Improved production of bacteriorhodopsin from Halobacterium salinarum through direct amino acid supplement in the basal medium.

Enhanced production and growth of Halobacterium salinarum are achieved by direct supplement of essential amino acids in the modified nutrient culture medium. As arginine (R) and aspartate (D) are the main amino acid sources for producing bacteriorhodopsin efficiently from Halobacterium salinarum, both individual and combined effects of these two amino acids (in different compositions) in the basal medium were studied. The BR production is enhanced by 83% on the eighth day (saturated) for all individual and combined amino acid supplements. Maximum production of 201 mg/l is observed for combined amino acid (R3D2)-supplemented culture which is 4.46-fold higher than the conventional culture growth from the basal medium. The obtained results suggest the efficient method to enhance BR production at low cost and thus, open up the possibility to utilize this potential biomolecule for various photonics applications which were earlier restricted due to the high cost of protein molecules.

Structurally modified bacteriorhodopsin as an efficient bio-sensitizer for solar cell applications.

Structurally modified bacteriorhodopsin (BR) was prepared by simple surfactant treatment using Cetyl trimethylammonium bromide (cationic; CTAB), Sodium dodecyl sulphate (anionic; SDS) and Triton X-100 (nonionic; TX-100). In the UV-visible absorption spectrum, the characteristic absorption band of native BR at 560 nm is hyperchromically (CTAB, due to induced aggregation), bathochromically (SDS, BR solubilisation and partial unfolding) and hypsochromically (TX-100, BR monomerizes) shifted after chemical treatment and the structural modifications were further confirmed by Raman spectra. Theoretical calculations based on optical absorption support an enhancement of BR optical and electrical conductivity via structural modification. Bio-sensitized solar cells (BSSCs) with structurally altered BR as sensitizer were fabricated and their photovoltaic performance was measured. We obtained the maximum short-circuit photocurrent and photoelectric conversion efficiency with TX-100-treated BR (0.93 mA cm-2, 0.47%), with a quasi-Fermi level and a 124-ms lifetime of photogenerated electrons in TX-100-treated BR-sensitized BSSCs, two times higher than that observed in BSSCs with native BR. A single-diode equivalent circuit model reveals favorable BSSC parameters such as high reverse saturation current (I0 = 55 nA), low series resistance (Rs = 22.9 Ω) and high shunt resistance (Rsh = 3765.5 Ω) with TX-100-treated BR-based BSSCs. As TX-100 does not alter the BR carboxyl terminus during its monomerization, maximum anchoring to the BSSC occurs which results in enhanced photocurrent generation. Thus, monomerized BR-sensitized BSSCs with their excellent photovoltaic parameters suggest the possibility of replacing native BR with TX-100 BR and this opens up the possibility of reduced cost manufacture of bio-sensitized solar cells.

Ethylenediaminium di(4-nitrophenolate): a third order NLO material for optical limiting applications.

Single crystals of ethylenediaminium di(4-nitrophenolate) [EDA4NP] were grown by slow evaporation solution growth technique using ethanol as solvent at constant temperature. It crystallizes in monoclinic centrosymmetric space group C2/c with cell dimension a=11.326Ǻ, b=7.264Ǻ, c=20.036Ǻ; ß=93.55°. Fourier Transform Infra Red (FT-IR) spectrum was recorded to identify various functional groups present in EDA4NP. Nuclear Magnetic Resonance (NMR) spectral studies were performed to confirm the functional groups. Thermogravimetric analysis and differential thermal analysis showed that the compound melts at 142.9°C. The material possesses a wide optical transparency window in the visible and near IR region (500-1200nm). The nonlinear refractive index, nonlinear absorption coefficient and third-order nonlinear susceptibility of EDA4NP were estimated to be n2=5.46×10(-8)cm(2)W(-1), ß=0.65×10(-3)cmW(-1) and χ((3))=2.96×10(-6)esu respectively. The limiting behavior observed with the sample is attributed mainly to nonlinear refraction.