Physics - Research Publications
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Item State of Art of Spinel Ferrites Enabled Humidity Sensors(Springer Science and Business Media Deutschland GmbH, 2021-10-29T00:00:00) Mathpal, Mohan Chandra; Niraula, Gopal; Chand, Mahesh; Kumar, Promod; Singh, Manish Kumar; Sharma, Surender K.; Soler, Maria A. G.; Swart, H.C.Controlling the moisture level in air and gases is an important aspect in defense, weather station, industry, laboratory and healthcare systems. The accurate measurement and sensing of the humidity/moisture level in the surrounding environment can help to maintain the temperature level for ideal living conditions; from a safety point of view, it can help to prevent the virus/disease transmission; importantly, it can protect expensive equipment, electronic devices and optical devices against damage which are sensitive to high humidity in the atmosphere. The controlled monitoring, regulation and management of humidity necessarily require humidity sensors with high sensitivity, high stability and low response time. Currently, there are various types of humidity sensors available in the market, but there are always limitations on the practical applications as the main problems are associated with their eco-friendly nature, cost, sensitivity, response time (rapid action) and lifetime. Aiming to address these issues, the spinel ferrite nanostructures arise as promising nanomaterials due to their moderate semiconducting features with high resistance, porous nature and high surface activities enabling easy fabrication of the humidity sensors. This chapter provides an overview of the role of spinel ferrite nanostructures for their applications in humidity sensors. � 2021, Springer Nature Switzerland AG.Item Ferrites as an Alternative Source of Renewable Energy for Hydroelectric Cell(Springer Science and Business Media Deutschland GmbH, 2021-10-29T00:00:00) Mathpal, Mohan Chandra; Niraula, Gopal; Kumar, Promod; Chand, Mahesh; Singh, Manish Kumar; Sharma, Surender K.; Soler, Maria A. G.; Swart, H.C.There are many conventional ways of producing energy at large scales such as fossil fuels, hydroelectric power station, wind energy, solar cell plants, marine energy, etc., but most of these require bulky plantation, huge manpower, wide land occupation and are non-portable and expensive to handle too. In the twenty-first century, there is still a huge gap between worldwide energy supply and its demand. The advances in the technology sector have also increased the consumption of energy, but the sources of generating the renewable energy remain limited. In order to account for these problems in recent years, several methods have been adopted and a significant research in this direction has been made by the invention of the hydroelectric cell by Dr. R. K. Kotnala�s group in 2016. Instead of using the magnetic character in the ferrite nanostructures, these nanomaterials were first time effectively exploited for direct energy harvesting application by using their capability to dissociate the absorbed water molecules on its porous surface. This allows the production of ions, which is then followed by the charge transfer of hydronium, hydroxyl and hydrogen ions between the electrodes of the ferrite nanostructures and results in the generation of an electric current across the circuit. The concept of the hydroelectric cell is new, and these cells are easily portable, inexpensive, biodegradable and eco-friendly in nature. This chapter provides an insight on the concept of spinel ferrite nanostructures for the application in the hydroelectric cell. � 2021, Springer Nature Switzerland AG.Item Optical properties of nanocrystallite films of ?-Fe2O3 and ?-Fe2-xCrxO3 (0.0 ? x ? 0.9) deposited on glass substrates(Institute of Physics Publishing, 2017) Kumar, Ajay; Yadav, Kamlesh?-Fe2O3 films are deposited on fluorine-doped tin oxide (FTO) and indium-doped tin oxide (ITO) substrates for 1, 4 and 6 min using a spray pyrolysis technique. We also deposited ?-Fe2-xCrxO3 (x = 0.0, 0.1, 0.2, 0.3, 0.4, 0.7 and 0.9) films on the FTO substrate for a deposition time of 35 s. The structural and optical properties of these films were then studied. The x-ray diffraction (XRD) patterns show that all the films are crystalline in nature with a hexagonal crystal structure. The average grain size and unit cell volume were calculated using XRD data. It is found that the average grain size and unit cell volume increase with an increasing film thickness and Cr-doping concentration. The value of strain decreases with an increasing film thickness and Cr-doping content. It is also found that films with the same deposition time on the ITO substrate are more crystalline than on the FTO substrate. Furthermore, the average grain size is obtained from field emission scanning electron microscopy (FESEM) images. FESEM analysis confirms that the average grain size increases with the film thickness and Cr-doping concentration. The optical absorption spectra of the films show that the absorbance increases with an increasing deposition time and Cr concentration. The energy band gap (Eg) of all the films has been calculated using Tauc's relation. A narrowing of the band gap was observed with an increase in film thickness and Cr-doping content. The reduction of the band gap with the increase in film thickness of the films deposited on the ITO substrate is larger than for the film deposited on the FTO substrate. The refractive index is also obtained from the absorption spectra of the films using the Moss relation: n = 4 (k/Eg), where k =108 eV. The refractive index decreases with an increase in the optical band gap. The band gaps of the films are also calculated from the FTIR spectra. This is in good agreement with the UV data. The correlation between the structural and optical properties of the deposited films has been discussed.