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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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ThesisItem Open Access Impact of seed priming techniques on germination and seedling performance in sandal (Santalum album L.)(Department of Silviculture and Agroforestry, College of Forestry,Vellanikkara, 2019) Chithra, P; KAU; Jijeesh, C MSantalum album L, known as the East Indian Sandalwood is a semi-root parasitic tree native to South India and it is one of the most precious and valuable among Indian forest trees. The poor rate of germination coupled with long germination period is the major constraints in the regeneration of sandal. Present study was conducted to assess the impact of seed priming techniques on the germination and seedling growth attributes of sandal at College of Forestry, Vellanikkara, Thrissur. The effect of different duration and concentration of priming agents viz. water (Hydropriming for 3, 6, 9 and 12 days), Pseudomonas fluorescens (Biopriming at 25, 50, 75 and 100% for 2, 4, 6 and 8 days), Polyethylene Glycol 6000 (Osmopriming at 5, 10, 15 and 20% for 3, 6, 9 and 12 days) and MnSO4 (Chemical priming at 0.4, 0.6, 0.8 and 1.0 M for 3, 6, 9 and 12 days) on seed germination and subsequent seedling growth in sandal were studied. The non- primed seeds were kept as control. Primed seeds were stored for one day and one month after the completion of priming processes and the germination and seedling growth were observed. The germination was obtained only in the seeds stored for one day after priming process and the seeds stored for one month failed to germinate. Results indicated that the hydropriming of the seeds could not improve the germination of the sandal seeds compared to control. Biopriming significantly increased the seed germination and the highest germination percentage (88%) was recorded in the seeds subjected to biopriming for 8 days at 100% concentration, which was 1.9 times higher compared to control. The highest germination recorded in osmopriming was 78%. The chemical priming with MnSO4 at different concentrations for 3 days also recorded the higher germination (88%) comparable to biopriming. Electrical conductivity was the highest in the leachates of seeds hydroprimed for 12 days (1.96 dS cm-1) and was the lowest in seeds subjected to biopriming (0.03 dS cm-1). The leachate conductivity of the seeds subjected to osmopriming treatments (1.69 dS cm-1) was comparable to that of the hydropriming treatments. Although the different concentrations and duration of MnSO4 reduced the leakage of solutes from the sandal seeds, the electrical conductivity was higher than that of the biopriming treatments. Hence, biopriming treatments were the best in reducing the leakage of solutes from the cells leading to better membrane integrity and stability. Biochemical analysis of the primed and non-primed seeds indicated that the hydropriming treatments recorded significantly lower carbohydrate, protein and crude fat content compared to control.ThesisItem Open Access Productivity of tree fodder banks in selected homegardens of central Kerala(Department of Silviculture and Agroforestry, College of Forestry, Vellanikkara, 2019) Anush Patric; KAU; Asha, K RajThe field study entitled “Productivity of tree fodder banks in selected homegardens of Central Kerala” was carried out as three separate experiments in selected small, medium, and large scale homegarden with livestock component in Arimboor panchayath, Thrissur, Kerala during 2018-2019. The study aimed to assess the forage yield and nutritive value of five fodder tree species viz. Mulberry (Morus indica), Agathi (Sesbania grandiflora), Moringa (Moringa oleifera), Gliricidia (Gliricidia sepium) and Calliandra (Calliandra calothyrsus) under hedgerow planting (45 x 45 cm spacing) in homegardens; and to explore the short term changes in soil nutrient status of homegardens with tree fodder integration. The treatments were laid out in randomized block design replicated four times. The trees were harvested at 1m height and at the interval of two months during rainy season and three months during summer season The result revealed that all the tree species established well in the homegardens after planting. Initial growth of Agathi and Calliandra was faster in terms of plant height, whereas Gliricidia showed excellence in lateral branching. In general, coppice parameters were better for Gliricidia followed by Agathi and Calliandra. The annual green and dry forage yields were higher for Gliricidia (24.27 & 4.39 Mg ha-1) and Calliandra (16.38 & 4.60 Mg ha-1) respectively followed by Agathi and Mulberry. The yield from Moringa was comparatively poor. Seasonal fodder yields were higher for rainy period than summer. Forage quality also differed among tree species. Calliandra (22.57 %) and