Mössbauer investigation of the transformations of the iron minerals in oil shale during retorting

Iron phases in raw and retorted shales have been studied from the TOSCO II, Paraho, and Lawrence Livermore Laboratory (LLL) 125 kg retorting processes by Mössbauer effect spectroscopy. Using the Mössbauer effect, changes in the iron mineralogy during retorting were monitored. Results show that the pyrite fraction in the TOSCO II, and LLL hydrogen run S-9 samples underwent changes during retorting whereas the iron-containing carbonates did not. As in other pyrolysis processes, FeS₂ breakdown is affected by the presence of organic matter. Hydrogen released by the indigenous kerogen acts to reduce pyrite to the magnetic sulphide pyrrhotite. In all of the retorts containing oxygen, carbonate breakdown was observed prior to pyrite oxidation. Free oxygen is introduced to several retorts. The iron minerals within these systems eventually become a mixture of the oxides hematite and magnetite. This study demonstrates that alteration of specific iron minerals during retorting may be controlled by varying the internal retorting conditions.     

Studies on the secondary structure of wheat 5.8 S rRNA. Conformational changes in the A + U-rich stem during ribosome assembly

The nucleotide sequence of wheat (Triticum aestivum) 5.8-S ribosomal RNA has been re-examined using partial chemical degradation with high-temperature sequencing gels and oligonucleotide analysis. The results clarify previously ambiguous residues and add two additional nucleotides, G127 and G135, to the sequence. Estimates of the secondary structure suggest that 5.8-S rRNAs of higher plants differ from previous examples in having more open G + C-rich and A + U-rich stems. S1 ribonuclease digestion was used to probe this secondary structure; the data generally support the 'burp gun' model proposed for all 5.8-S rRNAs but are also consistent with a more open A + U-rich stem. Diethyl pyrocarbonate reactivity was used to probe the topography of this RNA in wheat ribosomes. The results indicate that the G + C-rich and A + U-rich stems are accessible to chemical modification in the wheat ribosome and suggest that the A + U-rich stem undergoes a significant conformational change when the molecule associates into ribosomes.     

Biocatalytic reductions: from lab curiosity to "first choice"

Enzyme-catalyzed reductions have been studied for decades and have been introduced in more than 10 industrial processes for production of various chiral alcohols, alpha-hydroxy acids and alpha-amino acids. The earlier hurdle of expensive cofactors was taken by the development of highly efficient cofactor regeneration methods. In addition, the accessible number of suitable dehydrogenases and therefore the versatility of this technology is constantly increasing and currently expanding beyond asymmetric production of alcohols and amino acids. Access to a large set of enzymes for highly selective C=C reductions and reductive amination of ketones for production of chiral secondary amines and the development of improved D-selective amino acid dehydrogenases will fuel the next wave of industrial bioreduction processes.     

The Early Development of Passive Treatment Systems for Mining-Influenced Water: A North American Perspective

This paper reviews the early history (first 20 years) of passive treatment of mine water, from its beginnings, when it was viewed as a possible way to treat small flows of circumneutral and mildly acidic coal mine drainage, to its use for much larger flows and more contaminated mine water from metal mines. The original concepts of passive treatment have since been modified and used successfully to treat a wide range of mine water quality and quantities, far more than we would have believed possible.

     

Enzymatic Synthesis of Enantiopure α‐ and β‐Amino Acids by Phenylalanine Aminomutase‐Catalysed Amination of Cinnamic Acid Derivatives

The phenylalanine aminomutase (PAM) from Taxus chinensis catalyses the conversion of α‐phenylalanine to β‐phenylalanine, an important step in the biosynthesis of the N‐benzoyl phenylisoserinoyl side‐chain of the anticancer drug taxol. Mechanistic studies on PAM have suggested that (E)‐cinnamic acid is an intermediate in the mutase reaction and that it can be released from the enzyme's active site. Here we describe a novel synthetic strategy that is based on the finding that ring‐substituted (E)‐cinnamic acids can serve as a substrate in PAM‐catalysed ammonia addition reactions for the biocatalytic production of several important β‐amino acids. The enzyme has a broad substrate range and a high enantioselectivity with cinnamic acid derivatives; this allows the synthesis of several non‐natural aromatic α‐ and β‐amino acids in excellent enantiomeric excess (ee >99 %). The internal 5‐methylene‐3,5‐dihydroimidazol‐4‐one (MIO) cofactor is essential for the PAM‐catalysed amination reactions. The regioselectivity of amination reactions was influenced by the nature of the ring substituent.     

Availability analysis of design configurations to compose virtual performance-optimized data center systems in next-generation cloud data centers

Next-generation cloud data centers are based on software-defined data center infrastructures that promote flexibility, automation, optimization, and scalability. The Redfish standard and the Intel Rack Scale Design technology enable software-defined infrastructure and disaggregate bare-metal compute, storage, and networking resources into virtual pools to dynamically compose resources and create virtual performance-optimized data centers (vPODs) tailored to workload-specific demands. This article proposes four chassis design configurations based on Distributed Management Task Force's Redfish industry standard applied to compose vPOD systems, namely, a fully shared design, partially shared homogeneous design, partially shared heterogeneous design, and not shared design; their main difference is based on the used hardware disaggregation level. Furthermore, we propose models that combine reliability block diagram and stochastic Petri net modeling approaches to represent the complexity of the relationship between the pool of disaggregated hardware resources and their power and cooling sources in a vPOD. These four proposed design configurations were analyzed and compared in terms of availability and component's sensitivity indexes by scaling their configurations considering different data center infrastructure. From the obtained results, we can state that, in general, when one increases the hardware disaggregation, availability is improved. However, after a given point, the availability level of the fully shared, partially shared homogeneous, and partially shared heterogeneous configurations remain almost equal, while the not shared configuration is still able to improve its availability.