Photogalvanic effect in aqueous Methylene blue nickel mesh systems: Conversion of light into electricity

2011

Arab J Sci Eng

Sodium lauryl sulphate (SLS) was used as a surfactant, thymol blue as a photosensitizer and mannose as a reductant in a photogalvanic cell to improve the conversion efficiency and storage capacity of such cells to achieve commercial viability. The photopotential and photocurrent generated were 635.0 mV and 100.0 µA, respectively. The effect of various parameters including concentration of photosensitizer, reductant and surfactant, pH and diffusion length on the cell properties was observed. The observed conversion efficiency and the maximum power of the cell were 0.23% and 24.60 µW, respectively. The fill factor was 0.25 at the power point of the cell. The photogalvanic cell can be used for 37 minutes in the dark following illumination for 120 minutes. The current-voltage characteristics of the photogalvanic cell were studied experimentally. All of the results observed for the system were lower in absence of surfactant. The absorption spectra of the systems with and without surfactant were also studied.

Section: Introductionmentioning

confidence: 97%

The Role of Surfactants in Photogalvanics: Solar Energy Conversion and Storage in the Sodium Lauryl Sulphate–Thymol Blue–Mannose System

Solanki

2011

Arab J Sci Eng

“…Later on, Murthy et al [5], Rohatgi Mukherjee et al [6], Folcher and Paris [7], Alfredo et al [8], Pan et al [9], Dube et al [10], Jana and Bhowmik [11], Bayer et al [12], Matsumoto et al [13] and Shiroishi et al [14] have studied some interesting photogalvanic systems. Bisquert et al [15] have reviewed the physical-chemical principles of dye-sensitized solar cells, whereas Meyer [16] has presented the molecular approaches to solar energy conversion.…”

Section: Introductionmentioning

confidence: 99%

Studies of the micellar effect on photogalvanics: Solar energy conversion and storage-EDTA-safranine O-DSS system

2009

Int. J. Energy Res.

SUMMARYThe studies of the micellar effect on photogalvanics was done for solar energy conversion and storage in photogalvanic cell containing dioctyl sodium sulphosuccinate as anionic micellar species, EDTA as reductant and safranine O as photosensitizer. The photopotential and photocurrent generated were 800.0 mV and 65.0 mA respectively. The observed conversion efficiency was 0.2532 per cent, the fill factor was 0.38 and the maximum power of the cell was 52.0 mW whereas the power at power point of the photogalvanic cell was 26.34 mW. The rate of initial generation of current was 37.5 mA min À1 . The photogalvanic cell can be used for 80.0 minutes in the dark. The effects of different parameters on the electrical output of the photogalvanic cell were observed and a mechanism has also been proposed for the generation of photocurrent in the photogalvanic cell.

“…Later, many scientists have put their utmost efforts into solar energy conversion and storage in photogalvanic cells. Among these prominent researchers, Bayer et al (2001) have studied photogalvanic effect in an aqueous methylene blue nickel mesh system, and Olea et al (1990) have studied electron transfer via organic dyes for solar energy conversion. Eisenberg and Silverman (1961) and Mukhopadhyaya and Bhowmik (1992) have studied photoelectrochemical cells.…”

Section: Introductionmentioning

confidence: 99%

Studies of mixed reductant systems with Azur A as photosensitizer for solar energy conversion and storage in photogalvanic cells

International Journal of Sustainable Energy

Indora

Bhimwal

2011

Purpose: The role of mixed reductant systems in photogalvanic cells was studied in a photogalvanic system containing Azur A as photosensitizer, EDTA as reductant, which was mixed with dextrose, NTA and oxalic acid, respectively, for increasing the conversion efficiency and storage capacity of photogalvanic cells.Design/methodology/approach: This research presents an interesting photogalvanic system for improvement of conversion efficiency and storage capacity to reduce the cost of construction and ensure commercial viability.Findings: Observed values of photopotential and photocurrent for EDTA + dextrose-Azur A system are 778.0 mV, 55.0 μA, for EDTA + NTA-Azur A system are 830.0 mV, 292.0 μA and for EDTA + oxalic acid-Azur A system are 810.0 mV, 210.0 μA, respectively.Originality/value: The observed conversion efficiencies in these systems are 0.1045%, 0.9830% and 0.9092%, respectively, whereas storage capacities are 115.0 min., 290.0 min. and 86.0 min., respectively. It shows a higher performance of cells to gain its commercial viability.