Gliricidia (19.99 %) fodder had more crude protein content and yield followed by Mulberry (16.74 %). Crude fibre content was lower in Gliricidia, Calliandra and Mulberry than other species. Mulberry (7.93 %), Moringa (7.61 %) and Agathi (7.12 %) had higher ash content, whereas Moringa and Mulberry had higher P and K content. Dry matter content was significantly higher for Calliandra (30.40 %) and Mulberry (28.73 %). Higher leaf-stem ratio was observed in Mulberry (2.09) and Gliricidia (2.05), followed by Calliandra (1.67). In general, Gliricidia and Calliandra had higher forage yields and protein content, followed by Agathi. Mulberry showed intermediate performance with respect to yield and quality. Moringa was inferior in forage yields but rich in quality attributes like ash, minerals and P content. Comparing homegardens, yield performance of fodder banks was higher in medium homegarden (MHG) followed by large (LHG) and small homegarden (SHG). Whereas reverse trend was observed in quality attributes of fodder. Survival count of the trees after one year of planting was significantly higher in Mulberry (80.06 %) and Calliandra (71.13 %), followed by Gliricidia (44.35 %), whereas survival was drastically lower for Agathi (31.55 %) and Moringa (31.55 %). Inspite of poor yields of Mulberry in the initial year, higher persistence of Mulberry indicates its better performance in the subsequent years. Comparing different homegardens, survival percentage was higher for SHG (59.47 %) and MHG (54.46 %) followed by LHG (41.07 %). Low survival in LHG was due to waterlogging during rainy season. In general, the soil organic carbon, N and P content improved with fodder tree integration in SHG and MHG. There was no visible changes in K content. Soil N and P levels also improved in LHG whereas SOC showed a declining trend. Comparing tree species, Agathi plots showed more soil improvement with higher SOC and NPK levels whereas soil depletion was more evident in Moringa with respect to carbon, P and K, and in Calliandra in terms of carbon and nitrogen. PAR transmittance ranged from 50.10 % in SHG to 52.75 % in MHG and LHG which were on par. PAR transmittance levels in various tree plots ranged from 45.50 – 58.57 % with no statistical significance. A marginal reduction in transmittance was observed in Mulberry (45.50 %) when compared to other species. The economics of fodder bank cultivation in homegardens varied significantly with respect to tree species. Gliricidia fodder banks generated higher returns and B: C ratio (1.28) whereas all other species showed B: C ratio of less than one. The initial cost for raising fodder banks in homesteads is high whereas the forage yield in the initial year of planting is comparatively less as trees are under the establishment phase. Hence, in conclusion, fodder trees like Gliricidia, Calliandra, and Mulberry with good yield/persistence are found to be ideal for hedgerow planting in the understorey of homesteads. Agathi is not amenable to heavy pruning, hence frequent replanting is a management option due to its faster growth. Cultivation of Moringa should be confined to light intensive as well as dry areas of homesteads. Moreover, pruning of overhead trees in homesteads to enhance understorey light regimes can further elevate the yield levels of fodder banks. Scientific cultivation and management of multispecies tree fodder banks and feeding mixed forages will provide quality and balanced nutrition to enhance livestock production at minimal cost in homegardens.ThesisItem Open Access Optimization of fertilizer regimes and understorey productivity in four-year-old Swietenia macrophylla King stands(Department of Silviculture and Agroforestry, College of Forestry, Vellanikkara, 2018) Vikas Kumar; KAU; Kunhamu, T KExtensive field study was carried out to investigate the effect of fertilizer treatment and intercrops on the growth and productivity of 4-year-old Swietenia macrophylla King. The study was carried out in a S. macrophylla plantation that was established at Mala, Thrissur during 2009 at a spacing of 2.5 x 2.5m. The fertilizer cum intercropping trial was superimposed on the existing S. macrophylla plantation in a split plot design with fertilizer levels as main plots and intercrops as sub plots during two consecutive years (2014-2016). The various N, P, K fertilizer combinations were viz. F1: 0:0:0; F2-50:25:25 (68:78:26 g per tree); F3- 100:50:50 (136:156:52 g per tree) and F4-150:75:75 (205:234:78 g per tree) kg ha-1 year-1 N, P2O5 and K2O; equivalent to 0:0:0, 50:10.75:20.75, 100:21.5:41.5 and 150:32.25:62.25 kg ha-1 per year elemental N, P and K, respectively. The fertilizers were applied to the mahagony trees at a basal ring of 50 cm radius just after the pre-monsoon rains. The various intercrops selected were shade tolerant ginger (Zingiber officinale Roscoe), wild