Chauhan et al., 2012; Muhammad et al., 2016Muhammad S, Muhammad I, Sajid A, Muhammad L, Maqshoof A, Nadeem A. The effect of different weed management strategies on the growth and yield of direct-seeded dry rice (Oryza sativa). Planta Daninha. 2016;34:57-64.). It has been found that weeds compete with crop plants for nutrients, water and light and cause yield losses in rice up to 4,880 kg ha-1 (Ferrero, 2003Ferrero A. Weedy rice, biological features and control. In weed management for developing countries. Rome: FAO; 2003. p.89-107.; Zhang et al., 2003Zhang W, Webster EP, Lanclos DY, Geaghan JP. Effect of weed interference duration and weed-free period on Glufosinate resistant rice (Oryza sativa).Weed Technol. 2003;17:876-80. ). Critical periods for weed control were assessed at between 10 to 32 days after sowing (DAS) in wet seeding and up to 83 DAS in dry seeding (Johnson et al., 2004Johnson DE, Wopereis MCS, Mbodj D, Diallo S, Powers S, Haefele SM. Timing of weed management and yield losses due to weeds in irrigated rice in the Sahel. Field Crop Res. 2004;85:31-42.; Sharma et al., 2006Sharma HC, Singh HB, Friesen GH. Competition from weeds and their control in direct-seeded rice. Weed Res. 2006;17:103-8.). As the weeds and rice emerge simultaneously in DSR, proper time and method of weed control remains a difficult occurrence (Khaliq and Matloob, 2011Khaliq A, Matloob A. Weed crop competition period in three fine rice cultivars under direct-seeded rice culture. Pak J Weed Sci Res. 2011;17:229-43.). An operative and early weed management tactic is essential for any DSR production technology levelling at attaining higher productivity and effectiveness (Rao et al., 2007aRao AN, Johnson DE, Sivaprasad B, Ladha JK, Mortimer AM. Weed management in direct-seeded rice. Adv Agron. 2007a;93:153-255.; Jaya-Suria et al., 2011Jaya-Suria ASM, Juraimi AS, Rahman M, Man AB, Selamat A. Efficacy and economics of different herbicides in aerobic rice systemergence. Afr J Biotechnol. 2011;10:8007-22.).

Different weed control choices are open for rice crop such as tillage systems, manual weeding, herbicides, competitive cultivars, seeding density, water management, fertilizer management, seed invigoration and mulching and all these weed control strategies are helpful to increase rice yield (Rao et al., 2007bRao AN, Johnson DE, Sivaprasad B, Ladha JK, Mortimer AM. Weed management in rice as affected by agronomic management practices in eastern India. Field Crop Res. 2007b;63:187-98.; Khaliq et al., 2012aKhaliq A, Matloob A, Ahmad N, Rasul F, Awan IU. Post-emergence chemical weed control in direct-seeded fine rice. J Anim Plant Sci. 2012a;22:1101-6.; Sana et al., 2017Sana N, Bajwa R, Javaid A, Shoaib A. Effect of biopower application on weed growth and yield of rice. Planta Daninha. 2017;35:e017164872.). Tillage operations have been an integral component of the crop husbandry, providing appropriate environment for crop cultivation, growth and development. They greatly influence the composition of particular weed communities of the area (Buhler, 1995Buhler DD. Influence of tillage system on weed population dynamics and management in corn and soybean production in the central USA Crop Sci. 1995;35:1247-57. ; Arif et al., 2007Arif M, Marwat KB, Khan MA. Effect of Tillage and zinc application methods on weed and yield of maize. Pak J Bot. 2007;39:1583-1591.). Zero tillage has been favourable practice regarding alleviating soil degradation, enhancing water use efficiency and improving crop yield and farmer monetary benefits (Gupta and Sayre, 2007Gupta RK, Sayre K. Conservation agriculture in South Asia. J Agric Sci. 2007;145:207-14.). Rice cultivation under zero tillage and reduced tillage usually reduces fuel expenditures, water losses and intensive manpower requirement, and enhance the physico-chemical characteristics of soil (Chauhan et al., 2006Chauhan BS, Gill G, Preston C. Influence of tillage systems on vertical distribution, seedling recruitment and persistence of rigid ryegrass (Lolium rigidum) seed bank. Weed Sci. 2006;54:669-76.).

In DSR, chemical control of weeds using herbicides has appeared as a promising approach for weed management. It is easy, effective and economically feasible and has been expanded rapidly over years (Mukherjee and Singh, 2005Mukherjee D, Singh RP. Effect of micro-herbicides on weed dynamics, yield and economics of transplanted rice. Indian J Agron. 2005;50(40):292-5. ; Khaliq et al., 2012aKhaliq A, Matloob A, Ahmad N, Rasul F, Awan IU. Post-emergence chemical weed control in direct-seeded fine rice. J Anim Plant Sci. 2012a;22:1101-6.). Pre- and post-emergence application of synthetic weedicides effectively suppress weeds in DSR and provide a competition free environment to the direct-seeded fine rice (Pellerin and Webster, 2004Pellerin KJ, Webster EP. Imazethapyr at different rates and timings in drill and water seeded imidazolinone-tolerant rice. Weed Technol. 2004;18:223-7.; Baloch et al., 2005Baloch MS, Hassan G, Morimoto T. Weeding techniques in transplanted and wet-seeded rice in Pakistan. Weed Biol Mang. 2005;5:190-6.; Rao et al., 2007aRao AN, Johnson DE, Sivaprasad B, Ladha JK, Mortimer AM. Weed management in direct-seeded rice. Adv Agron. 2007a;93:153-255.; Khaliq et al., 2012b). Keeping in view the importance of rice and losses due to weeds in DSR, a field experiment was carried out with the aim to estimate the efficiency of some pre- and post-emergence herbicides for weed control in the direct-seeded rice crop grown under different tillage systems and to evaluate the agronomic and economic returns of DSR under different tillage systems and weed control methods.

MATERIAL AND METHODS

Study area

Study was carried out at the Agronomic Research Farm of the University of Agriculture, Faisalabad (Punjab, Pakistan) (31o26’ N, 73o04’ E). Soil of the experimental site is Aridisol (fine-silty, mixed, hyperthermic Ustalfic, Haplargid) as per USDA classification and Haplic Yermosols according to FAO classification. The physicochemical properties of soil of the experimental site are given in Table 1. Due to high evapotranspiration, Faisalabad features an arid climate with mean annual rainfall of about 200 mm. Meteorological data during the course of entire experimentation were obtained from Agro-Meteorological Observatory, Department of Crop Physiology of the University of Agriculture, Faisalabad.

