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2. Site-Specific Fertilizer Nitrogen Management Using Optical Sensor in Irrigated Wheat in the Northwestern India

Author

Yadvinder-Singh, R. K. Gupta, Varinderpal-Singh, Ajay Kumar, Bijay-Singh, Monika Vashistha, O. P. Choudhary, and H. S. Thind

Subjects
0106 biological sciences, Irrigation, Crop yield, Sowing, 04 agricultural and veterinary sciences, Plant Science, engineering.material, 01 natural sciences, Crop, Nitrogen fertilizer, Agronomy, Yield (wine), 040103 agronomy & agriculture, engineering, 0401 agriculture, forestry, and fisheries, Stage (hydrology), Fertilizer, Agronomy and Crop Science, 010606 plant biology & botany, Food Science, Mathematics
Abstract

An optical sensor-based fertilizer nitrogen (N) management strategy that relies on visible and near-infrared spectral response from plant canopies was evaluated for irrigated wheat in the northwestern India. GreenSeeker™ optical sensor-guided fertilizer N dose, computed from an estimate of potential yield and response index, takes into account both the temporal and field-to-field variabilities and is applied only once after measuring in-season spectral response from the crop canopy. Seven field experiments were conducted in four wheat seasons to decide whether to apply the optical sensor-guided fertilizer N dose at 2nd or 3rd irrigation stage and to work out the appropriate N management before applying it. Robust relationships between in-season sensor-based estimates of yield and actual wheat yields were observed both at 2nd (R 2 = 0.64) and 3rd (R 2 = 0.86) irrigation stages of the crop. GreenSeeker-based fertilizer N management resulted in high yield levels and high N-use efficiency. Application of 30 kg N ha−1 at planting and 45 kg N ha−1 at 1st irrigation was found to be the appropriate N management before applying the GreenSeeker-guided dose at 2nd irrigation stage. Grain yields obtained by following sensor-guided N management were at par with those observed with the blanket recommendation of 120 kg N ha−1, but with greater recovery efficiency (by 6.7–16.2%) and agronomic efficiency [by 4.7–9.4 kg grain (kg N applied)−1]. The major outcome of this study was that applying a moderate amount of fertilizer N at planting and enough fertilizer N to meet the high N demand during the period between crown root initiation stage and maximum tillering stage before applying a sensor-guided fertilizer N dose at 2nd irrigation stage results not only in high yields but also in high fertilizer N-use efficiency in irrigated wheat.

Published
2017

3. Fertilizer Nitrogen Management in Irrigated Transplanted Rice Using Dynamic Threshold Greenness of Leaves

Author

Ajay Kumar, R. K. Gupta, Varinderpal-Singh, Monika Vashistha, Yadvinder-Singh, Bijay-Singh, Jagmohan-Singh, and H. S. Thind

Subjects
0106 biological sciences, Oryza sativa, Rice grain, 04 agricultural and veterinary sciences, Plant Science, engineering.material, 01 natural sciences, Nitrogen fertilizer, Agronomy, N application, 040103 agronomy & agriculture, engineering, 0401 agriculture, forestry, and fisheries, Grain yield, Fertilizer, Cultivar, N management, Agronomy and Crop Science, 010606 plant biology & botany, Food Science, Mathematics
Abstract

Application of fertilizer N doses to rice (Oryza sativa L.) whenever leaf greenness as measured by chlorophyll meter (SPAD) and LCC falls below a fixed threshold is being extensively used for site-specific management of fertilizer N. As fixed threshold greenness varies with regions, rice cultivars and seasons, a dynamic threshold greenness concept in the form of SPAD-based sufficiency index has been introduced. For rice, the dynamic threshold greenness is defined as 90 % of the SPAD meter reading of leaves in an Nrich or over fertilized strip. In the present investigation, four field experiments with six cultivars were conducted at two locations to test fertilizer N management following two variants of the LCC-based dynamic threshold greenness concept—the leaf greenness one or 0.5 unit less than the LCC reading of the Nrich strip (LCC-Nrich), vis-a-vis SPAD meter-based sufficiency index approach and blanket recommendation of 120 kg N ha−1 applied in three equal split doses. The fertilizer N management following threshold greenness of one unit less than the LCC-Nrich resulted in total N application of only 60 kg ha−1 and thus sub-optimum rice grain yields. The grain yield of rice, N uptake and fertilizer N use efficiency measured with N management following threshold leaf greenness of 0.5 units less than LCC-Nrich were at par with the SPAD meter-based 90 % sufficiency index approach and were better than the blanket fertilizer recommendation in the region. The LCC-based dynamic threshold greenness strategy holds promise to efficiently manage fertilizer N rice as it can effectively take care of variations in the rice cultivars, locations and seasons.

