Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
Table 1: Treatments followed in rice experiment at AMTRC, Nawalpur, Sarlahi
Table 2: Performance of different parameters of rice at AMTRC, Nawalpur, Sarlahi, Nepal (2017-18 and 2018-19)
Table 2: Continue...
Table 3: Average gross margin of two years data from different cultivation practices of rice at AMRTC, Sarlahi
Table 1: Influence of alternate wetting and drying (AWD) method of irrigation on yield attributes in transplanted rice
Table 2: Influence of AWD method of irrigation on grain and straw yield (kg ha-1) and harvest index (%) in transplanted rice
Figure 1: Grain yield (kg ha-1) and water productivity (kg m-3) comparison in alternate wettingand drying (AWD) and submerged condition (control)
Table 3: Comparison of water inputs as influenced by irrigation method in transplanted rice
Figure 2: Water inputs under alternate wetting and drying (AWD) and submerged condition
Figure 3: Percentage of water saved over control under alternate wetting and drying (AWD)
People also read
Animal Resource management
Anti-trypanosomal Potential of Methanolic Extract of Calotropis gigantea Leaves against Trypanosma evansi and its Cytotoxicity
P. Shaba, N. N. Pandey, O. P. Sharma, J. R. Rao and R. K. SinghCalotropis gigantea leaves, anti-trypanosomal activity, cytotoxicity test
Published Online : 07 Mar 2011
Changes in the Chemical Properties of a Soil Impacted by Intensive Agriculture, North-eastern Mexico
F. Silva-Arredondo, M. Pando Moreno*, H. Gonzalez Rodriguez and L. Scott MoralesAgrochemicals, potato cropping, Chihuahuan desert, Mexican plateau
Published Online : 07 Jun 2013
Effects of NPK Fertilizers, Household Waste Compost and Poultry Manure on Soil Fertility and Nutrient Uptake by Maize (Zea mays L.)
N. Hossain, M. G. Kibria and K.T. OsmanCompost, household waste, uptake, nutrient
Published Online : 07 Jun 2013
Full Research
Morphological and Molecular Variability of Rhizoctonia solani Isolates Causing Banded Leaf and Sheath Blight in Maize
M. Madhavi, P. Narayan Reddy, R. Ranga Reddy and S. Sokka ReddyRhizoctonia solani, morphological variability, PCA, genetic variability
Published Online : 07 Jun 2015
Effect of Tillage and Organic Manures on Soil Moisture and Performance of Rainfed Groundnut (Arachis hypogea L.)
D. P. Sanepara, P. D. Vekariya, V. D. Vora, M. S. Gajera and K. N. AkbariDeep tillage, FYM, soil moisture, groundnut yield, economics
Published Online : 07 Aug 2015
Research Article
Growth, Yield and Quality of Soybean [Glycine max (L.) Merr.] as Influenced by Weed Management and Fertility Levels in Vertisols of S-E Rajasthan
Chaman Kumari Jadon, L. N. Dashora, S. N. Meena and Pratap SinghSoybean, weed management, fertility, productivity, quality
Published Online : 01 May 2019
.jpg)
.jpg)