turmeric (Curcuma aromatic Salisb) and turmeric (Curcuma longa L.). There were total 16 combinations of treatments with three replications (total 48 plots). The main plot size was 40 x 10 m and sub plot 10 x 10 m. The growth observation of the S. macrophylla tree after the fertilizer application showed consistent increase with increasing fertilizer dosage. Tree growth in terms of height, diameter, basal area and volume showed characteristic increase with increase in fertilizer levels. For instance, the stand basal area increased from 8.69 (F1: unfertilized) to 14.87 m2 ha-1 (F4: heavily fertilized). Similarly the tree volume also showed increase with fertilizer application. The difference in basal area for the higher fertilizer regimes were on par (F3, 14.50 m2 ha-1 and F4, 14.87 m2 ha-1) suggesting F3 as the optimal fertilizer regime if basal area production is the objective. However, the volume production was the highest under F4 regimes (105.28 m3 ha-1) which was significantly different from F3 (93.31 m3 ha-1). Hence tree management at F4 fertilizer regime would be ideal for optimal volume production for S. macrophylla. The biomass production results also showed positive response to applied fertilizers. Total mean tree biomass production was in the order 52.24, 60.62, 64.32 and 83.62 kg per tree for F1, F2, F3 and F4 fertilizer dosage regime respectively. The corresponding stand level biomass (per ha basis) was in the order 83.59, 97.00, 102.91 and 133.80 Mg ha-1 for F1, F2, F3 and F4 fertilizer dosage regime respectively. The highest fertilizer dosage plots showed almost 60 per cent increase in biomass production as compared to unfertilized control. Among the biomass components, stemwood represented almost 50 % of the total biomass production for all fertilizer regimes followed by roots which accounted almost 18 % of total biomass production. Branchwood biomass represented roughly 14-15 % of total biomass. Biomass accrual by the various components in the decreasing order was: stemwood> roots> branch wood >leaves>twigs. Mean tree and stand level carbon sequestration showed positive response to fertilizer application for 6 year old S. macrophylla. The total mean tree carbon stocks ranged from 29.1 kg (F1) to 46.66 (F4). The total carbon sequestration on per hectare basis was 74.66, 57.24, 54.31, and 46.56 Mg ha-1 for fertilizer regimes F4, F3, F2 and F1 respectively.Among the various biomass components, stemwood accounted bulk of the biomass carbon which was roughly 50% followed by roots (17 %). Nutrient partitioning S. macrophylla suggests that in general, nitrogen and potassium concentrations decreased in the order leaves > stem > branch > roots > twigs for N, P and K. However, tissue phosphorus concentration followed the order branches > leaves > roots > twigs > stem. Various components stored considerable amount of nutrients in their biomass. The total N stock in the standing biomass ranged from 0.428 (unfertilized control) to 0.716 Mg ha-1 (F4; heavily fertilized). The stock of phosphorus in the biomass was 0.174 (unfertilized control) to 0.223 Mg ha-1 (F4; heavily fertilized) while the corresponding stock for potassium was 0.090 (unfertilized control) to 0.144 Mg ha-1 (F4; heavily fertilized). Root distribution studies using logarithmic spiral trench technique in 6-year-old S. macrophylla showed increase in rooting intensity with fertilizer application for total roots and root class <2.5 mm. Fine root (< 2.5 mm) represented approximately 58 to 62 % of the total roots. Hence the increase in fine root count in high fertilized plots suggest higher nutrient uptake and there by higher tree growth for S. macrophylla. The present study showed the maximum foraging zone for S. macrophylla was at rhizosphere volume of 2.17 m lateral distance and 40 cm soil depth. At the present stocking this leads to considerable overlapping of the rhizosphere of S. macrophylla and intercrops and thereby limits the prospects of intercropping. Hence the possible optimal spacing suggested for 6-year-old S. macrophylla would be 5.5 m x 5.5 m for effective intercropping. Effect of intercrop on the tree growth in all the fertilizer treatment plots suggested non-significant response. Despite the overwhelming effect of fertilizer on tree growth and yield, the presence of intercrop had only very modest influence on tree growth. Interestingly some of the S. macrophylla tree growth variables were marginally better in the intercropped plots suggesting possible complementary interaction between the intercrop and trees for applied fertilizers. The intercrops viz. ginger, wild turmeric and turmeric showed better growth in fertilized plots as compared to unfertilized control. Also the biometric growth and rhizome yieldswere higher in the treeless open control plots as compared to S. macrophylla intercropped plots. Nevertheless