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Table 1
Physical and chemical properties of soil of experimental site

Experimental design and treatments

Experiment was laid out according to Randomized Complete Block Design with split-plot arrangement and was conducted during summer (kharif) season, 2014 and was repeated in 2015 in order to find out the efficacy of different tillage systems and herbicide treatments on weed dynamics, yield and yield component of rice. Certified seeds of rice variety Super Basmati were sown by direct-seeding technique. The experiment comprised of three tillage systems viz; zero tillage with glyphosate, conventional tillage with no stale seed bed, conventional tillage with stale bed and seven weed management treatments viz; weedy check (control plot), manual weeding, oxadiargyl (Top star 80WP) at 100 g a.i. ha-1 as pre-emergence, pyrazosulfuron (Terminator 10 WP) at 250 g a.i. ha-1 as pre-emergence (just before sowing), pyrazosulfuron (Terminator 10 WP) at 250 g a.i. ha-1 as post-emergence (seven days after sowing), oxadiargyl (Top star 80WP) as pre-emergence plus fenoxaprop-ethyle (Puma Super 7.5 EW; at 82.25 a.i. ha-1 + sodium fluoride (Sun Star 15 WG) at 200 g a.i. ha-1 as post-emergence, and pyrazosulfuron (Terminator 10 WP) as pre-emergence plus fenoxaprop-ethyle (Puma Super 7.5 EW+ sodium fluoride (Sun Star 15 WG) as post-emergence.

Data recording

Weed density and weed biomass were recorded at 30, 45 and 60 days after sowing (DAS) using randomly selected quadrats of 1 m2. Weeds within each quadrat were identified, counted and clipped off above the soil surface. Individual weeds were grouped into weed type (i.e. grasses, broad-leaved and sedges). Later on, these weed samples were oven dried at 700 oC for 72 h to determine dry biomass and for further analyses. Paddy rice yield was measured after harvesting randomly selected 1 m2 areas in each plot.

Growth

Samples for growth analysis were collected from area of 20 cm × 50 cm. Then this was separated into leaves and stems. For leaf area measurement, 2 g sample was taken from each plot leaves. Remaining samples were sun dried for 24 h then oven dried for 48 h for the calculation of other growth parameters.

Leaf area index (LAI)

Plants were harvested fortnightly from 25 cm × 25 cm area from each plot and were analysed for leaf area and dry matter accumulation. Leaf area was measured with the help of a leaf area meter. Leaf area index was calculated as the ratio of leaf area to land area (Watson, 1947Watson DJ. Comparative physiological studies on growth of field crops: I. Variation in net assimilation rate and leaf area between species and varieties, and within and between years. Ann Bot. 1947;11:41-76.).

L A I = \frac{l e a f a r e a ({c m}^{2})}{l a n d a r e a ({c m}^{2})}

Leaf area duration (days)

Leaf area duration (LAD) for the entire growing season was estimated by using the following formula of Hunt (1978Hunt R. Plant growth analysis. London: Edward Arnold; 1978.).

L A D = \{({L A I}_{1} + {L A I}_{2}) / 2\} \times (t_{2} - t_{1})

where LAD = Leaf are duration; LAI1 = Leaf area index at first harvest; LAI2 = Leaf area index at final harvest; t1 = Date of observation of first leaf area index; t2 = Date of observation of final leaf area index.

Crop growth rate (g m-2 d-1)

Crop growth rate was measured using the following formula of Hunt (1978Hunt R. Plant growth analysis. London: Edward Arnold; 1978.).

C G R = \frac{(W_{2} - W_{1})}{(t_{2} - t_{1})} \times \frac{1}{G A}

where W1 = Total dry matter at first harvest; W2 = Total dry matter at second harvest; t1 = Date of observation of first dry matter; t2 = Date of observation of second dry matter; GA = ground area (m2).

Net assimilation rate (NAR) (g m-2 d-1)

Net assimilation rate was measured by using the formula as proposed by Hunt (1978Hunt R. Plant growth analysis. London: Edward Arnold; 1978.).

N A R = \frac{T D M}{L A D}

where NAR = Net assimilation rate; TDM = Final total dry matter at harvesting; LAD = Final leaf area duration at harvesting.

Plant height (cm)

Plant height at maturity was measured with a meter rod from the base of the plant to the leaf tip. Height of 10 tillers chosen randomly was measured in each plot and was averaged.

Number of tillers (m-2)

Tillers from an area of 100 cm × 100 cm were counted at random from three different places in each plot and averaged.

Number of productive and non-productive tillers (m-2)

Tillers from an area of 100 cm × 100 cm were counted at random from three different places in each plot and averaged.

Number of spikelet’s per panicle

Ten panicles were harvested from each plot at maturity and placed in bags. After which each panicle was sketched on white paper and total number of spikelet’s per panicle were calculated and averaged.

Number of kernels per panicle

Ten panicles were harvested from each plot at maturity and threshed. Their kernel were manually counted and averaged.

Panicle length (cm)

Twenty panicles were harvested from each plot from primary tillers at maturity and panicle length was measured and averaged.

1000-kernel weight (g)

Three samples of normal kernels from each replication and from each treatment were taken and 1000 kernel weight was recorded.

Kernel yield (kg ha-1)

The clean rough rice was air dried, bulked and weighed after harvesting and threshing. The kernel weight was adjusted to 14% moisture content and the yield of clean rough rice was calculated in kg ha-1.

Straw yield (ton ha-1)

Produce of each plot was manually threshed by beating against a steel drum. The rice straw was weighed using a digital electronic balance. Weight in kg per plot was transformed into tons per hectare.

s t r a w y i e l d (ton {h a}^{- 1} = \{\frac{p l o t y i e l d (k g)}{p l o t s i z e (m^{2 -})}\}) \times \frac{1000}{1000}

Biological Yield (t ha-1)

At physiological maturity, crop was manually harvested with a sickle. The harvested crop was tied into bundles and kept in respective plots for five days for sun drying. Biological yield was recorded in kg per plot by using a digital electronic balance and converted into tons per hectare.

B i o l o g i c a l y i e l d (ton {h a}^{- 1} = \{\frac{p l o t y i e l d (k g)}{p l o t s i z e (m^{2})}\}) \times \frac{1000}{1000}

Harvest index (%)

Harvest index (HI) was calculated as the ratio of kernel yield to biological expressed as percentage as per Beadle (1993Beadle CL. Growth analysis. In: Hall DO, Scurlock JMO, Bolharnordenkampfh R, Leegood RC, Long SP, editors. Photosynthesis and production in a changing environment: a field and laboratory manual. London: Chapman and Hall; 1993. p.36-46.).

H I (%) = \{\frac{k e r n a l y i e l d}{b i o l o g i c a l y i e l d}\} \times 100

Kernel quality traits

Abortive kernels (%)

Abortive kernels are those which do not attain full size as they stop growing during early stages of kernel development though fertilization does take place. They do not permit light to pass through them and look dull.

