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Kerala Agricultural University, Thrissur

The history of agricultural education in Kerala can be traced back to the year 1896 when a scheme was evolved in the erstwhile Travancore State to train a few young men in scientific agriculture at the Demonstration Farm, Karamana, Thiruvananthapuram, presently, the Cropping Systems Research Centre under Kerala Agricultural University. Agriculture was introduced as an optional subject in the middle school classes in the State in 1922 when an Agricultural Middle School was started at Aluva, Ernakulam District. The popularity and usefulness of this school led to the starting of similar institutions at Kottarakkara and Konni in 1928 and 1931 respectively. Agriculture was later introduced as an optional subject for Intermediate Course in 1953. In 1955, the erstwhile Government of Travancore-Cochin started the Agricultural College and Research Institute at Vellayani, Thiruvananthapuram and the College of Veterinary and Animal Sciences at Mannuthy, Thrissur for imparting higher education in agricultural and veterinary sciences, respectively. These institutions were brought under the direct administrative control of the Department of Agriculture and the Department of Animal Husbandry, respectively. With the formation of Kerala State in 1956, these two colleges were affiliated to the University of Kerala. The post-graduate programmes leading to M.Sc. (Ag), M.V.Sc. and Ph.D. degrees were started in 1961, 1962 and 1965 respectively. On the recommendation of the Second National Education Commission (1964-66) headed by Dr. D.S. Kothari, the then Chairman of the University Grants Commission, one Agricultural University in each State was established. The State Agricultural Universities (SAUs) were established in India as an integral part of the National Agricultural Research System to give the much needed impetus to Agriculture Education and Research in the Country. As a result the Kerala Agricultural University (KAU) was established on 24th February 1971 by virtue of the Act 33 of 1971 and started functioning on 1st February 1972. The Kerala Agricultural University is the 15th in the series of the SAUs. In accordance with the provisions of KAU Act of 1971, the Agricultural College and Research Institute at Vellayani, and the College of Veterinary and Animal Sciences, Mannuthy, were brought under the Kerala Agricultural University. In addition, twenty one agricultural and animal husbandry research stations were also transferred to the KAU for taking up research and extension programmes on various crops, animals, birds, etc. During 2011, Kerala Agricultural University was trifurcated into Kerala Veterinary and Animal Sciences University (KVASU), Kerala University of Fisheries and Ocean Studies (KUFOS) and Kerala Agricultural University (KAU). Now the University has seven colleges (four Agriculture, one Agricultural Engineering, one Forestry, one Co-operation Banking & Management), six RARSs, seven KVKs, 15 Research Stations and 16 Research and Extension Units under the faculties of Agriculture, Agricultural Engineering and Forestry. In addition, one Academy on Climate Change Adaptation and one Institute of Agricultural Technology offering M.Sc. (Integrated) Climate Change Adaptation and Diploma in Agricultural Sciences respectively are also functioning in Kerala Agricultural University.

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2018 - 201919
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Subject: Agriculture × Author: KAU × End date: 2019 × Start date: 2018 × Type: Thesis ×
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    ThesisItemOpen Access
    Antioxidant and anticarcinogenic potential of jackfruit based ready-to-cook (RTC) curry mixes
    (Department of Community Science, College of Agriculture,Vellayani, 2019) Gayathri Mohan; KAU; Suma Divakar
    The research work entitled, “Antioxidant and anti-carcinogenic potential of jackfruit based Ready-To-Cook (RTC) curry mixes” was conducted at College of Agriculture, Vellayani during 2017-2019, with the objective to ascertain the antioxidant and anti-carcinogenic properties of the jackfruit based curry mixes (‘Avial’ mix, ‘Koottu’ mix and ‘Ularth’ mix) which were developed earlier at the Department of Community Science, using raw jackfruit (Koozha type). Methanol, ethanol, petroleum ether and acetone were used to extract the bioactive compounds of the powdered mixes for phytochemical screening, antioxidant analysis and verification of anti-carcinogenic property. The results of the phytochemical analysis indicated the presence of tannins, flavonoids, saponins, steroids, phenolic compounds, cardiac glycosides and anthraquinones in the three mixes; whereas the analyses revealed the absence of alkaloids and phlotobatinins. Quantitative analysis of antioxidants revealed that the beta carotene content of the RTC mixes was in the range of 0.07-1.16 mg/100g. Beta carotene content was found to be more in ‘Avial’ mix (1.16mg/100g). Ascorbic acid content was also found to be higher for ‘Avial’ mix (38.45 mg) and the lowest content was found for ‘Ularth’ mix (15.34 mg). The saponin content was found to be highest in ‘Avial’ mix (6.65 per cent) and lowest in ‘Ularth’ mix (5.00 per cent). The tannin content of ‘Ularth’ mix (11.57 mg) was observed to be on par with ‘Avial’ mix (11.52 mg). Total phenol content was found to be more in ‘Koottu’ mix (21.53 mg/100g) and the total flavonoid content of RTC mixes was seen to be in the range between 0.86-3.25 mg/100g. There was significant difference in the lectin content of ‘Avial’ mix (0.35%), ‘Koottu’ mix (0.56%) and ‘Ularth’ mix (0.75%). Alkaloids and selenium were found to be absent in the RTC mixes. In case of mineral analyses, Copper content was found to be higher in ‘Ularth’ mix (2.57 µg); zinc content was in the range of 4.65-6.55 µg and was found to be higher for ‘Koottu’ mix (6.55 µg) and lower for ‘Ularth’ mix (4.65 µg). Manganese content was found to be higher in ‘Koottu’ mix (5.30 µg) while, it was observed to be on par in ‘Avial’ mix (2.55 µg) and ‘Ularth’ mix (2.51 µg). The highest iron content was found in ‘Ularth’ mix (0.92 µg). Antioxidant activity in the present study revealed that ‘Avial’ mix had the highest DPPH activity with an IC50 value of 33.81 µg/ml. Total antioxidant activity was found to be more for ‘Avial’ mix (41.44 per µg/ml), followed by ‘Koottu’ mix (42.41 µg/ml) and ‘Ularth’ mix (43.45 µg/ml). ‘Avial’ mix showed more ferric reducing capacity while ‘Ularth’ mix had the least capacity in this regard. ABTS radical scavenging activities of RTC mixes ranged between 34.84-46.69 µg/ml. ABTS radical scavenging activity was observed to be higher for ‘Avial’ mix (34.84 µg/ml) and lower values were noted for ‘Ularth’ mix (40.52 µg/ml). Hydroxyl radical scavenging activity of RTC mixes was found to range between 50.55-52.55 µg/ml. ‘Avial’ mix showed higher superoxide radical scavenging activity with an IC50 value of 48.54 µg/ml and the lowest superoxide radical scavenging activity was observed in ‘Ularth’ mix (60.73 µg/ml). However, the highest nitric oxide scavenging activity was observed for ‘Ularth’ mix (14.11 µg/ml) followed by ‘Koottu’ mix (30.92 µg/ml) and ‘Avial’ mix (36.58 µg/ml). Among the three jackfruit based Ready-To-Cook (RTC) curry mixes ‘Avial’ mix was found to have higher antioxidant property and was therefore taken up for studying the anti-cancer property. Cytotoxicity of ‘Avial’ mix was estimated by MTT assay on Human breast adenocarcinoma cells (MCF-7) and 17 per cent of loss in cell viability was observed. Findings of the present study revealed that the jackfruit based RTC mixes comprised of various health promoting components such as beta carotene, ascorbic acid, saponins, tannins, total phenols, total flavonoids and lectins they also had potent antioxidant activities. Thus the curry mixes, in particular the ‘Avial’ mix can be promoted as functional food which will help to enhance its commercialization.