Published
2016

4. Site-specific fertilizer nitrogen management in irrigated transplanted rice (Oryza sativa) using an optical sensor

Author

Monika Vashistha, Varinderpal-Singh, H. S. Khurana, H. S. Thind, H. S. Uppal, Jagmohan-Singh, Parvesh Chandna, Raj K. Gupta, Yadvinder-Singh, R.K. Sharma, R. K. Gupta, Rajneet K. Uppal, Jaspreet Purba, M.L. Jat, Ajay Kumar, Bijay-Singh, and O. P. Chaudhary

Subjects
Oryza sativa, food and beverages, Spectral response, engineering.material, Nitrogen fertilizer, Agronomy, engineering, Grain yield, Transplanting, Fertilizer, N management, General Agricultural and Biological Sciences, Mathematics, Panicle
Abstract

Blanket fertilizer nitrogen (N) recommendations for large irrigated transplanted rice tracts lead to low N use-efficiency (NUE) due to field-to-field variability in soil N supply and seasonal variability in yield. To achieve high NUE, a fertilizer N management strategy based on visible and near-infrared spectral response from plant canopies using a GreenSeeker™ optical sensor was evaluated. Seven field experiments were conducted during 2005–2007 at two locations in the Indo-Gangetic plains of South Asia to define relationships between in-season sensor measurements at panicle initiation (PI) stage and up to 2 weeks later, and yield of rice. During 2006–2010, seven field experiments were conducted to assess the sensor-based N management strategy and to work out the prescriptive N management to be followed prior to applying sensor-guided fertilizer dose. During 2010 and 2011, the sensor- based N management strategy was evaluated versus farmers’ fertilizer practice at 19 on-farm locations. Relationships with R2 values 0.51 (n = 131), 0.45 (n = 74) and 0.49 (n = 131), respectively, were observed between in-season sensor-based estimates of yield at 42 (PI stage), 49 and 56 days after transplanting of rice and actual grain yield of rice. Applications of 30 kg N ha−1 at transplanting and 45 kg N ha−1 at active tillering stage were found to be the appropriate prescriptive strategy before applying the GreenSeeker-guided dose at PI stage. Sensor-guided N management resulted in similar grain yields as the blanket rate farmer practice, but with reduced N rates, i.e. greater recovery efficiency (by 5.5–21.7 %) and agronomic efficiency [by 4.7–11.7 kg grain (kg N applied)−1]. This study revealed that high yields coupled with high NUE in transplanted rice can be achieved by replacing blanket fertilizer recommendation by an optical sensor-based N management strategy consisting of applying a moderate amount of fertilizer N at transplanting and enough fertilizer N to meet the high N demand during the period between active tillering and PI before applying a sensor-guided fertilizer N dose at PI stage of rice.