Opaque kernels (%)

Opaque kernels are those which attain full size but lack of carbohydrates make them translucent and overall dull chalky structure due to porous filling of starch also do not allow light to pass through them. As their development stopped at later stage therefore they were bigger than abortive kernels. They did not acquire normal size because of retarded development

Normal kernels (%)

Normal kernels are those that are translucent, attain full size, allow light to pass through them and show normal starch compaction. Number of sterile spikelet’s, opaque, abortive and normal kernels from each sketch of all the treatments were counted, averaged and expressed in percentage. Total number of Spikelet’s was counted from each sketch and was averaged. The clear, translucent, normal and without chalky spots kernels were recorded by excluding all the abnormal kernels from total number of spikelet’s.

Chalky kernels (%)

Chalky kernels were separated on the basis of chalky area present on the kernels. Twenty kernels were placed in the front of light (Tungsten filament bulb) on working board. These were identified and expressed in present.

Statistical analysis

Statistix 8.1 software (Analytical software, Statistix; Tallahassee, FL, USA, 1985-2003) was used for data statistical extrapolation. Data on weed density and weed dry biomass were square root [ √√ (x þ 0.5)] transformed to improve the variance homogeneity. Analysis of variance (ANOVA) was performed to find out the effect of treatments on weed density and dry biomass and paddy rice yield parameters followed by Tukey’s honest significance difference (HSD) test at significance level of 0.05 in order to compare the differences among the treatment means.

RESULT AND DISCUSSION

Weeds infestation has been a critical issue in cultivation of agronomic crops such as rice. The study consisted of in situ evaluation of the effect of different weeds management methods fewer than three different tillage systems on weed dynamics, yield attributes and economic parameters of direct-seeded aerobic rice. The results revealed a significant effect of tillage systems and weeds management methods on all parameters studied. Tillage system and weed management affected the diversity, density and dry biomass of different weed species infesting rice crop. The dominant weed type under conventional tillage was broad-leaved weeds, while grassy (narrow-leaved) weeds were dominant under zero tillage system. Singh et al. (2005Singh Y, Singh G, Johnson D, Mortimer M. Changing from transplanted rice to direct seeding in the rice-wheat cropping system in India. In: Proceedings World Rice Research Conference. Rice is Life: Scientific Perspectives for the 21st Century, Tsukuba, Japan: 4-7 Nov., 2004. Tsukuba: 2005. p. 198-201.) reported that nutsedge Cyperus rotundus (a grassy weed) was dominant weed plant in drill sown rice under zero tillage. Similarly, diminution in density of broad leaved weeds density by herbicide applications in direct-seeded rice has been acknowledged by many previous studies (Chauhan and Opena, 2012Chauhan BS. Weed ecology and weed management strategies for dry-seeded rice in Asia. Weed Technol. 2012;26:1-13.; Joshi et al., 2015Joshi N, Singh VP, Dhyani VC, Chandra S, Guru SK. Weed management under different planting geometry in dry direct-seeded rice. Indian J Weed Sci. 2015;47:203-205.).

Weed density and dry biomass at 30 DAS, 45 DAS and 60 DAS

Data regarding weed density recorded at 30, 45 and 60 DAS (Table 2) indicated a significant (p<0.05) influence of weed management treatments on weed density whereas their interactions with tillage systems were non-significant. The maximum weed density (433.44 at 30 DAS, 262.11 at 45 DAS and 210.11 at 60 DAS.) was observed in weedy check (control). Maximum reduction in weed density up to 47, 39 and 40% against weedy check (control) was observed at 30, 45 and 60 DAS respectively, where pyrazosulfuron (pre-emergence), fenoxaprop-ethyle + sodium fluoride (post-emergence). The maximum weed dry biomass i.e. 128.61, 81.14 and 67.55 g m-2 was observed in weedy check plot at 30, 45 and 60 DAS, respectively.

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Table 2
Influence of tillage systems and weed management practices on total weed density (m2) at 30, 45 and 60 DAS in aerobic rice

Maximum reduction in weed dry biomass up to 46, 38 and 39% was observed against control plot at 30, 45 and 60 DAS respectively where pyrazosulfuron (pre-emergence), fenoxaprop-ethyle + sodium fluoride (post-emergence). In this study, weed plants were efficiently managed, both in terms of density and dry biomass by all herbicide treatments. Maximum reduction of weed density and dry biomass were recorded for pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence) i.e. Terminator followed by Puma Super + Sun Star. Khaliq et al. (2012bKhaliq A, Matloob A, Mahood S, Abbas RN, Khan MB. Seeding density and herbicide tank mixtures furnish better weed control and improve growth, yield and quality of direct-seeded fine rice. Int J Agric Biol. 2012b;14:499-508.) reported similar results that amalgamation of herbicides gave greater weed repression in aerobic rice than solitary of herbicides application. Similarly, Chauhan and Opena (2012Chauhan BS. Weed ecology and weed management strategies for dry-seeded rice in Asia. Weed Technol. 2012;26:1-13.) used chronological herbicides in aerobic rice and reported significant decreased in weed density as compared to weedy check. It was reported that combination of pre- and post-emergence herbicides applications recorded reduction in weed density over the sole application of some single herbicide (Khaliq et al., 2011Khaliq A, Matloob A, Shafique HM, Farooq M, Wahid A. Evaluating sequential application of pre and post-emergence herbicides in dry seeded fine rice. Pak J Weed Sci Res. 2011;17:111-23.).

Growth Parameters

Leaf area index (LAI) is an indicator of the size of assimilatory system of a crop. Leaf area duration (LAD) determines the importance of photosynthetic area during growth (emergence to maturity) and crop growth rate (CGR) is the rate of dry matter accumulation per unit of land area. LAI and LAD were gradually increased up to the end of grand growth stage and were affected by tillage systems and herbicide treatments (Figures 1and2). Maximum LAI and LAD were recorded for weed free plots under all tillage systems. LAI reached at peak at 3rd harvesting (75 DAS). Weedy check plots were quite pronounced regarding LAI and LAD minimum was receded at 1st harvesting stage (60 DAS) in all tillage systems. Results indicated that with the passage of time, CGR increased up to 70 DAS and then was decreased in between 70-85 DAS. Maximum CGR was showed in weed free plot under all tillage systems. CGR in all weed management treatments gradually decreased during 70-85 DAS. Among herbicides, application of pyrazosulfuron at pre-emergence stage and of pyrazosulfuron at post-emergence stage (70-85 DAS) gave the maximum CGR (Figure 3).

Figure 1
Influence of weed management treatments on Leaf Area Index (LAI) (days) in aerobic rice grown under different tillage systems.

Figure 2
Influence of weed management treatments on Leaf Area Duration (LAD) (days) in aerobic rice grown under different tillage systems.