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    ThesisItemOpen Access
    Standardization of hydroponics fodder production technology
    (Department of Agronomy, College of Agriculture, Vellayani, 2019) Sruthi Liz Thomas; KAU; Usha C Thomas
    The study entitled “Standardization of hydroponics fodder production technology” was undertaken during 2017-2019, at College of Agriculture, Vellayani, Thiruvananthapuram, Kerala, with the objectives to identify suitable fodder crops for hydroponics system and to standardize nutrient solution, seed rate and period for harvest. Research work comprised three experiments which was carried out in a low cost hydroponics fodder production system at the Integrated Farming System Research Station, Karamana, Thiruvananthapuram. The crops were grown in a hydroponics machine made of PVC pipes with 2m x 1.3m x 1.8m length, breadth and height with four shelves and automatic sprinkler irrigation system. The first experiment was aimed to evaluate the suitability of fodder crops for hydroponics. The experiment was laid out in completely randomised design and the crops included in the trial were rice (c1), barley (c2), maize (c3), wheat (c4), sorghum (c5), bajra (c6), ragi (c7), cowpea (c8), horse gram (c9) and greengram (c10). The seeds were soaked in 0.1 per cent sodium hypochlorite solution for 12 hours, tied in gunny bag and kept for germination for 24 hours. The seeds were then transferred to trays following a seed rate of 200 g ft-2 (0.22 g cm-2). Among the crops, maize recorded the highest net income and B:C ratio. Considering yield and quality, greengram recorded significantly superior GFY (10.17 kg kg-1seed), protein content (20.97 %), the lowest values for fibre and ash, and a B:C ratio more than one. In sorghum and pearl millet, seed to green fodder yield multiplication was very poor (<3 kg). Finger millet had undesirable characters for hydroponics green fodder like lower values for shoot length, shoot weight, protein content, EE and higher values for fibre and ash. Hence, maize and greengram were identified and selected for the next experiment. The second experiment was done to standardize seed rate and period of harvest of the selected crops. Three different seed rates viz, s1 : 150 g ft-2 (1.61 kg m-2), s2: 175 gft-2 (1.88 kg m-2), s3 : 200 g ft-2 (2.15 kg cm-2) and four different period for harvest viz, t1 : 7 days, t2 : 9 days, t3 : 11 days and t4 : 13 days were adopted. But, in the case of green gram, it was observed that the crop did not survive beyond nine days in hydroponic fodder production system and hence only two periods of harvest viz, t1 and t2 were taken for green gram. Both crops were separately analysed in completely randomised design with two factors. It was observed that maize sown at 200 g ft-2 (s3) and harvested on 11th day (t3) recorded significantly higher values for GFY (6.03 kg kg-1seed) and B:C ratio. While, greengram sown at 200 g ft-2 (s3) and harvested on 7th day (t1) recorded significantly higher values for GFY (10.18 kg kg-1seed) and B:C ratio. Hence, these best combinations of seed rate and period of harvest for both the crops were selected for the next experiment. The third experiment was done to standardize nutrient solution for hydroponics fodder production. The nutrient solutions tested were n1: hoagland solution (0.25%), n2: hoagland solution (0.5%), n3: 19:19:19 (0.5%), n4 : DAP (0.5%) + KCl (0.5%), n5 : starter solution (1:2:1), n6 : vermiwash (10 times dilution), n7 : groundnut cake (supernatant solution) and n8 : water (control), which was sprayed on alternate days from 3rd day. Both crops were separately analysed in completely randomised design. In green gram, spray of hoagland solution (0.25%) (n1) resulted in higher shoot weight, root weight, root length, shoot length and GFY, but the B:C ratio was less than one. Spray of 19:19:19 (0.5%) (n3) recorded on par values with hoagland solution (0.25%) (n1) for shoot weight, root weight, root length, shoot length, GFY and a significantly higher B:C ratio. In maize, spray of hoagland solution (0.25%) (n1) resulted in higher shoot weight, root weight, root length, shoot length and GFY, but a B:C ratio of less than one. The highest B:C ratio was recorded in treatment n8 i.e, water (control). From the results, it can be concluded that both maize and greengram are suited for hydroponics fodder production. Maize grown at a seed rate of 200 g ft-2 with water and harvested on 11th day, and greengram at a seed rate of 200 g ft-2, sprayed with 19:19:19 (0.5%) and harvested on 7th day were found to give the best results considering growth parameters, yield attributes, quality and economics.