Published
2015

5. Supplementing Fertilizer Nitrogen Application to Irrigated Wheat at Maximum Tillering Stage Using Chlorophyll Meter and Optical Sensor

Author

Satinderpal-Singh, Yadvinder-Singh, Monika Vashistha, H. S. Thind, Bijay-Singh, Varinderpal-Singh, O. P. Choudhary, Ajay-Kumar, and R. K. Gupta

Subjects
Sowing, Plant Science, engineering.material, Normalized Difference Vegetation Index, Crop, chemistry.chemical_compound, Agronomy, chemistry, Yield (wine), Chlorophyll, engineering, Cultivar, Stage (hydrology), Fertilizer, Agronomy and Crop Science, Food Science, Mathematics
Abstract

In the Indo-Gangetic plain in South Asia, fertilizer nitrogen (N) application to irrigated wheat in two split doses at planting and at crown root initiation (CRI) stages of the crop is the general recommendation. Farmers have a tendency to apply another dose of N at maximum tillering (MT) stage to avoid the risk of N deficiency. However, appropriate criteria to decide MT stage application of N are lacking. Field experiments were conducted for three seasons with four wheat cultivars to develop criteria for using a chlorophyll (SPAD) meter and an optical sensor (GreenSeekerTM) for guiding MT stage N application. Application of 0, 60, 80, 100 and 120 kg N ha−1 in two equal split doses at planting and at CRI stage constituted the main plots. The two subplots consisted of applying 0 and 30 kg N ha−1 at MT stage immediately after taking SPAD meter and GreenSeeker readings. Greenness of wheat leaves at MT stage was found to be a function of N applied at planting and CRI stages. Wheat grain yield at maturity was determined by the level of greenness of leaves at MT stage—whether measured by SPAD meter or GreenSeeker (expressed as in-season estimate of yield (INSEY) computed by dividing normalized difference vegetation index by number of days between planting and sensing). Grain yield response to N application at MT regressed against SPAD readings at MT revealed that an application of 30 kg N ha−1 will increase wheat yield by 1.0 or 0.5 t ha−1 when color of the wheat leaves was equivalent to or less than SPAD value of 32.5 or 42.5, respectively. Robust regression between grain yield response and INSEY values revealed that application of 30 kg N ha−1 at MT will lead to a grain yield increase by 1.0 or 0.5 t ha−1 if INSEY values were found to be 0.005 or 0.011, respectively. It should serve as an easy and useful criterion for applying a supplementary dose of fertilizer N at MT stage of wheat.

Published
2013

6. Land application of rice husk ash, bagasse ash and coal fly ash: Effects on crop productivity and nutrient uptake in rice–wheat system on an alkaline loamy sand

Author

Gobinder Singh, Yadvinder-Singh, H. S. Thind, Sandeep Sharma, Bijay-Singh, Varinderpal-Singh, and Monika Vashistha

Subjects
Crop, Soil health, Soil conditioner, Agronomy, Fly ash, Loam, Crop yield, Soil Science, Environmental science, Straw, Agronomy and Crop Science, Husk
Abstract

Large quantities of rice husk ash (RHA), bagasse ash (BA) and coal fly ash (FA) are available in many Asian countries as waste materials, which create a serious disposal problem. Recycling of these ashes on agricultural land can help to improve physical and chemical fertility of soil. The present field experiment was conducted for three and half years to explore the possibilities to utilize these waste materials as soil amendments to improve productivity of rice–wheat system (RWS). The treatments consisted of application of RHA and BA at 10 Mg ha−1 to either wheat or to rice or to both wheat and rice and 20 Mg ha−1 to rice alone. The rates used for FA were 15 and 30 Mg ha−1. Addition of RHA and BA significantly increased the grain yield of wheat and rice but FA caused small increases in crop yields. Direct application of RHA and BA to wheat was significantly superior than their application to rice in the RWS. Direct application of RHA and BA to wheat resulted in 25 and 24% increase in mean grain yield of wheat and 10 and 11% increase in subsequent rice crop, respectively. However, direct application to rice resulted in 8 and 11% yield increase in rice and 10 and 14% increase in subsequent wheat for RHA and BA, respectively. Application of RHA and BA at 20 Mg ha−1 to rice resulted in lower RWS productivity than that applied at 10 Mg ha−1 to wheat. There was no significant effect of these ashes on heavy metal contents in grain and straw of the 7th crop of wheat. Application of three types of ashes generally resulted in positive P balance in RWS, however, K balance remained negative. These results suggest that RHA and BA can be recycled successfully in rice–wheat system to improve its productivity with no adverse effect on soil health.

