High-Conductivity Stoichiometric Titanium Nitride for Bioelectronics • Kaufman ion-beam source setup Sample −1 −7 ρ [Ω m] × 10 −1 Thickness [nm] RS [Ω □ ] LT TiN 300 2.38 ± 0.20 7.15 1.40 HT TiN 300 0.78 ± 0.01 2.33 4.28 6 σ [S m ] × 10 https://doi.org/10.1002/aelm.202200980 Characterization of titanium nitride films sputter deposited from a high‐purity titanium nitride target https://doi.org/10.1116/1.583630 Resistivity - 40 micro ohm cm Conductivity – 2500 sm-1 Titanium Nitride as counter electrode in solar cells • Comparison b/w the efficiency of SC when TiN is coated on Ti-foil and Quartz at varying parameters such as Temp. and deposition time (nitridation time) • Comparative study on SC efficiency when TiN slurry is deposited on different substrates such as Ti, Quartz, glass, and FTO • Impact of Doping semi-conductor Photo-anodes on efficiency of DSSC (review) • Exploring Doped BSO and ZSO perovskite compounds for efficient and Stable DSSC • Make a detailed report on the nitridation of TiO2 thin films, TiO2 Nanoparticles, and CVD synthesis of TiN. • Slurry preparation of TiN • Search for the application of Ti-Oxynitrides in SC • Collect the literature specific to your paper title in single folder Hierarchical micro/nano-structured titanium nitride spheres as a high-performance counter electrode for a dye-sensitized solar cell • thicknesses of the CEs of micro/nano-TiN, P25 and P200 were controlled at about 7 μm Review Papers to be considered Dye sensitized solar cells go beyond using perovskite and spinel inorganic materials: A review Review on dye-sensitized solar cells (DSSCs): Fundamental concepts and novel materials Effects of doping, morphology and film-thickness of photo-anode materials for dye sensitized solar cell application – A review Nanostructured perovskite oxides for dye-sensitized solar cells Read Various papers on BSO doped Photoanodes to find out relation B/w Band Gap & absorption(n%) --- Cr/Zn Also read general/ Review paper on tuning the Band-gap of Semi-conductors for Photo-anode application in DSSC Structural, optical and magnetic behaviour of Cr doped BaSnO3 perovskite nanostructures • The band gap values of BSO and Cr doped BSO compounds are 3.1 eV, 3.05 eV, 3.03 eV, and 2.95 eV Boosting photo charge carrier transport properties of perovskite BaSnO3 photoanodes by Sr doping for enhanced DSSCs performance Band Gap n% Pure BaSnO3 3.21 0.71 1% Sr: BaSnO3 3.23 2.52 3% Sr: BaSnO3 3.25 2.61 5% Sr: BaSnO3 3.24 2.52 Nanocrystalline Sb-doped-BaSnO3 perovskite electron transport layer for dye-sensitized solar cells • bandgap for undoped BSO obtained to be 3.48 eV decreases slightly with Sb-doping (3.44 eV and 3.43 eV for ABSO1 and ABSO3 • BaSn(1-x)SbxO3 (x = 0, 0.01 and 0.03) nanocrystalline samples Band Gap n% Pure BaSnO3 3.48 3.23 0.01 Sb: BaSnO3 3.44 4.06 0.03 Sb: BaSnO3 3.43 3.76 A facile co-precipitation method for synthesis of Zn doped BaSnO3 nanoparticles for photovoltaic application • BSO exhibited a bandgap of 3.36eV, whereas 0.5 BSO and 1BSO exhibited 3.44eV and 3.72eV, respectively • doped materials exhibit low absorption than the pristine BSO in the visible range • For pristine BSO and Zn-doped BSO, the absorption band edge was observed in the UV region, which is a typical absorption behavior for a wide bandgap semiconductor • Used as ETL in Perovskite SC Improved Quantum Efficiency of Highly Efficient Perovskite BaSnO3-Based Dye-Sensitized Solar Cells A facile co-precipitation method for synthesis of Zn doped BaSnO3 nanoparticles for photovoltaic application High-reversible capacity of Perovskite BaSnO3/rGO composite for Lithium-Ion Battery Anodes First, the cubic perovskite BaSnO3 NPs are prepared via a co-precipitation and solid-state reaction method.[19] In a typical synthesis, 10 mM of BaCl2·2H2O (99.0%, Aldrich) and SnCl4·5H2O (98.0%, Aldrich) were dissolved in an aqueous hydrogen peroxide solution with continuous stirring at room temperature for 90 min. 70 wt.% Citric acid was added to the above precursor solution to control the size. The resulting mixture was vigorously stirred at room temperature for 15 min. A clear transparent solution was achieved after dissolving the citric acid, and aqueous ammonium hydroxide solution was then immediately added to the reaction to maintain the pH at approximately 10. The solution was then stirred continuously for 10-12 h at room temperature. After the desired time, a white precipitate was obtained and washed continuously with ethanol and DI water until the pH reached neutrality, and then the precipitate was freezedried. Finally, the obtained dried white powders were sintered at 800-900°C for 2 h. Graphene oxides (GO) were synthesized by following Hummer’s method through the N. Rajamanickam 08/08/23 BSO via DI water/ Sol-gel Effect of iron doping on magnetic and electrical properties of BaSnO3 nanostructures Efficiency enhancement of cubic perovskite BaSnO3 nanostructures based dye sensitized solar cells Effect of Co doping for improved photovoltaic performance of dyesensitized solar cells in BaSnO3 nanostructures This is what we followed …….. Exploration and study on the influence of Zinc substituted Barium Stannate (BaSnO3) nano powders for ammonia sensing applications