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    ThesisItemOpen Access
    Screening of pink pigmented facultative methylotroph isolates for water stress tolerance and yield in paddy
    (Department of Agricultural Microbiology, College of Agriculture, Vellayani, 2019) Riyas, N K; KAU; Meenakumari, K S
    The study entitled “Screening of Pink Pigmented Facultative Methylotroph (PPFM) isolates for water stress tolerance and yield in paddy” was undertaken during 2017-2019, in the Department of Agricultural Microbiology, College of Agriculture, Vellayani, Thiruvananthapuram, with the objective to screen the Pink Pigmented Facultative Methylotroph (PPFM) isolates for water stress tolerance and yield in paddy. The study comprised an in vitro screening experiment and a pot culture experiment with rice variety Harsha. For in vitro screening of PPFM isolates for water stress tolerance, 20 isolates of PPFM from paddy were selected from the previous study of M.Sc. (Ag.) thesis work conducted in the Department of Agricultural Microbiology, Vellayani during 2015-2017 on the basis of carotenoid pigment production, IAA production, proline content, seedling vigour index and yield. These isolates were screened by paper towel method for water stress tolerance under in vitro conditions using mannitol for inducing osmotic stress. There were 21 isolates (20 KAU isolates of PPFM and one TNAU isolate) and four water stress levels (1%, 2%, 3% mannitol and control). The experiment was laid out in completely randomized block design with two replications. Osmotic stress was higher in 3 per cent mannitol treatment. Seeds treated with PPFM 26 recorded the highest germination percentage, shoot length and seedling vigour index. The highest root length and shoot dry weight were observed with the isolate PPFM 15 whereas the highest root dry weight was recorded with PPFM 9. Scoring was done to assess the best five isolates and those with higher ranks were selected for the subsequent experiment. Consequently, PPFM 26, PPFM 15, PPFM 38, PPFM 37 and PPFM 35 which secured ranks from 1 to 5 were selected for the pot culture experiment. The pot culture experiment was undertaken to study the effect of PPFM isolates on growth and yield of paddy under water stress. The experiment was laid out in CRD with 21 treatments and three replications, during summer 2019. The treatments comprised six PPFM isolates (5 KAU isolates of PPFM and one TNAU isolate) and three moisture levels (at field capacity, 75% available water and 50% AW) and three control treatments (0.5% methanol, AMS liquid medium supplemented with 0.5% methanol and absolute control). The treatments were given as seed treatment, seedling root dip and foliar application at 15 and 30 DAT. The study revealed that PPFM isolates had significant effect on biometric parameters, physiological parameters, yield and yield attributes of paddy under water stress. Maximum plant height and leaf area index was recorded with PPFM 38 at 30 DAT and 60 DAT whereas PPFM 37 recorded maximum number of tillers per hill at 60 DAT. Leaf rolling score and leaf drying score were found to be the lowest with PPFM 37 at 30 and 60 DAT. Cell membrane integrity, relative water content, chlorophyll stability index and root dry weight were the highest with PPFM 38 at 30 and 60 DAT. Rooting depth was the highest with PPFM 38 at 30 DAT and PPFM 37 at 60 DAT. Proline content (at all the three moisture levels) and super oxide dismutase (SOD) were significantly higher with PPFM 37 at 30 and 60 DAT. While at 60 DAT, PPFM 37 recorded significantly higher catalase activity at FC and 50% AW, PPFM 38 was found to be superior at 75% AW. Both these isolates were comparable at the different moisture levels. Crop treated with PPFM 37 also recorded the lowest drought susceptibility index. However, peroxidase activity was significantly higher with PPFM 38 at all moisture levels at 30 and 60 DAT. All the PPFM isolates had significant effect on yield attributes and yield of paddy under water stress. Maximum number of panicles per hill, number of grains per panicle (at all moisture levels), grain yield and the lowest relative percentage yield reduction was recorded with PPFM 37. While, PPFM 37 recorded significantly higher number of panicles per hill at FC and 75% AW, PPFM 38 was found to be superior at 50% AW. Both these isolates were comparable at different moisture levels. Though PPFM 37 recorded higher grain yield at all the moisture levels it was on par with PPFM 38. Considering the major drought tolerance parameters such as leaf rolling score, leaf drying score, rooting depth, proline content, SOD, catalase and peroxidase, PPFM 38 was ranked first among the PPFM isolates tested in the pot culture experiment. With respect to the yield attributes and yield of rice under water stress the effect of PPFM 37 and PPFM 38 were observed to be at par. The present study revealed that the isolates PPFM 37 and PPFM 38 (seed treatment 1% PPFM broth culture + seedling dip 2% PPFM broth culture + foliar spray 1% PPFM broth culture at 15 and 30 DAT) were effective in improving the growth, yield and drought tolerance characters of rice.