Figure 3
Influence of weed management treatments on Crop Growth Rate (CGR) (gm-2 day-1) in aerobic rice grown under different tillage systems.

Net assimilation rate (NAR) is a dry matter produced per unit of leaf area. Figure 4 shows the pre and post-anthesis NAR. At Post-anthesis NAR showed less while Pre-anthesis NAR was higher in all treatments. Among herbicides, pyrazosulfuron at post-emergence stage and oxadiargyl at pre-emergence stage exhibited maximum pre- and post-anthesis NAR. Weed free treatment recorded moderately minimum pre- and post-anthesis NAR than other herbicide treatments (Figure 4).

Figure 4
Influence of weed management treatments on Net Assimilation Rate (NAR) (gm-2 day-1) in aerobic rice grown under different tillage systems.

In brief, maximum LAI and LAD values were exhibited by plots treated with sequential herbicide applications i.e. pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence) and oxadiargyl (pre-emergence)+ fenoxaprop-ethyle + sodium fluoride (post-emergence) and maximum CGR and NAR were observed for herbicide pyrazosulfuron (pre- and post-emergence) and minimum values were recorded in case of weedy check plots, which was most probably due to more competition of weeds and low resources availability in these plots (Khaliq et al., 2001). Among tillage systems, herbicides efficacy was higher in conventional tillage than under zero tillage system (Chauhan and Opena, 2012Chauhan BS. Weed ecology and weed management strategies for dry-seeded rice in Asia. Weed Technol. 2012;26:1-13.) and gave better yield of rice than zero tillage system. These results are in line with the findings of Chauhan et al. (2013Chauhan BS. Effect of tillage system, seeding rates, and herbicides on weed growth and grain yield in dry- seeded rice system in Philippines. Crop Protect. 2013;54:244-50. ).

Agronomic traits of rice

Data regarding total number of tillers recorded at maturity (Table 3) showed that it varied significantly (p<0.05) with weed control treatments. Partial weedy check treatment recorded minimum number of tillers. However, herbicide application and weed free treatments improved total number of tillers. Nevertheless, maximum number of tiller (414.55 m-2) was recorded in weed free treatments and was 52% more than control (196.22 m-2). Among herbicides treatments, Terminator 10 WP (pre-emergence) recorded maximum number of tillers (343.08 m-2). Application of these herbicides gave 42% more tillers as compared with weedy check treatment. However, herbicide application and weed free treatments improved total number of tillers. Nevertheless, maximum number of tiller (370 m-2) was recorded in weed free treatments and 55% more than weed check (control).

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Table 3
Influence of tillage systems and weed management practices on agronomic traits in aerobic rice

Among herbicides treatments Terminator 10 WP (pre-emergence) recorded maximum number of tillers (309.08 m-2 and46% more recorded productive tillers as compared with weedy check treatment. Nevertheless, maximum number of non-productive tillers (44 m-2) was recorded in weed free treatments and 31% more than weed check treatments. Among herbicide treatments Top star 80 WP (pre-em.) followed by Puma super 7.5 EW+ Sun star 15 EW (post-em.) recorded maximum number of non-productive of tillers (35.55 m-2) and 15% more as compared to weed check treatments. Partial weedy check treatment recorded minimum number of non-productive tillers (30 m-2).

In Conventional tillage with stale seedbed recorded significantly (p<0.05) more panicle length of 22.66 cm. Zero tillage recorded 4% less panicle length (21.59 cm) as compared to conventional tillage with stale seed bed. Minimum number of branches per panicle (8.12) was recorded in weed check plots. Weed free plots was recorded maximum number of branches per panicle (10.41) and 22% more than weed check treatments. Among the herbicides application maximum number of branches per panicle (9.72) recorded with Top star 80 WP (pre-emergence), followed by Puma super 7.5 EW+ Sun star 15 EW (post-emergence) and 17% more as compared to weed check treatments. Minimum kernels per panicle (62.78) were recorded for weed check plots. Weed free plots was recorded maximum number of kernel per panicle (83.72) and 26% more than weed check treatments. Among the herbicides application maximum kernel per panicle (75.37) recorded with Terminator 10 WP applied at pre emergence stage and 16% more number of kernels per panicle as compared to weed check treatment.

Data regarding 1000 kernel weight (g), biological yield and kernel yield varied significantly (p<0.05) for weed management treatments (Table 3). Minimum 1000 kernels weight (16.78 g) was recorded in weed check plots. Among the herbicides applied, maximum 1000 kernel weight (19.15 g) was recorded where pyrazosulfuron applied at the pre-emergence stage while fenoxaprop-ethyle + sodium fluoride (post-emergence) enhanced 1000 kernel weight by 8% over the weedy check. In addition, data regarding biological yield, the maximum value (15.58 ton ha-1) was recorded in oxadiargyl (pre-emergence), around 58% higher than that of weedy check plots, followed by pyrazosulfuron (post-emergence) (13.06 ton ha-1; Table 3). Similarly, maximum kernel yield values was recorded in oxadiargyl (pre-emergence) (3.45 ton ha-1) which is approximately 57% more than that of weedy check plots (1.45 ton ha-1). Pyrazosulfuron (pre-emergence) exhibited a kernel yield of 3.20 ton ha-1 approximately 48% higher than weedy check plots.

Quality traits of rice kernels

The application of herbicides as pre-emergence and post-emergence in aerobic rice showed performance. Herbicides treated plots showed significantly (P<005) increased plant height than weedy check most probably due to accessibility of complimentary conditions for growth produced by herbicides by eliminating weeds as described by Mann et al. (2007Mann RA, Ahmad S, Hassan G, Baloch MS. Weed management in DSR crop. Pak J Weed Sci Res. 2007;13:219-26.).

Data regarding normal, opaque, chalky and abortive kernels percentage varied significantly (p<0.05) among different weed management practices, whereas the main effect of tillage systems and their interactions with herbicides were non-significant (p<0.05) (Table 3). Weedy check treatments exhibited minimum normal kernels (43.777%). Maximum normal kernels (71.54%) were recorded for weed free treatments. Among herbicides tested, pyrazosulfuron (post-emergence) treated plots recorded higher percentage of normal kernels (64.98%) which was statistically at par with other herbicides. In case of abortive kernels, weedy check treatment scored maximum value (22.64%) and minimum abortive kernels (9.11%) were recorded for weed free treatment. Among herbicides, pyrazosulfuron (pre-emergence) treated plots gave lower percentage of abortive kernels. Similarly, regarding chalky kernels, weedy check treatments produced maximum value (17.66%) while minimum chalky kernel value (9.31%) was found for weed free treatments. Among herbicide applications, pyrazosulfuron (pre-emergence) and fenoxaprop-ethyle + sodium fluoride (post-emergence) exhibited lower chalky kernels (11.71%). Likewise, weedy check treatments scored maximum opaque kernels (18.51%) while minimum opaque kernels (10.41%) were recorded for weed free treatments. Among herbicides, maximum of opaque kernels (14.47%) were recorded for oxadiargyl (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence).