Published
2012

7. Establishment of threshold leaf colour greenness for need-based fertilizer nitrogen management in irrigated wheat (Triticum aestivum L.) using leaf colour chart

Author

H. S. Thind, Yadvinder-Singh, Varinderpal-Singh, Ajay Kumar, Monika Vashistha, Gobinder-Singh, Satwinderjit-Kaur, and Bijay-Singh

Subjects
Irrigation, Crown (botany), Soil Science, Sowing, engineering.material, Crop, Agronomy, Chart, Yield (wine), engineering, Leaf size, Fertilizer, Agronomy and Crop Science, Mathematics
Abstract

Over and untimely application of fertilizer nitrogen (N) are the major constrains in improving fertilizer N recovery efficiency in irrigated wheat ( Triticum aestivum L.). Large field to field and seasonal variability further lower fertilizer N recovery efficiency when broad based blanket recommendations are followed. Six field experiments were conducted during 2005 to 2009 at different locations to establish threshold leaf colour greenness to guide in-season need-based fertilizer N topdressings in wheat. Colour of the first top fully exposed leaf as measured by comparison with different shades of green colour on a leaf colour chart (LCC) and wheat grain yield were significantly correlated. The Cate-Nelson plot of leaf greenness expressed as LCC values against relative grain yield of 0.91 indicated that leaf greenness between LCC shade 4 and 5 may guide crop demand driven N applications in wheat. A series of experiments with progressive refinement in treatments were conducted to develop adequate need-based N management strategy using a single threshold LCC value in irrigated wheat. It was found that a dose of at least 25 kg N ha −1 should be applied at planting. At 1st irrigation (crown root initiation) stage leaf greenness cannot be quantified properly using LCC due to small leaf size and thus it did not lead to adequate fertilizer N management decision. At 2nd irrigation (maximum tillering) stage leaf colour of the first fully exposed leaf served as best indicator of inherent soil N supply as well as crop N needs and thus helped guide need-based fertilizer N top dressing for improving fertilizer N use efficiency in wheat. Fertilizer N management strategy based on application of prescriptive doses of 25 kg N ha −1 at planting and 45 kg N ha −1 at 1st irrigation and then a dose of 30 or 45 kg N ha −1 at 2nd irrigation stage depending on colour of the leaf to be ≥LCC 4 or

Published
2012

8. Fixed-time adjustable dose site-specific fertilizer nitrogen management in transplanted irrigated rice (Oryza sativa L.) in South Asia

Author

Yadvinder-Singh, Bijay-Singh, Monika Vashistha, H. S. Thind, Amit Kaul, Varinderpal-Singh, Ajay Kumar, and R. K. Gupta

Subjects
South asia, Oryza sativa, fungi, food and beverages, Soil Science, engineering.material, Nitrogen fertilizer, Agronomy, Fixed time, Yield (wine), engineering, Transplanting, Fertilizer, Cultivar, Agronomy and Crop Science, Mathematics
Abstract

In the quest of enhancing nitrogen (N) use efficiency in irrigated transplanted rice beyond that observed with blanket recommendation, leaf colour chart (LCC) is being used to apply N whenever colour of the first fully opened leaf from the top is less green than a critical colour shade. So as to avoid frequent (every 7–10 days) monitoring of leaf colour, criteria were developed to apply fertilizer N at critical growth stages of rice but by adjusting the dose of N as per colour of the leaf measured with LCC. A series of experiments were carried out at Ludhiana and Gurdaspur locations from 2007 to 2010 with treatments refined progressively to work out appropriate combination of fixed and adjustable rates of fertilizer N at critical stages of transplanted rice. A dose of 30 kg N ha −1 at transplanting as prescriptive N management proved to be adequate for achieving high yields of rice. Corrective N management consisting of adjustable N doses was worked out as application of 45, 30 or 0 kg N ha −1 depending upon leaf colour to be −1 only if leaf colour is less green than LCC shade 4 at initiation of flowering. A combination of these prescriptive and corrective N management strategies resulted in optimum rice grain yield and high N use efficiency with less fertilizer N application than the blanket recommendation. For some rice cultivars, particularly in years with favorable climate, fixed date adjustable dose N management produced yield levels higher than those achieved by applying blanket recommendation for fertilizer N and resulted in agronomic efficiency higher than 25 kg grain/kg N.

