Subhasis Roy

Fabrication and characterization of next generation nano-structured organo-lead halide-based perovskite solar cell

AbstractGeneration of alternative source of energy is one of the talks of the present decade. In the present work, the focus has been given to produce energy from perovskite-based solar cells. For this purpose, a unique and novel nano-structured perovskite material ethyl ammonium lead chloride (C2H5NH3+PbCl3−) was prepared through a novel co-precipitation route using ethyl amine (C2H5NH2) and hydrochloric acid as the starting precursors with aqueous solution of Pb(CH3COO)23H2O. Finally acetic acid was added in the solution, and this solution was allowed to concentrate and cooled down at room temperature. Then the synthesized material was deposited over TiO2 film in order to fabricate the solar cell. Systematic study using XRD, SEM, UV, and photo conversion were conducted to properly analyze the structural, optical, and electrical properties of device. In the presence of light, this perovskite-based solar cell has shown energy conversion efficiency (η) of around 5.2% which is appreciably good. This result has depicted that this material is promising material for fabrication of highly efficient solar cells. This technology can be applied in industrial scale as substitute of the conventional energy in the future. Graphical abstractᅟ

Thermal engineering of lead-free nanostructured CH 3 NH 3 SnCl 3 perovskite material for thin-film solar cell

AbstractPerovskite solar cell is a kind of revolutionary investigation in the field of renewable energy which is capable of mitigates the deficiencies of silicon solar cell and its uprising efficiency can bring blessing to society. The presence of lead (Pb) in perovskite solar cell can make worst and negative impact on environment and is not desirable for our society. In this paper, general plans are anticipated by replacement of Pb with tin (Sn) in open atmosphere to fabricate the CH3NH3SnCl3 photovoltaic cells in chlorine (Cl)-rich environment. Excess uses of Cl has positive influences on morphological growth of the film and it also suppresses the oxidation tendency of tin (Sn) with existing oxygen in atmosphere and maintains same chemical atmosphere as bulk. Various characterization tools like X-ray diffraction, scanning electron microscope (SEM) have been used to study the effect of annealing temperature on crystal stricture, phase formation, impurities, and morphologies of the film. Finally, photovoltaic performance was reported using the solar simulator under 1.5 sun illumination. Graphical abstractᅟ

An overview of engineered porous material for energy applications: a mini-review

The ordered porous materials, developed using various templating materials, have generated huge interest among the electrochemist community due to their plenty of unique properties and functionalities that can be effectively applied in optoelectronic devices. Mesoporous materials possess excellent opportunities in energy storage and energy conversion applications due to their extraordinarily high surface area and large pore size. These properties may enhance the performance of porous materials in terms of lifetime and stability, energy and power density. In this review, we have tried to club the fields of optoelectronics and mesoporous materials. Also, we have summarised the primary methods for preparing mesoporous materials using various templates and described their applications as electrodes and catalysts in fuel cells, solar fuel production, dye-sensitised solar cells, perovskite, supercapacitors and rechargeable batteries. Finally, we have highlighted the research and development challenges of mesoporous materials those need to be overcome to enhance their contribution in renewable energy applications.

Fabrication of Environmental Friendly Perovskite Solar Cell by Partial Replacement of Lead with Tin

In the recent years a new class of solar material based on solid state mixed organic-inorganic halides perovskites has become the rising stars of the photovoltaic world. In this case perovskites are structured compounds which act as a light harvesting active layer. There has been a meteoric rise in the photoelectric efficiency from 3.8% in 2009 to 22.1% by the end of 2016. This is also attractive because it is flexible, cheap to produce and simple to manufacture. In spite of holding such a promising position in the advancing solar technologys world, it has certain setbacks; one of the most important among them is the presence of harmful lead (Pb) in the perovskite material. In this report, attempt has been made to replace the amount of lead (Pb) in perovskite solar cell by tin (Sn) to give birth to ABX 3 (A- CH 3 NH 3 ; B- CUSn; X- Cl/I), a less hazardous and environmental friendly perovskite solar device for a greener world. For this purpose, lead (Pb) has been partially replaced with tin (Sn) through chemical deposition method. The detailed characteristics of the thin film were studied using Scanning Electron Microscope and Ultraviolet- Visible Spectroscopy and finally photoelectric efficiency of the solar cell was evaluated under 1.5 Sun illumination .

Synthesis and Characterization of Solid-Phase Super Acid Catalysts and Their Application for Isomerization of N-Alkanes

ABSTRACT In the present work, first, the reference catalyst super acidic nanostructured sulfated zirconia (SZ) and super acidic nanostructured aluminum chloride impregnated sulfated zirconium oxides in mole ratios of Zr4+:Al3+ as 2:1 (ACSZ-1), 1:1 (ACSZ-2), and 1:2 (ACSZ-3) were synthesized by a simple precipitation method. The catalytic performance of these four catalysts were evaluated during the isomerization of n-hexane, n-heptane, and n-octane to their corresponding branched chain isomers at low temperature and pressure conditions. ACSZ-2 shows high activity toward isomerization of n-hexane, n-heptane, and n-octane into their corresponding branched chain isomers. The reference catalyst SZ was proved to be less effective compare to the other three synthesized ACSZ catalysts. Ammonia-temperature-programmed desorption of these two materials ensures that the super acidity of ACSZ-2 is higher than that of SZ. Atomic force microscopic and scanning electron microscopic pictures predict the nature of the surface of the catalysts. Transmission electron micrographic analysis indicates the presence of particle-bulks having average size 12–20 nm, presenting an amorphous nature and having no definite surface morphology of ACSZ-2. Fourier transform infrared provides an outline regarding different linkages and bond connectivities between atoms and groups in ACSZ-2 and SZ. After catalyst evaluation and characterization a probable reaction mechanism has been proposed theoretically. The reactivity and selectivity of ACSZ-2 and SZ as well as the order and activation energy of the isomerization reactions in presence of ACSZ-2 have been calculated. The use of ACSZ-2 is beneficial from the point of cost efficiency as well as its use is energy saving.