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    ThesisItemOpen Access
    Evaluation of pongamia oil soap against major pests of okra, Abelmoschus esculentus (L). Moench
    (Department of Agricultural Entomology, College of Agriculture, Padannakkad, 2019) Anu Thomas; KAU; Sreekumar, K M
    The proposed study entitled, Evaluation of pongamia oil soap against major pests of okra, Abelmoschus esculentus (L). Moench was aimed at evaluating the efficacy of a new product made of pongamia oil - pongamia oil soap at different concentrations in combating the major pests of okra viz., shoot and fruit borer, leaf roller and leaf hopper. Laboratory bioassay of pongamia oil soap was carried out in the Department of Agricultural Entomology, College of Agriculture, Padannakkad, during 2018-19 to evaluate the feeding deterrency and growth retardation properties of pongamia oil soap against fourth instar and first instar larvae of bhindi leaf roller, Sylepta derogata respectively and its insecticidal property or repellent property on bhendi leaf hopper, Amrasca biguttula biguttula. The test organisms were exposed to six treatments viz., T1: Pongamia oil soap 0.6%; T2: Pongamia oil soap 1%; T3: Pongamia oil soap 2%; T4: Neem oil soap 0.6%; T5: Soap solution 0.5%; T6: control with three replications under completely randomised design (CRD). Among the different treatments, pongamia oil 2 per cent showed the maximum antifeedent activity on fourth instar larvae and maximum growth retardation activity on first instar larvae of S. derogata. Spraying of pongamia oil soap 2 per cent showed 100 per cent mortality of leaf hoppers by 16 h after the treatment. But neem oil soap 0.6 per cent and pongamia oil soap 0.6 per cent took 24 h to attain 100 per cent mortality. Field efficacy of pongamia oil soap was evaluated by randomised block design (RBD) with seven treatments and four replications on okra variety ‘Arka Anamika’ during rabi and summer seasons at the Instructional farm in College of Agriculture, Padannakkad. The treatments applied were: T1: Pongamia oil soap 0.6%; T2: Pongamia oil soap 1%; T3: Pongamia oil soap 2%; T4: Neem oil soap 0.6%; T5: Soap solution 0.5%; T6: Quinalphos 0.05% - (Standard check); T7: Control. All treatments were applied once at vegetative stage and twice during reproductive stage. Observations were taken one day prior to treatment and 1, 3, 5, 7 and 14 days after treatment (DAT) for sucking pests. Damage symptoms caused by lepidopteran pests were observed one day prior to and 7 and 14 DAT. After three sprays during the rabi season pongamia oil soap 2 per cent was superior among botanicals in reducing the leaf hopper population significantly as compared to that of control. The effectiveness against leaf hopper lasted up to seven days after treatment. By the end of the rabi season pongamia oil 2 per cent showed significant reduction in damaged leaves as compared to other botanicals whereas the damage per cent was significantly increased in control and soap solution 0.5 per cent. Damage caused by leaf roller was cut down by the treatment of pongamia oil soap 2 per cent for seven days due to its antifeedent, repellent and growth retardation activity. Mean percentage of shoots and fruits infested by okra shoot and fruit borer Earias vitella and fruit borer Helicoverpa armigera during rabi and summer season was observed lowest in pongamia oil 2 per cent among botanicals. Reduction in mean per cent of fruit and shoot damage by pongamia oil soap may be due to the feeding deterrency of pongamia oil which remained effective for seven days. However all the treatments were effective in reducing the pest infestation except soap solution 0.5 per cent. Effectiveness of pongamia oil soap was observed to decline after seven days after spray application. Higher concentration of the soap gave better results as compared to that of lower concentrations. Pongamia oil soap 2 per cent exhibited increased fruit yield and marketable yield as compared to that of control due to lower incidence of pests during both the seasons. Economics of pongamia oil soap 2 per cent in turns of cost benefit ratio was also high as compared to control in both rabi and summer seasons, making it an effective component in IPM programmes and organic farming.
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    ThesisItemOpen Access
    Evaluation of micronutrient formulation in cowpea
    (Department of Soil Science and Agricultural Chemistry, College of Agriculture, Padannakkad, 2019) Roshni John; KAU; Binitha, N K
    The project “Evaluation of micronutrient formulation in cowpea (Vigna unguiculata L. Walp)” was carried out at College of Agriculture, Padannakkad and Regional Agricultural Research Station (RARS), Pilicode during 2017 to 2019. The objectives of the study were to evaluate the effect of micronutrient formulation through seed treatment and foliar nutrition on growth, nodulation and yield of cowpea and to study its effect on plant nutrient uptake and residual soil nutrient status. Laboratory study was carried out at COA, Padannakkad to formulate and standardize the micronutrient solution for cowpea. Different concentrations of the standardized micronutrient formulation were used for seed treatment study (Experiment 1). The experiment was carried out in completely randomized design with 7 treatments and 3 replications which included seed treatment with micronutrient formulation @ 0.25, 0.50, 0.75, 1, 1.5 and 2 per cent as T1, T2, T3, T4, T5 and T6 respectively. T7 (seed treatment with water) was the control. Observations on germination percentage, number of days taken for germination, seedling length at three leaf stage and seedling vigour index were recorded. Treatment T6 (micronutrient formulation @ 2 %) showed highest seedling length (24.23 cm) and seedling vigour index (2423) which was followed by T5 (micronutrient formulation @ 1.5 %). Thus the best and second best treatment from seed treatment study was concluded as T6 and T5 respectively and was selected for the field experiment (Experiment 2). The field experiment was conducted in randomized block design with 12 treatments replicated three times. The treatment consisting of combination of four levels of seed treatment (no seed treatment, seed treatment with rhizobium, seed treatment with best concentration from experiment 1 and second best seed treatment from experiment 1) and three levels of foliar application of micronutrient (no foliar application, one foliar application at 15 DAS and two foliar applications at 15 and 30 DAS). Biometric observations were recorded at flower bud initiation and at harvest. Plant height at flower bud initiation and at harvest was superior in S3 (Seed treatment with micronutrient formulation at 2 %) while stem diameter was highest in S4 (seed treatment at 1.5 %) and S3 respectively in both stages. Double foliar spray was superior in plant height