The retrotransposon-derived capsid genes and maintain reproductive capacity.

The human genome contains 24 -like capsid genes derived from deactivated retrotransposons conserved among eutherians. Although some of their encoded proteins retain the ability to form capsids and even transfer cargo, their fitness benefit has remained elusive. Here we show that the -like genes and support reproductive capacity during aging.

Kinetic Modeling and Techno-Economic Analysis of a Methanol-to-Gasoline Production Repurposed Refinery Equipment.

Methanol-to-gasoline (MtG) is an alternative process for the production of liquid fuel that involves the conversion of methanol into light and heavy hydrocarbons. The attractiveness of this option relies on multiple feedstocks that can be used to produce methanol, which can impact the greenhouse gases emitted into the atmosphere in comparison to petroleum-based feedstocks. However, one of the challenges of this alternative gasoline production is its high investment cost.

The retrotransposon derived capsid genes and maintain reproductive capacity.

The human genome contains 24 -like capsid genes derived from deactivated retrotransposons conserved among eutherians. Although some of their encoded proteins retain the ability to form capsids and even transfer cargo, their fitness benefit has remained elusive. Here we show that the -like genes and support reproductive capacity.

Skeletal CHOH/NO Kinetic Model for Simulating Spark-Ignition and Turbulent Jet Ignition Engines.

Methanol is a promising renewable fuel for achieving a better engine combustion efficiency and lower exhaust emissions. Under exhaust gas recirculation conditions, trace amounts of nitrogen oxides have been shown to participate in fuel oxidation and impact the ignition characteristics significantly. Despite numerous studies that analyzed the methanol/NO interaction, no reliable skeletal kinetic mechanism is available for computational fluid dynamics (CFD) modeling.

Quantum chemistry and kinetics of hydrogen sulphide oxidation.

A fundamental understanding of the acid gas (HS and CO) chemistry is key to efficiently implement the desulphurisation process and even the production of clean fuels such as hydrogen or syngas. In this work, we developed a new kinetic model for the pyrolysis and oxidation of hydrogen sulphide by merging two previously reported models with the goal of covering a wider range of conditions and including the effect of carbon dioxide. The resulting model, which consists of 75 species and 514 reactions, was used to conduct rate of production and sensitivity analysis in plug flow reactor simulations, and the results were used to determine the most prominent reactions in which hydrogen sulphide, molecular hydrogen, and sulphur monoxide are involved.