Our findings are consistent with those of Sharma et al. (2004) and Mann et al. (2007Mann RA, Ahmad S, Hassan G, Baloch MS. Weed management in DSR crop. Pak J Weed Sci Res. 2007;13:219-26.) who also reported the same trend. Treatments under both zero and conventional tillage gave higher weed control than control plots. A total number of tillers and productive tillers were relatively higher in herbicides treated plots than control plots. Mubeen et al. (2014Mubeen K, Nadeem MA, Tanveer A, Jhala AJ. Effects of seeding time and weed control mehthod in DSR (Oryza sativa L.). J Anim Plant Sci. 2014;24:534-452. ) recorded significant reduction in a number of tillers in rice due to the season-long weed. High weed control was recorded in treatments under zero and conventional tillage than control plots. Herbicides treated plots were showed maximum number of total and productive tillers than control plots. Mubeen et al. (2014) said that due to the season long weed competition reduced in number of tillers. Ahmad and Chauhan (2014Ahmad S, Chauhan BS. Performance of different herbicides in dry-seeded rice in Bangladesh. Sci World J. 2014;189-202. ) and Khaliq et al. (2012aKhaliq A, Matloob A, Ahmad N, Rasul F, Awan IU. Post-emergence chemical weed control in direct-seeded fine rice. J Anim Plant Sci. 2012a;22:1101-6.) also recorded more productive tillers and kernels per panicle in herbicides treated plots. Results of the study indicated that manual weeding and herbicides application not only increased rice yield but also improve its quality. This might be favoured by more efficient and uniform distribution of fertilizers and photo-assimilates causing more chalky, opaque, normal kernels and less abortive on direct-seeded rice (Khaliq et al., 2011, 2012).

Economic analysis and benefit cost ratio

Economic analysis is the criteria for basic determination of net benefits. The economic analysis of weed management under different tillage systems and treatments applied on DSR crop is important to be considered from farmers’ point of view as they are more interested net benefit or returns. Maximum benefit cost ratio (BCR) of 1.85 was calculated for weed free treatment under zero tillage system (Table 4). Among herbicide applications, pyrazosulfuron at post-emergence stage under zero tillage system recorded maximum (1.72) BCR. Total cost of production was less grass income than partial weedy check treatments. Hence, these showed negative values of net returns and BCR values less than 1 (0.72, 0.65 and 0.91) (Table 4).

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Table 4
Benefit cost ratio for aerobic rice under different tillage and weed management practices

Dominance analysis

On the basis of net field benefits, final recommendation for production technology cannot be specified. Dominance is a mechanism for identification of good alternatives. Data given in Table 5 indicated net field benefit of some treatments were less than those with the lower cost rendering these treatments dominated (D) and the remaining others (un-dominated).It is concluded that applications of oxadiargyl (pre-emergence) followed by fenoxaprop-ethyle + sodium fluoride (post-emergence) is an efficient approach to increase the DSR rice kernel yield under conventional tillage without stale seed bed, while herbicide pyrazosulfuron exhibits maximum net benefit (USD$ 817 ha-1) and benefit to cost ratio (1.76) under zero tillage system when applied at pre- and post-emergence stage.

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Table 5
Marginal analysis for aerobic rice under different tillage and weed management practices. (* D = dominated)

