Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
Table 1: Physical and hydro-physical properties of the experimental soil
Table 2: Effect of different levels of irrigation and phosphorus application on seed yield (t ha-1) of broad bean
Table 3: Components of soil water balance and water use f broad bean under different levels of irrigation and phosphorus application during 2009-10, 2010-11 and 2011-12
Table 4: Components of soil water balance, crop water use (CWU) and water use efficiency (WUE) of broad bean under different levels of irrigation and phosphorous application (average data of 3 years)
Figure 1: Relationship between seasonal irrigation water applied (x) and seed yield (y) of broad bean for different irrigation schedules (average data of 3 years)
Figure 2: Relationship between dose of P application (x) and seed yield (y) of broad bean (average data of 3 years)
Table 5: Moisture extraction pattern (%) at different soil depths as influenced by different levels of irrigation and phosphorus application (average data of 3 years)
Table 6: Economic analysis of broad bean under different levels of irrigation and phosphorus application (average data of 3 years)
Figure 3: Relationships of seasonal irrigation water applied (x) with net return and benefit-cost ratio (y) of broad bean for different irrigation schedules (average data of 3 years)
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