and stem diameter at both stages. Interaction S3F3 (2 per cent seed treatment plus two foliar spray) recorded highest plant height at both stages and stem diameter was highest in S2F3 (treatment with rhizobium plus two foliar spray). Number of nodules was highest in S2 (seed treatment with rhizobium). Number of pods per plant (21.02 & 20.97), pod weight per plant (36.14 g & 33.49 g), grain yield (2224 kg ha-1) and dry matter production (2292.91 & 2372.92 kg ha-1) was superior in S3 and F3 (two foliar spray). Interaction S3F3 was superior in number of pods per plant (25), pod weight per plant (38.11 g), grain yield (2320 kg ha-1) and dry matter production (2613.24 kg ha-1). Leaf analysis revealed that P and K content in leaf was highest in S3. N, P, K and Ca content in leaf was highest in F3. Interaction S3F3 recorded highest N, P and K content in cowpea leaf. Mg content was highest in S2F3 (treatment with rhizobium plus two sprays). Fe, Mn, Zn and B content in leaf was highest in S3 and F3. Interaction S3F3 (2 per cent seed treatment plus two foliar spray) recorded highest Fe, Mn and Zn content in cowpea leaves. The uptake of N, P, K, Ca, S, Fe, Mn, Zn and B were highest in both S3 and F3 whereas Mg uptake was highest in S3 and F2 (one foliar spray). Cu uptake was highest in F3. Interaction S3F3 recorded highest uptake of N, P, Mn and Zn. N content in cowpea grain was superior in S2 and F3. While K, Ca, Fe, Mn, Zn, Cu and B content in cowpea grain was highest in both S3, F3 and interaction S3F3. In case of interaction, N was highest in S2F3. The uptake of N, P, K, Ca, Mg, S, Fe, Zn and B in cowpea grain was highest in both treatments S3 and F3 and the interaction, S3F3 recorded highest uptake of P, K, Ca, Fe, Mn, Zn and B in grain. Studies on residual soil nutrient status revealed that available N and P in soil was highest in S2 at both 45 DAS and at harvest. Available K was highest in S3, F3 and S3F3 at both stages. Organic carbon content was found to increase in plots receiving two foliar spray and interaction S3F3. Available Fe, Mn and Zn was highest in S3 at harvest and in F3 at both stages. Available B was highest in S3 and F3 at 45 DAS while Mo at harvest. B and Zn were highest in S3F3 at 45 DAS while at harvest available Fe was found to be higher in S3F3. Available Fe at 45 DAS was highest in S1F3 (no seed treatment plus two foliar spray). Root CEC was superior in S3, F3 and in interaction S3F3. The results obtained from the investigation revealed that the application of micronutrient formulation as two foliar spray (15 and 30 DAS) along with seed treatment (2 per cent) was found to be highly effective in increasing the growth and yield characters of cowpea. The uptake of nutrients in cowpea leaf and grain was also found to increase with the application of micronutrient formulation enhancing the nutritional quality of grain.
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    ThesisItemOpen Access
    Productivity enhancement of rice based cropping system with pulses
    (Department of Agronomy, College of Agriculture, Padannakkad, 2019) Adarsh, S; KAU; Jacob John
    The project “Productivity enhancement of rice based cropping system with pulses” was undertaken with the objective of assessing the suitability of different pulse crops for summer fallows of double cropped lowland rice fields under varying nitrogen levels and its residual effect on the succeeding virippu rice crop. The experiment was laid out in Randomised Block Design with thirteen treatments and replicated thrice, during summer 2017-18 and virippu 2018-19 seasons. The treatments were T1 (cowpea with 100 % recommended dose of nitrogen (RDN)), T2 (cowpea with 75 % RDN), T3 (cowpea with 50 % RDN), T4 (black gram with 100 % RDN), T5 (black gram with 75 % RDN), T6 (black gram with 50 % RDN), T7 (green gram with 100 % RDN), T8 (green gram with 75 % RDN), T9 (green gram with 50 % RDN), T10 (red gram with 100 % RDN), T11 (red gram with 75 % RDN), T12 (red gram with 50 % RDN) and T13 (fallow during summer). The varieties of cowpea, black gram, green gram, red gram and rice used were PGCP 6, Co 6, Co 8, APK 1 and Uma respectively. The growth parameters, yield attributes, nutrient uptake, soil available nutrient status were recorded and economics was worked out during summer and virippu seasons. Physiological parameters of crop, composition of weeds, absolute density of weeds and nutrient removal by weeds were assessed during summer season. During summer, the height of cowpea (100 % RDN) and green gram (75 and 50 % RDN) was found superior. The number of branches per plant was found higher in cowpea (T1 and T2). Leaf area index (100 and 50 % RDN) and crop growth rate (50 % RDN) was superior in cowpea. The number of pods were significant in green gram (75 and 50 % RDN). The yield was significantly high in cowpea (50 % RDN) and it was on par in red gram. Broad-leaved weeds dominated, followed by sedge and grasses. Among grasses, sedge and broad-leaved weeds; Oryza sativa, Cyperus rotundus and Boerhavia diffusa dominated respectively. Absolute density of weeds was lesser in T11 and T12. Black gram (50 % RDN) was effective in smothering weeds. The dry matter production of weeds was highest in fallow during summer. The N and P uptake was on par in cowpea (100 and 50 % RDN) and green gram (75 and 50 % RDN). The K uptake was higher in cowpea (50 % RDN). The N removal by weeds was higher in fallow and that of P and K were on par in all treatments. The available soil nutrients showed no difference after summer crop. Gross income, net income, and B:C ratio were higher for red gram. During virippu, growth attributes, yield, and yield parameters were on par in all treatments in rice. The thousand grain weight was highest in plots where cowpea and green gram with 100 per cent RDN were grown during summer. The N uptake of rice was significant with red gram (75 % RDN). The available soil nutrients were on par in all treatments in rice. The economic parameters viz., gross returns, net returns, B:C ratio were on par among all treatments in rice. The following conclusions, which meet the objectives, can be arrived at from the study: • During summer, cowpea and red gram performed better among the different pulses, in terms of yield. However, regarding gross income, net income and B:C ratio, red gram ranked first. • There was no significant difference in yield, gross income, net income and B:C ratio of pulses under varying levels of N, thereby indicating that the lower level of N (50 % RDN) will be sufficient. It is also logical to infer that the residual effect of the preceding two crops of rice contributed to reduce N dose when pulses are raised during summer in double cropped lowlands. • Reducing the dose of N for the summer crops did not have any adverse effect on the succeeding virippu rice crop as evident from the on par yield and economics among different treatments.