REFERENCES

Ahmad S, Chauhan BS. Performance of different herbicides in dry-seeded rice in Bangladesh. Sci World J. 2014;189-202.
Arif M, Marwat KB, Khan MA. Effect of Tillage and zinc application methods on weed and yield of maize. Pak J Bot. 2007;39:1583-1591.
Baloch MS, Hassan G, Morimoto T. Weeding techniques in transplanted and wet-seeded rice in Pakistan. Weed Biol Mang. 2005;5:190-6.
Beadle CL. Growth analysis. In: Hall DO, Scurlock JMO, Bolharnordenkampfh R, Leegood RC, Long SP, editors. Photosynthesis and production in a changing environment: a field and laboratory manual. London: Chapman and Hall; 1993. p.36-46.
Bhushan L, Ladha JK, Gupta RK, Singh S, Tirol-Padre A, Saharawat YS, et al. Saving of water and labour in a rice-wheat system with no-tillage and direct seeding technologies. Agron J. 2007;99:1288-96.
Buhler DD. Influence of tillage system on weed population dynamics and management in corn and soybean production in the central USA Crop Sci. 1995;35:1247-57.
Chauhan BS, Gill G, Preston C. Influence of tillage systems on vertical distribution, seedling recruitment and persistence of rigid ryegrass (Lolium rigidum) seed bank. Weed Sci. 2006;54:669-76.
Chauhan BS, Johnson DE. Growth response of direct-seeded rice to oxadiazon and bispyribac-sodium in aerobic and saturated soils. Weed Sci. 2011;59:119-22.
Chauhan BS, Johnson DE. Influence of tillage systems on weed seedling emergence pattern in rainfed rice. Soil Till Res. 2009;106:15-21.
Chauhan BS, Opena DJ. Effect of tillage systems and herbicides on weed emergence, weed growth, and grain yield in dry-seeded rice systems. Field Crop Res. 2012;137:56-69.
Chauhan BS. Effect of tillage system, seeding rates, and herbicides on weed growth and grain yield in dry- seeded rice system in Philippines. Crop Protect. 2013;54:244-50.
Chauhan BS. Weed ecology and weed management strategies for dry-seeded rice in Asia. Weed Technol. 2012;26:1-13.
Ehsanullah N, Akbar N, Jabran k, Habib T. Comparison of different planting methods for optimization of plant population of rice (Oryza sativa L.) in Punjab (Pakistan). Pak J Agric Sci. 2007;44:597-99.
Ferrero A. Weedy rice, biological features and control. In weed management for developing countries. Rome: FAO; 2003. p.89-107.
Food and Agriculture Organization of the United Nations - FAO. Rice and us. 2004. [accessed on: 20 Oct. 2015]. Available at: Available at: http://www.fao.org/ rice2004/en/aboutrice.htm
» http://www.fao.org/ rice2004/en/aboutrice.htm
Gupta RK, Sayre K. Conservation agriculture in South Asia. J Agric Sci. 2007;145:207-14.
Hunt R. Plant growth analysis. London: Edward Arnold; 1978.
Jaya-Suria ASM, Juraimi AS, Rahman M, Man AB, Selamat A. Efficacy and economics of different herbicides in aerobic rice systemergence. Afr J Biotechnol. 2011;10:8007-22.
Johnson DE, Wopereis MCS, Mbodj D, Diallo S, Powers S, Haefele SM. Timing of weed management and yield losses due to weeds in irrigated rice in the Sahel. Field Crop Res. 2004;85:31-42.
Joshi N, Singh VP, Dhyani VC, Chandra S, Guru SK. Weed management under different planting geometry in dry direct-seeded rice. Indian J Weed Sci. 2015;47:203-205.
Khaliq A, Matloob A, Ahmad N, Rasul F, Awan IU. Post-emergence chemical weed control in direct-seeded fine rice. J Anim Plant Sci. 2012a;22:1101-6.
Khaliq A, Matloob A, Mahood S, Abbas RN, Khan MB. Seeding density and herbicide tank mixtures furnish better weed control and improve growth, yield and quality of direct-seeded fine rice. Int J Agric Biol. 2012b;14:499-508.
Khaliq A, Matloob A, Shafique HM, Farooq M, Wahid A. Evaluating sequential application of pre and post-emergence herbicides in dry seeded fine rice. Pak J Weed Sci Res. 2011;17:111-23.
Khaliq A, Matloob A. Weed crop competition period in three fine rice cultivars under direct-seeded rice culture. Pak J Weed Sci Res. 2011;17:229-43.
Ladha JK, Dawe D, Pathak H, Padre AT, Yadav RL, Singh B, et al. How extensive are yield declines in long term rice-wheat experiments in Asia. Field Crop Res. 2003;81:159-80.
Mann RA, Ahmad S, Hassan G, Baloch MS. Weed management in DSR crop. Pak J Weed Sci Res. 2007;13:219-26.
Mubeen K, Nadeem MA, Tanveer A, Jhala AJ. Effects of seeding time and weed control mehthod in DSR (Oryza sativa L.). J Anim Plant Sci. 2014;24:534-452.
Muhammad S, Muhammad I, Sajid A, Muhammad L, Maqshoof A, Nadeem A. The effect of different weed management strategies on the growth and yield of direct-seeded dry rice (Oryza sativa). Planta Daninha. 2016;34:57-64.
Mukherjee D, Singh RP. Effect of micro-herbicides on weed dynamics, yield and economics of transplanted rice. Indian J Agron. 2005;50(40):292-5.
Pellerin KJ, Webster EP. Imazethapyr at different rates and timings in drill and water seeded imidazolinone-tolerant rice. Weed Technol. 2004;18:223-7.
Rao AN, Johnson DE, Sivaprasad B, Ladha JK, Mortimer AM. Weed management in rice as affected by agronomic management practices in eastern India. Field Crop Res. 2007b;63:187-98.
Rao AN, Johnson DE, Sivaprasad B, Ladha JK, Mortimer AM. Weed management in direct-seeded rice. Adv Agron. 2007a;93:153-255.
Sana N, Bajwa R, Javaid A, Shoaib A. Effect of biopower application on weed growth and yield of rice. Planta Daninha. 2017;35:e017164872.
Sartori GMS, Marchesan E, Azevedo CF, Roso R, Coelho LL, Oliveira ML. Effects of irrigated rice sowing season and imazapyr+ imazapic time of application on rice grain yield and red rice management. Planta Daninha. 2013;31(3):631-44.
Sharma HC, Singh HB, Friesen GH. Competition from weeds and their control in direct-seeded rice. Weed Res. 2006;17:103-8.
Singh S, Bhushan L, Ladha JK, Gupta RK, Rao AN, Sivaprasad B. Weed management in dry-seeded rice (Oryza sativa) cultivated in the furrow-irrigated raised-bed planting systemergence Crop Protect. 2006;25:487-95.
Singh Y, Singh G, Johnson D, Mortimer M. Changing from transplanted rice to direct seeding in the rice-wheat cropping system in India. In: Proceedings World Rice Research Conference. Rice is Life: Scientific Perspectives for the 21st Century, Tsukuba, Japan: 4-7 Nov., 2004. Tsukuba: 2005. p. 198-201.
Watson DJ. Comparative physiological studies on growth of field crops: I. Variation in net assimilation rate and leaf area between species and varieties, and within and between years. Ann Bot. 1947;11:41-76.
Weerakoon WMW, Mutunayake MMP, Bandara C, Rao AN, Bhandari DC, Ladha JK. Direct-seeded rice culture in Sri Lanka: lessons from farmers. Field Crop Res. 2011;121:53-63.
Zhang W, Webster EP, Lanclos DY, Geaghan JP. Effect of weed interference duration and weed-free period on Glufosinate resistant rice (Oryza sativa).Weed Technol. 2003;17:876-80.

Publication Dates

Publication in this collection
30 Sept 2019
Date of issue
2019

History

Received
06 Oct 2017
Accepted
11 May 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Ahmad S, Chauhan BS. Performance of different herbicides in dry-seeded rice in Bangladesh. Sci World J. 2014;189-202.

[2] Arif M, Marwat KB, Khan MA. Effect of Tillage and zinc application methods on weed and yield of maize. Pak J Bot. 2007;39:1583-1591.

[3] Baloch MS, Hassan G, Morimoto T. Weeding techniques in transplanted and wet-seeded rice in Pakistan. Weed Biol Mang. 2005;5:190-6.

[4] Beadle CL. Growth analysis. In: Hall DO, Scurlock JMO, Bolharnordenkampfh R, Leegood RC, Long SP, editors. Photosynthesis and production in a changing environment: a field and laboratory manual. London: Chapman and Hall; 1993. p.36-46.

[5] Bhushan L, Ladha JK, Gupta RK, Singh S, Tirol-Padre A, Saharawat YS, et al. Saving of water and labour in a rice-wheat system with no-tillage and direct seeding technologies. Agron J. 2007;99:1288-96.

[6] Buhler DD. Influence of tillage system on weed population dynamics and management in corn and soybean production in the central USA Crop Sci. 1995;35:1247-57.

[7] Chauhan BS, Gill G, Preston C. Influence of tillage systems on vertical distribution, seedling recruitment and persistence of rigid ryegrass (Lolium rigidum) seed bank. Weed Sci. 2006;54:669-76.

[8] Chauhan BS, Johnson DE. Growth response of direct-seeded rice to oxadiazon and bispyribac-sodium in aerobic and saturated soils. Weed Sci. 2011;59:119-22.

[9] Chauhan BS, Johnson DE. Influence of tillage systems on weed seedling emergence pattern in rainfed rice. Soil Till Res. 2009;106:15-21.

[10] Chauhan BS, Opena DJ. Effect of tillage systems and herbicides on weed emergence, weed growth, and grain yield in dry-seeded rice systems. Field Crop Res. 2012;137:56-69.

[11] Chauhan BS. Effect of tillage system, seeding rates, and herbicides on weed growth and grain yield in dry- seeded rice system in Philippines. Crop Protect. 2013;54:244-50.

