Production of Astaxanthin Using Modified E. coli Cells

There are several promising markets for naturally synthesized Astaxanthin, a carotenoid found in krill, shrimp, salmon, and other marine life that imparts to these creatures a pink coloring of the flesh and has demonstrated human health-promoting anti-inflammatory and antioxidant activity. Compared to Astaxanthin produced through chemical synthesis, Astaxanthin synthesized through natural fermentative processes (in yeast and algae) is esterified, imparting greater antioxidant activity as well as bioavailability and making it the preferred ingredient for nutraceutical formulations. Additionally, as consumer preferences trend toward natural production processes free from the use of petrochemical solvents which may pose hazards to health hazards, fermentative production coupled with an extraction process featuring more environment- and health-friendly solvents is desired. Recently, a strain of E.coli has been genetically optimized to produce Astaxanthin, offering a cheaper synthesis route compared with algal cultivation. Herein, the authors propose a process for the production of natural Astaxanthin through fermentation in genetically modified E.coli and recovery of the compound from biomass via supercritical CO2 extraction. The fermentation seed train is composed of three pre-seed, two seed, and three production fed-batch fermenters. Biomass from the production stage is collected in a harvest/surge tank for continuous downstream processing. The biomass is concentrated in broth, the cells are lysed, and the slurry of lysed cells are dried. The lysis product is loaded with fructose and diatomaceous earth in order to produce biomass pellets that are appropriate for the extraction phase. Supercritical CO2 with ethanol co-solvent is used to extract Astaxanthin from these pellets. Astaxanthin is heat-sensitive and has low accumulation in cells. Despite the expensive equipment necessary to preserve the structure and activity of the product and the low yearly production rate, the high selling price of Astaxanthin makes this process economically profitable, with an investor’s rate of return of 125%, net present value of $468 million, and return on investment of 171%

Development of a Constant -Stress Creep Testing Equipment

ABSTRACT The design and development of constant stress creep testing equipment has been undertaken in this work. It was discovered that the cost of purchasing laboratory testing equipment is huge due to the present foreign exchange rate in Nigeria, thereby depriving most of laboratories of this necessary equipment. This accounts for one of the reasons why many science and engineering graduates go through tertiary institutions without having adequate practical experience of some of these equipment which are either non functional or not available in most cases. The developed constant stress creep testing equipment is one of such equipment required in a materials testing laboratory. The materials used for the equipment development were locally sourced, therefore expected to be easily assessable and affordable as well as preserve foreign exchange. As of July, 2010, a unit cost less than N 250,000 Nigerian (approximately $1,700 U.S.)

Strongly enhanced effective mass in dilute two-dimensional electron systems: System-independent origin

We measure the effective mass in a dilute two-dimensional electron system in (111)-silicon by analyzing temperature dependence of the Shubnikov-de Haas oscillations in the low-temperature limit. A strong enhancement of the effective mass with decreasing electron density is observed. The mass renormalization as a function of the interaction parameter r_s is in good agreement with that reported for (100)-silicon, which shows that the relative mass enhancement is system- and disorder-independent being determined by electron-electron interactions only.Comment: As publishe

Double quantum dot with tunable coupling in an enhancement-mode silicon metal-oxide semiconductor device with lateral geometry

We present transport measurements of a tunable silicon metal-oxide-semiconductor double quantum dot device with lateral geometry. Experimentally extracted gate-to-dot capacitances show that the device is largely symmetric under the gate voltages applied. Intriguingly, these gate voltages themselves are not symmetric. Comparison with numerical simulations indicates that the applied gate voltages serve to offset an intrinsic asymmetry in the physical device. We also show a transition from a large single dot to two well isolated coupled dots, where the central gate of the device is used to controllably tune the interdot coupling.Comment: 4 pages, 3 figures, to be published in Applied Physics Letter

Study of Magnetic Properties of A_2B^'NbO_6 (A=Ba,Sr, (BaSr): and B^'=Fe and Mn) double perovskites

We have studied the magnetic properties of Ba_2FeNbO_6 and Ba_2MnNbO_6. it is seen that Ba_2FeNbO_6 is an antiferromagnet with a weak ferromagnetic behaviour at 5K while Ba_2MnNbO_6 shows two magnetic transitions one at 45 K and the other at 12K. Electron spin resonance (ESR) measurements at room temperature show that the Mn compound does not show any Jahn-Teller distortion. It is also seen that the Neel temperature of the A_2FeNbO_6 (A=Ba,Sr, BaSr) compounds do not vary significantly. However variations in the average A-site ionic radius influence the formation of short range correlations that persist above T_N.Comment: 10 oages, 5 figures, MMM, to appear in J.Appl.Phy

Temperature-dependent transport in a sixfold degenerate two-dimensional electron system on a H-Si(111) surface

Low-field magnetotransport measurements on a high mobility (mu=110,000 cm^2/Vs) two-dimensional (2D) electron system on a H-terminated Si(111) surface reveal a sixfold valley degeneracy with a valley splitting <= 0.1 K. The zero-field resistivity rho_{xx} displays strong temperature dependence for 0.07 < T < 25 K as predicted for a system with high degeneracy and large mass. We present a method for using the low-field Hall coefficient to probe intervalley momentum transfer (valley drag). The relaxation rate is consistent with Fermi liquid theory, but a small residual drag as T->0 remains unexplained.Comment: 5 pages, 4 figures; revised and slightly shortened for publication

Valley degeneracy in biaxially strained aluminum arsenide quantum wells

This paper details a complete formalism for calculating electron subband energy and degeneracy in strained multi-valley quantum wells grown along any orientation with explicit results for the AlAs quantum well case. A standardized rotation matrix is defined to transform from the conventional- cubic-cell basis to the quantum-well-transport basis whereby effective mass tensors, valley vectors, strain matrices, anisotropic strain ratios, and scattering vectors are all defined in their respective bases. The specific cases of (001)-, (110)-, and (111)-oriented aluminum arsenide (AlAs) quantum wells are examined, as is the unconventional (411) facet, which is of particular importance in AlAs literature. Calculations of electron confinement and strain in the (001), (110), and (411) facets determine the critical well width for crossover from double- to single-valley degeneracy in each system. The notation is generalized to include miscut angles, and can be adapted to other multi-valley systems. To help classify anisotropic inter-valley scattering events, a new primitive unit cell is defined in momentum space which allows one to distinguish purely in-plane inter-valley scattering events from those that requires an out-of-plane momentum scattering component.Comment: 17 pages, 4 figures, 2 table