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    ThesisItemOpen Access
    Dynamics of carbon stock in rice based farming systems of kari soils
    (Department of Agronomy, College of Agriculture, Padannakkad, 2019) Chethankumar, S; KAU; Devi, V S
    An investigation entitled “Soil carbon dynamics in a rice based cropping system” was carried out with the objective of assessing and comparing the soil carbon dynamics in different rice based cropping systems viz., rice-rice-maize (R- R-M), rice-rice-bhindi (R-R-B) and rice-rice-daincha (R-R-D) in a lowland riverine alluvium. The investigation was undertaken at College of Agriculture, Vellayani and Integrated Farming System Research Station (IFSRS), Karamana during 2017- 19. At IFSRS, rice based cropping sequence viz., rice (Virippu) - rice (Mundakan) - maize+ bhindi+ daincha has been practicing since 2011-12. The study was undertaken during three seasons of 2018-19 as three experiments. For experiments 1 (Virippu) and 2 (Mundakan), medium duration rice variety, Uma was cultivated. Surface soil (0-15 cm) samples were collected after each crop harvest and analyzed for soil physical, chemical and biological properties and carbon fractions. The results were compared with that of rice- rice- fallow (R- R-F) sequence. All the carbon fractions (total organic carbon [TOC], particulate organic carbon [POC] - >53 and <53 µm) except labile carbon [LC] slightly increased after Mundakan crop. On an average, TOC and POC increased by 5.9 and 5.24 per cent, respectively. There was not much variation in soil bulk density (BD), EC, available K, Ca, Mg, S, Fe, B and microbial count during both the seasons. The pH slightly increased after Mundakan, with the highest value for R-R-F (5.14) and R-R-B (5.22) sequences during Virippu and Mundakan, respectively. Available N, P, Mn, Zn, Cu, microbial biomass carbon (MBC) and enzyme activities (dehydrogenase, urease and acid phosphatase) declined nominally after Mundakan season. The lowest enzyme activities were recorded in R-R-F sequence, during both the seasons. Both paddy grain and straw were analyzed for major, secondary and micronutrients. R-R-D sequence had recorded the highest grain N (1.98 per cent) content after Virippu. K content was also highest for R-R-D sequence, after both Virippu (1.09) and Mundakan (1.42) seasons. Highest P and Ca contents were obtained with R-R-M and R-R-B sequence, respectively, after both the seasons. Micronutrient content of grain and straw were almost the same in all the systems, after both Virippu and Mundakan, Economic yield was highest for R-R-B (5.21 t ha-1) and R-R-D (4.09 t ha-1) sequence after Virippu and Mundakan, respectively. During the summer season (experiment 3), field was divided into three equal parts and planted with maize (var. Co 6), bhindi (var. Manjima) and daincha (var. TN local), respectively. Daincha at 50 per cent flowering stage and maize leaves after crop harvest were incorporated into the field. Soil samples were drawn at 15 cm intervals up to 105 cm depth and analysed for major soil parameters and carbon fractions. Plant samples were analysed for major, secondary and micro nutrients. Economic and biomass yield of R-R-B and R-R-M sequence were 9.21 and 25.1 t ha-1 and 3.6 and 7.89 t ha-1, respectively. Biomass yield of R-R-D sequence was 22.5 t ha-1. The cropping systems significantly influenced soil carbon dynamics. R-R- D sequence recorded 10, 14, 13 and 22 per cent increase in TOC, LC, POC and MBC, respectively, up to 105 cm depth compared to that of R-R-F sequence at the end of cropping cycle. Enzyme activities (dehydrogenase, urease and acid phosphatase) showed significantly higher positive correlation with the carbon fractions. Among the weather parameters, atmospheric temperature (both minimum and maximum) was found to be positively correlated with soil carbon dynamics. The role of crop residue incorporation in improving soil carbon dynamics was clearly understood from the carbon management index (CMI) value, which was highest in R-R-D (120.56) followed by R-R-M (109.31), R-R-F (106.79) and R-R- B (72.81). Except BD and available Fe and Mn, all the other soil parameters showed a declining trend with soil depth. BD ranged from 1.19 to 1.62, 1.21 to 1.73, 1.17 to 1.72 and 1.2 to 1.65 g cm-3 for R-R-B, R-R-M, R-R-D and R-R-F systems, respectively. Available Fe and Mn increased upto 30 cm depth and thereafter declined. R-R-D system resulted in the highest soil available N, K, Ca, Mg, S, B, MBC, urease, acid phosphatase, TOC, LC and POC upto 30 cm depth. pH and EC increased by 9.3 and 77 per cent, respectively in R-R-M system. Available P and Ca in the surface layer declined in R-R-B and R-R-M systems compared to R-R-F. Available Fe and Mn contents were reduced in the all systems except R-R-F. The R-R-B system had the highest available Zn and Cu compared to R-R-F (8 and 13 per cent, respectively). Microbial load, enzyme activities and MBC were negligible beyond 75 cm depth. Daincha recorded the highest N (1.47) and P (1.13) content, while the highest K (1.96), Ca (0.85) and Mg (0.21 per cent) were in bhindi. The study revealed that, among the different rice based cropping systems, R-R-D system influenced soil carbon dynamics most significantly followed by R- R-M, thereby indicating the role of crop residue incorporation particularly, green manures in improving the soil carbon sequestration potential and consequently soil health.