the growth differences were lower in the heavily fertilized plotsas compared to open control. The better growth and rhizome yields during the second year for all the three intercrops was due to improvement in understory light regimes consequent to uniform tree pruning.ThesisItem Open Access Productivity, carbon and nutrient stocks in mulberry (Morus indica L.) and subabul (Leucaena leucocephala Lam.) based high density fodder production system in coconut(Department of Silviculture and Agroforestry College of Forestry, Vellanikkara, 2018) Acsah Rose, John; KAU; Asha K RajThe research programme entitled “Productivity, carbon and nutrient stocks in mulberry (Morus indica L.) and subabul (Leucaena leucocephala Lam.) based high density fodder production system in coconut”, was conducted at Instructional farm, College of Horticulture, Vellanikkara during 2017-18, to evaluate the influence of tree density and harvest interval on forage yield, carbon and nutrient stocks of three- years- old mulberry and subabul fodder banks in coconut garden. The study also examined the variation in coconut productivity and soil fertility changes associated with fodder bank integration in coconut plantations. The treatments included intercropping of fodder tree species like mulberry and subabul-1 at three levels of tree densities (49,382; 37,037 and 27, 777 plants ha-1 ) and three levels of harvest intervals (8, 12 and 16 weeks) in all possible combinations with randomized block design replicated thrice. The study indicated that annual fresh fodder yield from fodder tree banks per hectare of coconut garden in the third year of intercropping was significantly higher in mulberry (33.93 Mg ha-1 yr ) than that of subabul (20.14 Mg ha-1 yr ). Forage yields of tree banks increased from 18.97 to 35.04 Mg ha yr from lower to higher density classes, and were also found to be higher (33.98 Mg ha-1 yr ) for medium harvest interval of 12 weeks than longer or shorter intervals. Comparing the cumulative effects of stand management practices, forage yields of mulberry and subabul stands showed drastic variation which ranged from 16.40 to 63.38 and 9.33 to 30.96 Mg ha-1 yr-1respectively under various management levels, there by indicating the critical role of proper management for productivity enhancement from tree fodder banks. Maximum yield was obtained from the highest density stand (49,382 plants ha-1 ) and at medium harvest interval of 12 weeks in both the tree species. In general, fodder tree intercropping and various management regimes showed no significant influence on coconut productivity. However, a slight decrease in nut yield was observed under very high fodder tree density (49,382 plants ha-1 ), especially with that of mulberry, there by pointing out the need for crop specificnutrient and moisture supplementation to prevent competition and yield loss in coconut under high density intercropping. Intercropping of fodder trees and various management practices resulted in significant enhancement in total biomass production and carbon storage potential of coconut plantations (82.70-108.48 Mg ha-1 ) than that of coconut monoculture system (75.35 Mg ha-1 ). The intercropped fodder trees have fixed additional carbon to a maximum of 33 Mg ha-1 in the plant biomass and in soil up to 40 cm depth, thereby making considerable contribution for reducing atmospheric carbon dioxide levels. Significant difference was observed in nutrient uptake by the two fodder tree species, tree density and harvest schedule. N, P and K uptake was found to be significantly higher for mulberry (70.77, 4.80 and 38.22 kg ha-1 ) than that of subabul (51.62, 2.97 and 24.45 kg ha-1 ). N, P and K uptake enhanced by 81, 113 and 96 per cent from lower to higher densities. The nutrient uptake was higher in the medium interval of 12 weeks when compared to shorter or longer intervals. In general, intercropping practices in coconut have overall improved the fertility status of soil compared to coconut monoculture. However, proper nutrient supplementation should be ensured while adopting very high tree densities to avoid any possible competition with coconut palms. Fodder tree species and tree density had significant effect on soil properties like pH and water holding capacity (WHC) in mulberry and subabul plots intercropped in coconut plantation. Soil pH was observed higher in subabul (4.84) than mulberry (4.58). Water holding capacity (WHC) was observed higher in mulberry plots (53.96 %) than that of subabul (50.84%). Comparing the economics of tree fodder integration in coconut garden, significantly higher B: C ratio was obtained from mulberry (2.94) than subabul (2.54). B: C ratio showed an increasing trend (2.26 to 3.05) from lower to higher density classes. The highest B: C ratio (3.07) was obtained from 12 weeks harvest interval.Hence, the present field study