Published
2012

9. Assessment of the nitrogen management strategy using an optical sensor for irrigated wheat

Author

Harminder S. Uppal, Yadvinder-Singh, Bijay-Singh, K. L. Martin, Ramesh Kumar Sharma, O. P. Choudhary, William R. Raun, Mangi L. Jat, Parvesh Chandna, Jagmohan-Singh, Varinderpal-Singh, H. S. Thind, Harmandeep S. Khurana, Monika Vashistha, Rajneet K. Uppal, Raj K. Gupta, Ajay-Kumar, R. K. Gupta, and Jaspreet-Kaur

Subjects
[SDV.SA]Life Sciences [q-bio]/Agricultural sciences, [SDV.EE]Life Sciences [q-bio]/Ecology, environment, 2. Zero hunger, 0106 biological sciences, Irrigation, Environmental Engineering, Nitrogen management, food and beverages, Sowing, 04 agricultural and veterinary sciences, engineering.material, 01 natural sciences, Nitrogen fertilizer, Agronomy, Yield (wine), 040103 agronomy & agriculture, engineering, 0401 agriculture, forestry, and fisheries, Poaceae, Fertilizer, N management, Agronomy and Crop Science, ComputingMilieux_MISCELLANEOUS, 010606 plant biology & botany, Mathematics
Abstract

Blanket fertilizer nitrogen (N) recommendations for large irrigated wheat tracts lead to low N-use efficiency due to field-to-field variability in soil N supply and seasonal variability in yield. To achieve high N use efficiency, a site-specific N management strategy using GreenSeeker™ optical sensor was evaluated. We conducted seven field experiments during 2004–2006 at three locations to define relationships between in-season sensor measurements and yield of wheat and to know whether response of wheat to fertilizer N can be estimated by sensor measurements. During 2005–2007, four field experiments were conducted to assess the sensor-based N management strategy and to work out prescriptive N management to be followed prior to applying sensor-guided fertilizer dose. We observed robust relationships between in-season sensor-based estimates of yield at Feekes 5–6 and 7–8 stages and actual wheat yields. Response of wheat to fertilizer N defined by the sensor was highly correlated with harvest response index. Sensor-guided fertilizer N applications resulted in high yield levels and high N-use efficiency. Application of 90 kg N ha-1 at planting or in two equal doses at planting and crown root initiation stage was the appropriate prescriptive fertilizer N management. This study reveals that high N-use efficiency in irrigated wheat can be achieved by replacing blanket fertilizer recommendation by an optical sensor-based N management strategy consisting of applying moderate amount of fertilizer N at planting and crown root initiation stages and sensor-guided fertilizer N dose at Feekes 5–6 or 7–8 stages of wheat.

Published
2011

10. Calibrating the leaf colour chart for need based fertilizer nitrogen management in different maize (Zea mays L.) genotypes

Author

H. S. Thind, Yadvinder-Singh, Bijay-Singh, Ajay Kumar, Varinderpal-Singh, and Monika Vashistha

Subjects
Vegetative reproduction, Soil Science, engineering.material, Zea mays, Crop, chemistry.chemical_compound, Nitrogen fertilizer, Chart, chemistry, Agronomy, Chlorophyll, engineering, Grain yield, Fertilizer, Agronomy and Crop Science, Mathematics
Abstract

