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Dr. Rajendra Prasad Central Agricultural University, Pusa

In the imperial Gazetteer of India 1878, Pusa was recorded as a government estate of about 1350 acres in Darbhanba. It was acquired by East India Company for running a stud farm to supply better breed of horses mainly for the army. Frequent incidence of glanders disease (swelling of glands), mostly affecting the valuable imported bloodstock made the civil veterinary department to shift the entire stock out of Pusa. A British tobacco concern Beg Sutherland & co. got the estate on lease but it also left in 1897 abandoning the government estate of Pusa. Lord Mayo, The Viceroy and Governor General, had been repeatedly trying to get through his proposal for setting up a directorate general of Agriculture that would take care of the soil and its productivity, formulate newer techniques of cultivation, improve the quality of seeds and livestock and also arrange for imparting agricultural education. The government of India had invited a British expert. Dr. J. A. Voelcker who had submitted as report on the development of Indian agriculture. As a follow-up action, three experts in different fields were appointed for the first time during 1885 to 1895 namely, agricultural chemist (Dr. J. W. Leafer), cryptogamic botanist (Dr. R. A. Butler) and entomologist (Dr. H. Maxwell Lefroy) with headquarters at Dehradun (U.P.) in the forest Research Institute complex. Surprisingly, until now Pusa, which was destined to become the centre of agricultural revolution in the country, was lying as before an abandoned government estate. In 1898. Lord Curzon took over as the viceroy. A widely traveled person and an administrator, he salvaged out the earlier proposal and got London’s approval for the appointment of the inspector General of Agriculture to which the first incumbent Mr. J. Mollison (Dy. Director of Agriculture, Bombay) joined in 1901 with headquarters at Nagpur The then government of Bengal had mooted in 1902 a proposal to the centre for setting up a model cattle farm for improving the dilapidated condition of the livestock at Pusa estate where plenty of land, water and feed would be available, and with Mr. Mollison’s support this was accepted in principle. Around Pusa, there were many British planters and also an indigo research centre Dalsing Sarai (near Pusa). Mr. Mollison’s visits to this mini British kingdom and his strong recommendations. In favour of Pusa as the most ideal place for the Bengal government project obviously caught the attention for the viceroy.

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2015 - 20172
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Author: Kumari, Smita × End date: 2019 × Start date: 2015 × Type: Thesis × Thesis Type: M.Sc ×
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    ThesisItemOpen Access
    Effect of Salinity Levels on Productivity and Juice Quality of Sugarcane genotypes
    (Dr. Rajendra Prasad Central Agricultural University, Pusa (Samastipur), 2017) Kumari, Smita; Jha, C. K.
    The present investigation was undertaken with an aim to study the Effect of Salinity Levels on Productivity and Juice Quality of Sugarcane Genotypes during 2016-17, at Sugarcane Research Institute, Dr. Rajendra Prasad Central Agricultural University, Pusa, Bihar. The pot experiment was conducted with treatment consisted of three salinity levels (0, 2.5 and 5.0 dSm-1) and five sugarcane genotypes (CoP 9702, CoP 112, B.O. 154, B.O 153 and CoP 9301) with three replication in CRD. The salinity of 2.5 dSm-1 (S1) and 5.0 dSm-1 (S2) was developed and sugarcane was planted as per technical programme of the experiment. Salinity was developed using suitable amount of NaCl. NPK was applied as per recommendations (150-85-60). The half dose of N, full P2O5 and K2O applied at the time of planting. Rest 50 % N was applied in two splits. The sugarcane was planted in Feb, 2016 and harvested in January; 2017. Maximum (30.28%) reduction in germination was recorded at S2 levels of salinity compared to control (S0). The genotype BO 154 recorded significantly highest germination percentage (53.84%) followed by CoP112 (50.53%) compared to CoP 9301 and CoP 9702. The maximum plant height was attained by the BO154 followed by CoP112. The growth performance of genotype CoP9301 and BO153 was significantly inferior at different stages of plant growth. The number of tillers was statistically significant and decreased significantly with increasing salinity. Sugarcane genotype BO154 recorded significantly maximum and CoP 9301 minimum number of tillers at 120 DAP. The yield components of sugarcane indicated that there was overall reduction in cane length (31.07%), cane girth (8.75%) and single cane weight (25.72%) at S2 level of salinity over S0 (Control). Among sugarcane genotypes, BO154 followed by CoP112 was found superior as compared to rest of the genotypes in terms of yield attributing characteristics. The reduction in cane yield due to salinity in S1 and S2 treatments over control was to the extent of 14.69 % and 28.07%, respectively. The mean cane yield increased by 14.00 % and 10.12 % in genotypes BO154 and CoP112, respectively over CoP9301. The mean reduction in yield among the genotypes were in order BO154 > CoP112 > CoP9702 > BO153> CoP9301. The value of brix and pol in sugar cane juice significantly decreased with increasing level of salinity, however purity coefficient was