clearly demonstrates the possibility of integrating mulberry and subabul fodder banks in coconut gardens of Kerala to enhance quality forage production, so as to minimize farmer’s expenses on feed cost. Adoption of ideal stand management practices viz., tree density of 49,382 plants ha-1 and 12 weeks harvest interval, can generate higher forage yields from limited land area. Moreover, the intercropped fodder trees have fixed additional carbon to a maximum of 33 Mg ha-1 , thereby making considerable contribution for reducing atmospheric CO2 levels to minimize global warming. Thus, establishment and proper management of mulberry and subabul fodder banks in coconut garden is a low cost technology to enhance quality forage production in humid tropics, and a promising strategy for climate change mitigation via carbon sequestration.ThesisItem Open Access Understorey productivity of selected fodder grasses in mature coconut and rubber plantations(Department of Silviculture and Agroforestry, Vellanikkara, 2018) Rose Mary Jose; KAU; Jamaludheen, VA field experiment was conducted at Vellanikkara, Thrissur, Kerala from May 2017 to February 2018 to assess the understorey productivity of four fodder grasses viz congosignal (Brachiaria ruziziensis), guinea (Panicum maximum) and two hybrid napier cultivars CO-3 and CO-5 when grown under mature coconut (Cocos nucifera L.) and rubber (Heavea barsiliensis Muell. Arg,) plantations, which are the two prominent land use systems in Kerala. The biophysical attributes influencing the productivity of these land use systems and the biochemical changes in the products of understorey crops were also studied. Growth parameters of understorey fodder crops varied remarkably among these land use systems. The fodder grasses grown in coconut plantations showed an increased plant height, leaf area index, leaf area ratio, and leaf weight ratio as compared with treeless open plot. However, the number of tillers per clump and number of leaves per clump showed a decreasing trend when grown as understorey crops in mature coconut and rubber plantations. Rubber grown fodder grasses expressed substantially poor performance both in growth and yield attributes. Regarding fodder production, open grown fodder grasses consistently showed maximum biomass dry weight throughout the harvests. On comparing with the open, the rubber plot showed a substantial reduction of 91.35% in the total biomass dry weight from all harvests whereas the reduction was only 39.02% under coconut plantations. Mean mid day (12–1p.m) understorey photosynthetic Photon Flux Density (PPFD) were 1342.5 moles μ m -2 sec -1 in rubber and 1575 μ molesm -2 sec -1 in coconut, with respective understorey PAR transmittance of 39.84 % and 56.08% of full sunlight. The understorey crops in coconut and rubber showed an increased chlorophyll-a, chlorophyll-b, and total chlorophyll content and leaf moisture content over treeless control. The maximum crude protein value was noticed in the rubber (11.97%) grown fodder grasses and was on par with open while 124 coconut (9.29 %) accounted the least crude protein content. The understorey crops showed a decreased crude fibre content as compared to open. The maximum leaf nitrogen content was observed in the rubber plot (1.92%) and this was followed by open plot (1.87%). The lowest nitrogen content was observed in the coconut plot (1.49%). No noticeable changes were observed in foliar phosphorus and potassium content across both land use systems. The soil analysis revealed that the organic carbon and available nitrogen content of the top soil were increased under both the tree based cropping systems as a result of understory intercropping. However, on comparing with the initial values of different soil properties studied, only modest changes were observed in the soil properties in general across both the land use systems and treeless open plot. It is concluded that the coconut based fodder production systems with these grasses are almost comparable, in terms of growth and yield, to the open areas and hence recommended for farmers adaption. This practice of integrating fodder grasses in coconut plantations gains immense importance in Kerala, where mature coconut plantations forms one of the extensive and prominent land management system. Thus, judicious use of the vast area of interspaces under these matures coconut plantations for fodder production is very ideal especially in the state of Kerala. The best proven combination of land use system and the fodder grass in a coconut based intercropping scenario was the cultivation of CO-3 fodder grass under matured coconut plantations. However, the rubber based fodder production system is not at all feasible and further conclusive studies may be done for affirming more reasons for such a substantial reduction of growth and yield in rubber based system.