Open Access
Subscription Access
Study on Structural and Dielectric Properties of (Ti, Cr) Co-doped SnO2 Nanoparticles
The present study deals with the impact of (Ti, Cr) co-doping on the structural, optical, and dielectric properties of the SnO2 nanoparticles. The traditional solid-state reaction route is adopted to prepare undoped, Ti-doped and (Ti, Cr) co-doped SnO2 nanoparticles. The structural analysis revealed the polycrystalline nature with a single phase of tetragonal rutile type structure for all the prepared samples. The increment in the crystallite size is observed with doping. The Scanning electron microscopy showed that the nanoparticles are spherical and uniformly distributed. A small variation is noticed in the optical band gap energy of doped samples as compared to the undoped SnO2. The significant changes have been reported in parameters such as dielectric function, capacitance, dielectric loss factor, and AC conductivity. Maxwell-Wagner model is suitable to illustrate the decreasing behaviour of dielectric constant and dielectric loss with frequency. Ti and Cr co-doped SnO2 nanoparticles revealed lower dielectric loss contrary to Ti-doped and undoped SnO2 nanoparticles. The ac conductivity of all the prepared samples increases with frequency and doping. Ti-doped SnO2nanoparticles exhibited higher ac conductivity, which can be explained by the hopping of charge carriers.
Keywords
Co-doping; Structural analysis; Crystallite size; Maxwell-wagner model; Dielectric constant.
User
Font Size
Information
- Snaith H J & Ducati C, Nano Lett, 10 (2010) 1259.
- Azam A, et al., J Alloys Compd, 506 (2010). 237.
- Pandian S K, et al., Mater Manuf Process, 27 (2012) 130.
- Tagreed M, et al., Energy Procedia, 157 (2019) 457.
- Ahmed A, et al., Mater Sci Eng, 577 (2019) 012041.
- Jahnavi V S, et al., J Electron Mater, 49 (2020) 3540.
- Mehraj S & Ansari M S, Phys. E Low-dimensional Syst Nanostruct, 65 (2015) 84.
- Wan N, et al., Scientific Reports, 6 (2016) 1.
- Narzary R, et al., Mater Sci Semicond Process, 142 (2022) 106477.
- Duhan M, et al., Vacuum, 181 (2020) 109635.
- Gopinadhan K, et al., J Appl Phys, 102 (2007) 113513.
- Kuppan M, et al., Adv Condens Matter Phys, 2014 (2014).
- Ahmed A, et al., Appl Surf Sci, 483 (2019) 463.
- Subramanyam K, et al., Solid State Sci, 39 (2015) 74.
- Lachore W L, et al., Appl Phys A, 128 (2022) 515.
- Ahmed R, et al., Mater Res Bull, 63 (2015) 32.
- Rajwali K & Fang M H, Chin Phys B, 24 (2015) 127803.
- Sahay P P, et al., Curr Appl Phys, 13 (2013) 479.
Abstract Views: 89
PDF Views: 48