[12] Chauhan BS. Weed ecology and weed management strategies for dry-seeded rice in Asia. Weed Technol. 2012;26:1-13.

[13] Ehsanullah N, Akbar N, Jabran k, Habib T. Comparison of different planting methods for optimization of plant population of rice (Oryza sativa L.) in Punjab (Pakistan). Pak J Agric Sci. 2007;44:597-99.

[14] Ferrero A. Weedy rice, biological features and control. In weed management for developing countries. Rome: FAO; 2003. p.89-107.

[15] Food and Agriculture Organization of the United Nations - FAO. Rice and us. 2004. [accessed on: 20 Oct. 2015]. Available at: Available at: http://www.fao.org/ rice2004/en/aboutrice.htm
» http://www.fao.org/ rice2004/en/aboutrice.htm

[16] Gupta RK, Sayre K. Conservation agriculture in South Asia. J Agric Sci. 2007;145:207-14.

[17] Hunt R. Plant growth analysis. London: Edward Arnold; 1978.

[18] Jaya-Suria ASM, Juraimi AS, Rahman M, Man AB, Selamat A. Efficacy and economics of different herbicides in aerobic rice systemergence. Afr J Biotechnol. 2011;10:8007-22.

[19] Johnson DE, Wopereis MCS, Mbodj D, Diallo S, Powers S, Haefele SM. Timing of weed management and yield losses due to weeds in irrigated rice in the Sahel. Field Crop Res. 2004;85:31-42.

[20] Joshi N, Singh VP, Dhyani VC, Chandra S, Guru SK. Weed management under different planting geometry in dry direct-seeded rice. Indian J Weed Sci. 2015;47:203-205.

[21] Khaliq A, Matloob A, Ahmad N, Rasul F, Awan IU. Post-emergence chemical weed control in direct-seeded fine rice. J Anim Plant Sci. 2012a;22:1101-6.

[22] Khaliq A, Matloob A, Mahood S, Abbas RN, Khan MB. Seeding density and herbicide tank mixtures furnish better weed control and improve growth, yield and quality of direct-seeded fine rice. Int J Agric Biol. 2012b;14:499-508.

[23] Khaliq A, Matloob A, Shafique HM, Farooq M, Wahid A. Evaluating sequential application of pre and post-emergence herbicides in dry seeded fine rice. Pak J Weed Sci Res. 2011;17:111-23.

[24] Khaliq A, Matloob A. Weed crop competition period in three fine rice cultivars under direct-seeded rice culture. Pak J Weed Sci Res. 2011;17:229-43.

[25] Ladha JK, Dawe D, Pathak H, Padre AT, Yadav RL, Singh B, et al. How extensive are yield declines in long term rice-wheat experiments in Asia. Field Crop Res. 2003;81:159-80.

[26] Mann RA, Ahmad S, Hassan G, Baloch MS. Weed management in DSR crop. Pak J Weed Sci Res. 2007;13:219-26.

[27] Mubeen K, Nadeem MA, Tanveer A, Jhala AJ. Effects of seeding time and weed control mehthod in DSR (Oryza sativa L.). J Anim Plant Sci. 2014;24:534-452.

[28] Muhammad S, Muhammad I, Sajid A, Muhammad L, Maqshoof A, Nadeem A. The effect of different weed management strategies on the growth and yield of direct-seeded dry rice (Oryza sativa). Planta Daninha. 2016;34:57-64.

[29] Mukherjee D, Singh RP. Effect of micro-herbicides on weed dynamics, yield and economics of transplanted rice. Indian J Agron. 2005;50(40):292-5.

[30] Pellerin KJ, Webster EP. Imazethapyr at different rates and timings in drill and water seeded imidazolinone-tolerant rice. Weed Technol. 2004;18:223-7.

[31] Rao AN, Johnson DE, Sivaprasad B, Ladha JK, Mortimer AM. Weed management in rice as affected by agronomic management practices in eastern India. Field Crop Res. 2007b;63:187-98.

[32] Rao AN, Johnson DE, Sivaprasad B, Ladha JK, Mortimer AM. Weed management in direct-seeded rice. Adv Agron. 2007a;93:153-255.

[33] Sana N, Bajwa R, Javaid A, Shoaib A. Effect of biopower application on weed growth and yield of rice. Planta Daninha. 2017;35:e017164872.

[34] Sartori GMS, Marchesan E, Azevedo CF, Roso R, Coelho LL, Oliveira ML. Effects of irrigated rice sowing season and imazapyr+ imazapic time of application on rice grain yield and red rice management. Planta Daninha. 2013;31(3):631-44.

[35] Sharma HC, Singh HB, Friesen GH. Competition from weeds and their control in direct-seeded rice. Weed Res. 2006;17:103-8.

[36] Singh S, Bhushan L, Ladha JK, Gupta RK, Rao AN, Sivaprasad B. Weed management in dry-seeded rice (Oryza sativa) cultivated in the furrow-irrigated raised-bed planting systemergence Crop Protect. 2006;25:487-95.

[37] Singh Y, Singh G, Johnson D, Mortimer M. Changing from transplanted rice to direct seeding in the rice-wheat cropping system in India. In: Proceedings World Rice Research Conference. Rice is Life: Scientific Perspectives for the 21st Century, Tsukuba, Japan: 4-7 Nov., 2004. Tsukuba: 2005. p. 198-201.

[38] Watson DJ. Comparative physiological studies on growth of field crops: I. Variation in net assimilation rate and leaf area between species and varieties, and within and between years. Ann Bot. 1947;11:41-76.

[39] Weerakoon WMW, Mutunayake MMP, Bandara C, Rao AN, Bhandari DC, Ladha JK. Direct-seeded rice culture in Sri Lanka: lessons from farmers. Field Crop Res. 2011;121:53-63.

[40] Zhang W, Webster EP, Lanclos DY, Geaghan JP. Effect of weed interference duration and weed-free period on Glufosinate resistant rice (Oryza sativa).Weed Technol. 2003;17:876-80.