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    ThesisItemOpen Access
    Development of chilli (capsicum annuum l.) hybrids with leaf curl virus resistance, high yield and quality
    (Department of Vegetable Science, College of Agriculture , Vellayani, 2019) Vijeth, S; KAU; Sreelathakumary, I
    The investigation entitled “Development of chilli (Capsicum annuum L.) hybrids with leaf curl virus resistance, high yield and quality” was carried out at the Department of Vegetable Science, College of Agriculture, Vellayani, during the period of 2015-2018. The study was aimed at identification of sources for chilli leaf curl virus (ChiLCV) resistance, development of chilli hybrids with ChiLCV resistance, high yield and quality and studying the gene action of ChiLCV resistance. The investigation was conducted in four experiments. In experiment I (a), 70 chilli genotypes were evaluated for yield and quality traits. The best genotypes based on per se performance were CHIVAR-9 for plant height (73.33 cm), CHIVAR-4 for primary branches plant-1 (4.77), Jwalasakhi for days to first harvest (42.00 days), CHIVAR-7 for fruits plant-1(137.33), Vellayani Athulya for days to first flower (26.94 days), fruit length (8.50 cm), fruit girth (4.78 cm) and fruit weight (7.57 g), CA-32 for yield plant-1 and yield plot-1 (587.33 g and 16.10 kg/6.48m2 respectively), Punjab Sindhuri for vitamin C (120.33 mg 100 g-1) and Byadagi Kaddi for carotenoids (331.33 mg 100 g-1). Seven genotypes viz., CHIVAR-3 (L1), CHIVAR-7 (L2), CHIVAR-6 (L3), CA-32 (L4), Vellayani Athulya (L5), Keerthi (L6) and CHIVAR-10 (L7) were selected based on selection index ranking for utilization as lines in line (L) × tester (T) analysis. Among the 70 genotypes screened against ChiLCV under field condition [experiment I (b)], 23 were moderately susceptible, 12 each were susceptible and moderately resistant, ten were symptomless, six were resistant, five were highly resistant and two were highly susceptible. The selected ten symptomless and five highly resistant genotypes were subjected to artificial screening by using whitefly mediated and graft inoculations in experiment II (a). Six genotypes were symptomless under whitefly mediated inoculation, among which, four genotypes viz., Sel-3, Sel-4, Sel-6 and CHIVAR-1 showed highly resistant reaction under graft inoculation. The resistant genotypes identified under artificial inoculation by Polymerase Chain Reaction (PCR) using universal primers (AV494/AC1048) for the confirmation of ChiLCV. All the graft inoculated genotypes showed presence of virus. However, in the whitefly mediated inoculation, four genotypes viz., Sel-3 (T1), Sel-4 (T2), Sel-6 (T3) and CHIVAR-1 (T4) did not show any amplification for presence of virus. Hence, they were used as testers (male parent) in line (L) × tester (T) analysis. The overall disease score was higher with graft inoculation than whitefly mediated inoculation. The BLAST analysis of the amplified sequence showed 93 per cent similarity to Tomato leaf curl Karnataka virus (ToLCKV). Seven genotypes (lines) with high yield and quality attributes were crossed with four highly resistant genotypes (testers) in line (L) × tester (T) mating design in experiment III (a) to produce 28 F1 hybrids. These hybrids were evaluated along with parents and two checks (CH-27 and Arka Harita) for yield and quality attributes and ChiLCV resistance during summer in 2017 [experiment III (b)]. Based on per se performance most promising hybrids were L3 × T2, L6 × T1, L1 × T1, L7 × T1 and L3 × T1 for yield traits and L4 × T1, L4 × T2, L4 × T3 and L7 × T1 for quality traits. The superior crosses based on heterobeltosis, standard heterosis and SCA effects were L3 × T2, L1 × T1, L7 × T1, L6 × T1, L3 × T1, L2 × T4, L4 × T1, L5 × T3 and L5 × T4 for yield attributes; L4 × T1, L4 × T2, L3 × T1, L7 × T1, L3 × T2, L6 × T3 and L1 × T1 for quality traits; L6 × T1, L7 × T4, L3 × T2, L7 × T1 and L7 × T3 for ChiLCV resistance. Lines vs. testers showed significant differences for all the characters except for plant height. The GCA effects for testers were significant for all the traits except for days to first harvest. The ratio of σ2GCA/σ2SCA was less than unity for all the characters, which indicated the predominance of non-additive gene effects in the inheritance of these traits. The contribution of lines were more compared to testers for all the characters except for primary branches plant-1. The superior lines based on GCA effects were L1, L3, L7 and L6 for yield attributes; L2, L3, L4 and L7 for quality traits and L1, L2 and L4 for ChiLCV resistance. Among testers, T1 and T2 were best general combiners for yield and quality traits, and T1 and T3 for ChiLCV resistance. The hybrids viz., L3 × T2, L7 × T1, L1 × T1, L6 × T3, L1 × T4, L4 × T2, L5 × T3, L5 × T4, L7 × T3 were most promising with desirable SCA effects, heterosis and per se performance for yield and quality attributes and they were moderately resistant to ChiLCV except L5 × T3 and L5 × T4. The hybrid L1 × T1 and L7 × T1 had both parents with high GCA effects for yield plant-1. All the four testers were symptomless and among seven lines, two were moderately resistant and five were moderately susceptible. Among 28 F1 hybrids, 12 showed moderate resistant reaction, 11 were moderately susceptible and five susceptible. The check hybrids CH-27 and Arka Harita were moderately resistant and susceptible respectively. Three superior crosses identified from line (L) × tester (T) analysis viz., cross 1 (L1 × T1), cross 2 (L3 × T2) and cross 3 (L7 × T1) were utilized for generation mean analysis. The six generations (P1, P2, F1, F2, BC1 and BC2) of three crosses were developed and evaluated during 2018 summer. Both simple and joint scaling tests were significant for all the characters in all the crosses indicating the inadequacy of additive-dominance model and involvement of digenic or higher order non-allelic gene interactions. Duplicate type of epistasis was observed for plant height, days to first flower, days to first harvest, fruit length, fruit girth, vitamin C, carotenoids and ChiLCV resistance (cross 1); plant height, primary branches plant-1, days to first harvest, fruit girth, fruit weight, fruits plant-1, vitamin C, carotenoids and ChiLCV resistance (cross 2); primary branches plant-1, days to first flower, days to first harvest, fruit girth, fruit weight, fruits plant-1, yield plant-1, vitamin C, carotenoids and ChiLCV resistance (cross 3). These crosses can be improved by biparental mating between recombinants in early segregating generation and delaying the selection in the advanced generations. Complementary type of epistasis was noticed for fruits plant-1, yield plant-1 and yield plot-1 (cross 1); fruit length, yield plant-1 and yield plot-1 (cross 2); plant height and yield plot-1 (cross 3). Additive, additive × additive or complementary gene interactions are fixable, thus, these crosses can be exploited effectively through pedigree method of selection. For ChiLCV resistance dominance (h) gene action, additive × additive (i), additive × dominance (j) and dominance × dominance (l) type of gene interactions are significant. Among them, the former three are in negative desirable direction. The four ChiLCV resistant genotypes identified in this study could be used as potential parents for ChiLCV resistance breeding programme. The 93 per cent similarity of the amplified sequence to ToLCKV suggests that, it could be a strain of ToLCKV responsible for ChiLCV disease. The parents L1, L3, T1 and T3 were superior on the basis of GCA effects for most of the economic traits studied. The hybrids L3 × T2, L7 × T1, L1 × T1, L6 × T3, L1 × T4, L4 × T2 and L7 × T3 were most promising for yield and quality traits, and were moderately resistant to ChiLCV. The dominance (h) gene action and dominance × dominance (l) epistasis were predominant for yield and quality traits indicating the importance of heterosis breeding in varietal improvement of chilli. The ChiLCV resistance could be improved through recombinant breeding or recurrent selection.
