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Chaudhary Charan Singh Haryana Agricultural University, Hisar

Chaudhary Charan Singh Haryana Agricultural University popularly known as HAU, is one of Asia's biggest agricultural universities, located at Hisar in the Indian state of Haryana. It is named after India's seventh Prime Minister, Chaudhary Charan Singh. It is a leader in agricultural research in India and contributed significantly to Green Revolution and White Revolution in India in the 1960s and 70s. It has a very large campus and has several research centres throughout the state. It won the Indian Council of Agricultural Research's Award for the Best Institute in 1997. HAU was initially a campus of Punjab Agricultural University, Ludhiana. After the formation of Haryana in 1966, it became an autonomous institution on February 2, 1970 through a Presidential Ordinance, later ratified as Haryana and Punjab Agricultural Universities Act, 1970, passed by the Lok Sabha on March 29, 1970. A. L. Fletcher, the first Vice-Chancellor of the university, was instrumental in its initial growth.

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Subject: Basic Sciences × End date: 2019 × Start date: 2010 × Type: Thesis × Thesis Type: M.Sc ×
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    ThesisItemOpen Access
    Study on temperature dependent dielectric properties of honey for quality assessment
    (CCSHAU, 2019) Raman Devi; Paul Singh
    Honey, being valuable nutrient product of high price and in short supply, has become a prime target for economically motivated adulteration. This may involve illegal adulteration by adding water or sugar syrups as well as overheating. Therefore, inexpensive, fast, non-destructive methods for its quality assessment are of interest for food industry and consumers alike. For this purpose, dielectric assessment kit (DAK) which offer high precision dielectric parameter measurements such as permittivity, conductivity, loss tangent over a broad frequency range 4MHz to 67GHz was used. Affect of temperature and water content on dielectric properties of different brands A, B, C & D of honey was investigated with an open-ended coaxial line probe from 600 to 6000MHz at 25-55 ºC.The dielectric constant of honey is found to decrease with increase in frequency at a given value of temperature. The increase in temperature from 25 ºC to 55 ºC at an interval of 10 ºC resulted in an increase in both the dielectric constant and electrical conductivity over the whole range of frequency. The dielectric parameters for different brands A, B, C & D, when compared, it was found that dielectric constant and dielectric conductivity of brand C is consistent with the pure honey sample A whereas the parameters for C and D are significantly different from A. Hence, there is adulteration of water in the honey sample B and D. The dielectric loss factor in all the brands is found significantly different from each other and finally, the overheating and water content in honey strongly influence its dielectric parameters and their measurements can be utilized for quality assessment.
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    ThesisItemOpen Access
    Estimation of Buildup Factor for Shielding Materials Using Gamma Ray Spectroscopy
    (CCSHAU, 2019) Richa; Paul Singh
    Gamma ray measurement and shielding have various applications in the fields of atomic physics, radiation physics, health physics, agriculture, cancer therapy, environmental science and forensic science. It is also required to protect human being and environment from radiation hazards. In this study, shielding characteristics of gamma radiation such as linear attenuation coefficient and buildup factors for Aluminium and Ceramic materials were measured using the NaI(Tl) inorganic scintillation detector with an computer based multi-channel analyzer gamma ray spectrometer system. These characteristics were measured as a function of gamma energy, for 0.511, 0.662 and 1.274 MeV, by using cesium and sodium sources of radiation. It was found that linear attenuation coefficient for both materials decreases with increase in energy of incident radiation and for particular energy aluminium attenuate more radiation than ceramic. Buildup factor was found to be decreasing almost linearly with increasing thickness of materials and increases with increasing gamma energy for each material. This study concludes that for a bad geometry, the buildup factor decreases with increase in thickness of materials and increases with increase in energy.