Parameter	Value	Status
Texture class	Sandy loam soil	Medium Hard
EC (dSm^-1)	0.43	Non Saline
pH	8.4	Medium Alkaline
Exchangeable Sodium (me100 g^-1)	0.9	Medium
Organic Matter (%)	1.00	Medium
Nitrogen (%)	0.77	Medium
Phosphorus (ppm)	120	High
Exchangeable K (ppm)	104	Medium

Treatment	Weed density (m²)			Dry weed biomass (g m²)
Tillage systems	30 DAS	45 DAS	60 DAS	30 DAS	45 DAS	60 DAS
Zero tillage	313.89	191.22	163.17	93.14	59.20	52.47
Conventional tillage without stale seed bed	311.56	183.72	162.00	92.45	56.88	52.09
Conventional tillage with stale seed bed	316.22	213.44	153.28	93.83	66.08	52.09
Weed management practices
Weedy check	433.44 A	262.11 A	210.11 A	128.61 A	81.14 A	67.55 A
Oxadiargyl (pre-emergence)	322.33 B	203.22 B	169.55 B	95.64 B	62.91 B	54.51 B
Pyrazosulfuron (pre-emergence)	335.33 B	182.11 BC	161.22 B	99.50 B	56.38 BC	51.83 B
Pyrazosulfuron (post-emergence)	315.55 BC	202.11 B	153.55 B	93.63 BC	62.57 B	49.37 B
Oxadiargyl (pre- emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	247.44 BC	168 C	134.66 C	73.42 BC	52.01 C	43.30 C
Pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	229.22 C	159.22 C	127.77 C	68.01 C	49.29 C	41.08 C

Tillage system	Weed control treatment	Variable cost (USD$ ha^-1)	Fixed cost (USD$ ha^-1)	Total cost (USD$ ha^-1)	Gross income (USD$ ha^-1)	Net field benefit (USD$ ha^-1)	Net return (USD$ ha^-1)	BCR (%)
Zero tillage	Weedy check	55.75	826.38	882.13	631.20	575.45	-250.93	0.72
	Weed free	145.75	826.38	972.13	1802.70	1656.95	830.57	1.85
	Oxadiargyl (pre-emergence)	54.25	826.38	880.63	1480.50	1426.25	599.87	1.68
	Pyrazosulfuron (pre-emergence)	56.25	826.38	882.63	1485.90	1429.65	603.27	1.68
	Pyrazosulfuron (post-emergence)	56.25	826.38	882.63	1555.20	1498.95	672.57	1.76
	Oxadiargyl (pre- emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	82.75	826.38	909.13	1498.50	1415.75	589.37	1.65
	Pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	84.75	826.38	911.13	1449.90	1365.15	538.77	1.59
Conventional tillage with stale seed bed	Weedy check	105.00	82638	931.38	609.00	504.00	-322.38	0.65
	Weed free	195.00	826.38	1021.38	1535.40	1340.40	514.02	1.50
	Oxadiargyl (pre-emergence)	103.50	826.38	929.88	1558.80	1455.30	628.92	1.68
	Pyrazosulfuron (pre-emergence)	105.50	826.38	931.88	1406.70	1301.20	474.82	1.51
	Pyrazosulfuron (post-emergence)	105.50	826.38	931.88	1462.50	1357.00	530.62	1.57
	Oxadiargyl (pre- emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	132.00	826.38	958.38	1483.20	1351.20	524.82	1.55
	Pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	134.00	826.38	960.38	1567.80	1433.80	607.42	1.63
Conventional tillage without stale seed bed	Weedy check	125.00	826.38	951.38	868.80	743.80	-82.58	0.91
	Weed free	215.00	826.38	1041.38	1649.70	1434.70	608.32	1.58
	Oxadiargyl (pre-emergence)	123.50	826.38	949.88	1528.20	1404.70	578.32	1.61
	Pyrazosulfuron (pre-emergence)	125.50	826.38	951.88	1525.50	1400.00	573.62	1.60
	Pyrazosulfuron (post-emergence)	125.50	826.38	951.88	1484.10	1358.60	532.22	1.56
	Oxadiargyl (pre- emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	152.00	826.38	97838	1478.70	1326.70	500.32	1.51
	Pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	154.00	826.38	98038	1478.70	1324.70	498.32	1.51

Tillage system	Weed control treatment	Variable cost (USD$ ha^-1)	Net field benefit (USD$ ha^-1)	Marginal cost (USD$ ha^-1)	Marginal net benefit (USD$ ha^-1)	Marginal rate of return (%)
Zero tillage	Weedy check	55.75	575.45			D*
	Oxadiargyl (pre-emergence)	54.25	1426.25
	Pyrazosulfuron (pre-emergence)	56.25	1429.65	0.50	854.20	1708.42
	Pyrazosulfuron (post-emergence)	56.25	1498.95		69.30	D
	Oxadiargyl (pre- emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	82.75	1415.75	26.50		D
	Pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	84.75	1365.15		D	D
	Weed free	145.75	1656.95	61.00	291.80	4.78
Conventional tillage with stale seed bed	Weedy check	105.00	504.00			D
	Oxadiargyl (pre-emergence)	103.50	1455.30
	Pyrazosulfuron (pre-emergence)	105.50	1301.20		797.20
	Pyrazosulfuron (post-emergence)	105.50	1357.00			D
	Oxadiargyl (pre- emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	132.00	1351.20
	Pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	134.00	1433.80			D
	Weed free	195.00	1340.40			D
Conventional tillage without stale seed bed	Weedy check	125.00	743.80			D
	Oxadiargyl (pre-emergence)	123.50	1404.70
	Pyrazosulfuron (pre-emergence)	125.50	1358.60		614.80	D
	Pyrazosulfuron (post-emergence)	125.50	1400.00	0.50	41.40	8280
	Oxadiargyl (pre- emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	152.00	1326.70			D
	Pyrazosulfuron (pre-emergence) + fenoxaprop-ethyle + sodium fluoride (post-emergence)	154.00	1324.70			D
	Weed free	215.00	1434.70	61.00	110.00	180.33

Brasil

Brasil

Influence of Tillage Systems and Selective Herbicides on Weed Management and Productivity of Direct-Seeded Rice (Oryza sativa)

Efeito de Sistemas de Cultivo e Herbicidas Seletivos no Manejo de Plantas Daninhas e na Produtividade de Arroz em Semeadura Direta (Oryza sativa)

ABSTRACT:

RESUMO:

INTRODUCTION

MATERIAL AND METHODS

Study area

Experimental design and treatments

Data recording

Growth

Leaf area index (LAI)

Leaf area duration (days)

Crop growth rate (g m-2 d-1)

Net assimilation rate (NAR) (g m-2 d-1)

Plant height (cm)

Number of tillers (m-2)

Number of productive and non-productive tillers (m-2)

Number of spikelet’s per panicle

Number of kernels per panicle

Panicle length (cm)

1000-kernel weight (g)

Kernel yield (kg ha-1)

Straw yield (ton ha-1)

Biological Yield (t ha-1)

Harvest index (%)

Kernel quality traits

Abortive kernels (%)

Opaque kernels (%)

Normal kernels (%)

Chalky kernels (%)

Statistical analysis

RESULT AND DISCUSSION

Weed density and dry biomass at 30 DAS, 45 DAS and 60 DAS

Growth Parameters

Agronomic traits of rice

Quality traits of rice kernels

Economic analysis and benefit cost ratio

Dominance analysis

REFERENCES

Publication Dates

History