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    ThesisItemOpen Access
    Aggrading lateric soils (ultisol) using biochar
    (Department of Soil Science, College of Horticulture, Vellanikkara, 2019) Rajakumar, R; KAU; Jayasree Sankar, S
    The present investigation was undertaken at College of Horticulture, Vellanikkara and Agricultural Research Station, Mannuthy during 2016-2018. The study consisted of production and characterization of bioehar from coconut based materials, an incubation experiment, and two field experiments. The incubation experiment was conducted for 15 months to study the dynamics of C and N in soil over time and the soil samples were analyzed for C and N fractions at three months' interval. Two field experiments were carried out sequentially, wherein Chinese potato was raised to study the direct effect of bioehar and vegetable cowpea was the test crop to study the residual effect of bioehar applied to the first crop. Three levels of bioehar (5, 7.5, 10 t ha"'), FYM 10 t ha"', soil test based POP + bioehar 10 t ha"' and soil test based POP were the treatments, for both incubation and field experiments. Soil test based POP consisted of NPK and FYM 10 t ha"'. Control plots without the addition of biochar/fertilizers were also maintained. Recovery of bioehar from coconut husk and shell (1:1) on pyrolysis was 22 per cent. The produced bioehar had an alkaline pH (10.01), high EC (3.42 dS m"'), C (64.14 %), CEC (15.78 cmol (+) kg"'), and C: N ratio (113:1). Total N, P, K, Ca, Mg and S contents were 0.567, 0.982, 4.175, 1.19, 0.456 and 0.244 per cent, respectively. Regarding physical properties, bioehar had low bulk density (0.128 Mg m"^), very high porosity (84.63 %) and WHC (307.3 %). Basicity and acidity of bioehar were 2.02 and 0.08 mmol g"', respectively. The surface morphology and chemistry studied using SEM, TEM, FT-IR and Raman spectroscopy revealed the porous, aromatic and recalcitrant nature of bioehar and the presence of functional groups mainly carboxyl, hydroxyl and carbonyl. Results of incubation experiment revealed that the content of organic carbon - (OC), water soluble carbon (WSC) and microbial biomass carbon (MBC) increased up to 6 months of incubation and decreased thereafter. In the case of permanganate oxidizable carbon (POXC) and hot water soluble carbon (HWSC), a decreasing trend was noticed. While the highest value of WSC and HWSC were recorded in FYM 101 ha"', all other C fractions were higher in the treatments viz. soil test based POP + bioehar 10 t ha"' and bioehar 10 t ha"'. With an increase in levels of bioehar, the labile C fractions viz. POXC and MBC increased. The labile C fractions in soil were in the order POXC > HWSC > MBC = WSC. As regards the N fractions, NH4-N declined steadily at 3 months, then increased up to 9 months of incubation after which it decreased till the incubation ended. The NO3-N and amino acid N increased up to 12 months of incubation and slightly declined thereafter. Increase in total hydrolysable N was noticed up to 6 months of incubation and thereafter, a progressive decrease was noticed. While the total N content decreased over the incubation period, the KMn04-N increased. With an increase in levels of biochar, the NO3-N and KMn04-N increased. The treatments soil test based POP + biochar and soil test based POP were equally superior to other treatments with respect to N fractions. Results of field experiments revealed the superiority of biochar 10 t ha"' in increasing soil pH and NH4OAC-K and reducing the exchangeable acidity. The treatments soil test based POP + biochar and soil test based POP were superior with respect to most of the soil properties. Application of biochar at 10 t ha"', either alone or in combination with POP improved the soil properties viz. OC, dehydrogenase activity, CEC, MWHC and hot water soluble B. With an increase in levels of biochar, the soil properties viz. pH, CEC, WHC, dehydrogenase activity, NH4OACK, Ca, HCl-Zn and humic acid increased. With respect to the growth parameters and yield of Chinese potato, application of soil test based POP + biochar and soil test based POP were comparable. The same treatment soil test based POP + biochar that faired in terms of direct effect proved good in residual effect as well, as reflected from the plant growth and yield of cowpea. Path analysis had shown that the soil properties viz. OC, MBC, Bray-P, NH4OAC-K, Ca and EC directly influenced the tuber yield, reinstating the role of biochar in yield improvement. The nutrient content in plant parts and its uptake varied among treatments and corroborated the trend. Considering the quality attributes of Chinese potato, the treatments biochar 10 t ha"' and soil test based POP + biochar recorded higher CHO content. Protein content was highest in the treatments soil test based POP and soil test based POP + biochar. The advantage of biochar on increasing protein content and decreasing crude fibre content was visible in the succeeding crop of cowpea also, thus establishing its high residual effect. The study revealed the potential of biochar as an amendment in the highly weathered, nutrient-poor acidic laterite soils of the tropics. Its application brought about increase in soil pH, addition of basic cations, improvement in CEC and WHC, and gradual release of nutrients to the growing plants. The overall improvement in physical, chemical and biological soil conditions through biochar could promote plant growth, yield as well as quality. The positive effect of biochar could be observed in combination with soil test based fertilizer application also.