non-significant. The sugarcane genotype CoP 9301 was superior in terms of brix, pol and CCS%. The reduction in juice recovery maximum by 42.96% was recorded at S2 level of salinity. Among sugarcane genotypes, CoP112 recorded significantly maximum juice recovery (43.56%) and found at par with BO 154.The reduction in mean sugar yield varied significantly and ranges from 16.75 - 33.25 % due to salinity. Among sugarcane, genotypes BO 154 recorded significantly highest sugar yield followed by CoP112 and lowest in BO 153. The mean sugar yield increased by 9.66 % in BO 154 and 5.44 % in CoP112 over BO153. Sugar yield, a function of cane yield and exhibited similar trend of cane yield. The increasing salinity significantly decreased nutrient concentration (NPK) and uptake of nutrient (NPK) by sugarcane genotypes while, Na+ concentration, its uptake and Na/K ratio increased due to salinity over control. The higher cane yield resulted in higher uptake of nutrients. The pH and EC of soil increased while organic carbon of soil decreased significantly with increasing level of salinity. The organic carbon content of soil reduced due to salinity to the extent of 20.51 % over control. The availability of macro (NPK) and micronutrient (Fe, Zn, Cu and Mn) decreased with increasing level of salinity. The salt stress increased Na+ and decreased Ca2++Mg2+ content of soil significantly with increase in SAR and anions content of post harvest soil. The sugarcane genotypes BO154 produced highest cane and sugar yield at all salinity level. Among sugarcane genotypes BO154, followed by CoP112 and CoP9702 performed well in terms of sugar yield and cane yield under saline condition as compare to other genotypes (BO153 and CoP9301) indicating that BO154, CoP112 and CoP9702 genotypes may be grown as moderately salt tolerant genotype under different agro-climatic conditions of North Bihar.
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    ThesisItemOpen Access
    Biology, Seasonal incidence and Management of lace bug, Cochlochila bullita (Stål) (Hemiptera: Tingidae) on Tulsi, Ocimum basilicum L.
    (Rajendra Agricultural University, Pusa (Samastipur), 2015) Kumari, Smita; Kumar, Nagendra
    Present study envisages the result of studies conducted on various aspects of biology, seasonal incidence and management of lace bug, Cochlochila bullita (Stål) in the laboratory as well as field, experiments were conducted during 2014-15. Under laboratory conditions eggs were laid by the female bug mostly singly but sometimes in groups also on the under surface and margin of leaves and tender shoots within the air chamber. The incubation period varied from 3 - 7 (mean 5 ± 1.24) days. The nymph passed through five instars to complete the nymphal period. Newly moulted nymphs were pale brown in colour. Later on, the cuticle colour changed to brown to black. The first instar lasted for 2 to 4 (mean 2.9 ± 0.73) days. The second instar occupied 2 to 4 (Mean 2.8 ± 0.78) days. The third instar larval duration was for 2 to 3 (mean 2.3 ± 0.48) days. The Fourth instar occupied 1 to 3 (mean 2.0 ± 0.81) days. The fifth instar took 1 to 2 (mean 1.2 ± 0.42) days for its development. The total nymphal period varied from 8 to 16 (mean 19.8 ± 3.58) days. The total life cycle of C. bullita from egg to adult emergence varied from 11.0 to 23.0 (mean 19.8 ± 3.58) days. Females were significantly larger than male with respect to body length. The female can be differentiated from the male by the presence of an ovipositor whereas male has a distinct genital capsule with hidden structure (parameres). The adult individuals reared in the laboratory survived for 27 to 36 days with average of (mean 33.7 ± 4.78) days. Total life duration was recorded as: 38-59 (mean 50 ± 8.39) days. The incidence of lace bug on tulsi commenced from the October, 2014 and continued till the month of January, 2015. Maximum bug population (43.2 insects per plant) was recorded during 52 standard week of December, 2014. All weather parameters except relative humidity (RH) at 07 hrs and 14 hrs had significant impact on lace bug population on tulsi. All these weather parameters together produced 86 per cent impact on lace bug population. Among the chemical insecticides and plant products under test, overall best performance was found in case of three times spraying of prophenophos 50EC @ 1 ml/l applied at fortnightly intervals in reducing lace bug population 6.20, 4.70, 3.37 lace bug per plants as against 20.40, 33.40, 43.20 lace bug per plant in untreated control after 1st, 2nd, and 3rd spraying which was at par with imidacloprid 17.8 SL@ 0.3ml/l and malathion 50 EC@ 1ml/l. All plant products were least effective in reducing the lace bug population in comparison to synthetic chemicals but significantly superior to the untreated control. The overall mean per cent reduction in lace bug population, was recorded with prophenophos (73.97 %) followed by imidacloprid (68.40 %) and malathion (67.49 %) as compared to 45.22 %, 44.81 %, and 41.41 in karanj oil @2%, NSKE@5% and neem oil 2% after 3rd spray. Damage intensity caused due to infestation of C. bullita on the tulsi crop was also assessed by estimating the fresh herbage yield under protected and unprotected conditions. In protected plot yield was 5.4 tonnes/ ha whereas in unprotected plot yield obtained was 3.6 tonnes/ ha. Therefore, 33.33 per cent herbage yield loss was recorded in unprotected plot when compared with protected plot.