Large field to field variability restricts efficient fertilizer N management when broad based blanket recommendations are used in maize (Zea mays L.). To achieve higher yields and to avoid nitrogen (N) deficiency risks, many farmers apply fertilizer N in excess of crop requirement in maize. Field experiments were conducted for five years (2005–2009) to establish and evaluate threshold leaf colour to guide in-season need based fertilizer N topdressings in four maize genotypes. Colour (of the first top maize leaf with fully exposed collar) as measured by comparison with different shades of green colour on a leaf colour chart (LCC) and maize grain yield was significantly correlated. The Cate–Nelson plot of chlorophyll (SPAD) meter/leaf colour chart values against relative grain yield of 0.93 for the experiments conducted during first two years indicated that LCC shade 5 during vegetative growth stages and LCC shade 5.5 at silking stage (R1) can guide crop demand driven N applications in maize. Evaluation of the established threshold leaf greenness during the next three years revealed that fertilizer N management using LCC 5 starting from six-leaf (V6) stage to before R1 stage resulted in improved agronomic and N recovery efficiency in different maize genotypes. There was no response to fertilizer N application at R1 stage. The study revealed that in maize, fertilizer N can be more efficiently managed by applying fertilizer N dose based on leaf colour as measured by LCC than blanket recommendation.

Published
2011

11. Site-specific Fertilizer Nitrogen Management in Irrigated Wheat using Chlorophyll Meter (SPAD meter) in the North-western India

Author

Varinderpal Singh, Seema Sharma, Ashok Kumar, Bijay Singh, O. P. Choudhary, H. S. Thind, Yadvinder Singh, and Monika Vashistha

Subjects
010504 meteorology & atmospheric sciences, Nutrient management, Crown (botany), Soil Science, Sowing, 04 agricultural and veterinary sciences, engineering.material, 01 natural sciences, Chlorophyll meter, Crop, Agronomy, Yield (wine), 040103 agronomy & agriculture, engineering, 0401 agriculture, forestry, and fisheries, Metre, Fertilizer, Agronomy and Crop Science, 0105 earth and related environmental sciences, Mathematics
Abstract

In irrigated wheat as grown in north-western India, fertilizer nitrogen (N) management following blanket recommendations is increasing resulting in stagnant yield levels with low N use efficiency. Site-specific nutrient management strategy to apply N as per need of wheat crop was formulated based on leaf colour measured by chlorophyll meter (Minolta SPAD meter) as a function of soil N supply. The SPAD meterguided protocols for fertilizer N application at crown root initiation (CRI) and maximum tillering (MT) stages, coinciding with first two irrigations, were evaluated through a series of field experiments with seven wheat varieties in Ludhiana and Gurdaspur in north-western India. Threshold leaf greenness levels equivalent to SPAD readings

Published
2018

12. Relative performance of neem (Azadirachta indica) coated urea vis-à-vis ordinary urea applied to rice on the basis of soil test or following need based nitrogen management using leaf colour chart

Author

Ajay Kumar, Monika Vashistha, H. S. Thind, Jagmohan Singh, Yadvinder-Singh, Varinderpal-Singh, Bijay-Singh, R.S. Pannu, and R. K. Gupta

Subjects
Soil test, biology, Soil Science, chemistry.chemical_element, Azadirachta, biology.organism_classification, Nitrogen, Horticulture, chemistry.chemical_compound, Agronomy, chemistry, Coated urea, Loam, Urea, Nitrification, Transplanting, Agronomy and Crop Science, Mathematics
Abstract

Neem coated urea (NCU) applied to rice can result in high N use efficiency as it contains nitrification inhibition properties. Field experiments were conducted for three years (2005–2007) at Ludhiana (sandy loam soil) and Gurdaspur (clay loam soil) for evaluating the relative performance of NCU vis-a-vis ordinary urea as a source of N for transplanted wetland rice. Along with a no-N control, the two N sources were tried at three N levels––40, 80 and 100% of the recommended level of 120 kg N ha−1. Different doses of N were applied in three equal split doses at transplanting, 21 and 42 days after transplanting (DAT). For need based site specific N management for improved N use efficiency, the two sources of N were applied using leaf colour chart (LCC). In this treatment a basal dose of N at the rate of 20 kg N ha−1 was applied after 7 DAT and LCC readings were recorded at weekly intervals starting 14 DAT. Whenever the intensity of green colour of the first fully opened leaf from the top was less than shade 4 of the LCC, N was applied at the rate of 30 kg N ha−1.

Published
2009

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