Quantitative estimation of corrosion rate in 3C steels under seawater environment

An artificial neural network method is proposed to correlate the relationship between the corrosion rate of 3C steels with seawater environment factors. The predictions with the unseen test data are in good agreement with experimental values. Further, the developed model used to simulate the combined effect of environmental factors (temperature, dissolved oxygen, salinity, pH values, and oxidation-reduction potential) on the corrosion rate. 3D mappings remarkably reveal the complex interrelationship between the input environmental parameters on the output corrosion rate. The quantitative estimation of corrosion by virtual addition/subtraction of environmental factors individually to a hypothetical system helps to understand the impact of each parameter

Corrigendum to “Quantitative estimation of corrosion rate in 3C steels under seawater environment” [J Mater Res Technol vol. 11 (March–April 2021) 681–686]

The authors regret to inform you that there are two corresponding authors for this article (B.B. Panigrahi and N. S. Reddy). Corresponding authors: 1. B.B. Panigrahi, 040-23016555, [email protected] 2. N. S. Reddy, 055-7721669, [email protected]

Enhancing the mechanical properties and corrosion resistance of commercially pure titanium using tungsten carbide composites fabricated via additive manufacturing

Commercially pure Ti (CP Ti) exhibits an exceptional corrosion resistance, and it is thus critical in the aerospace, marine, and petrochemical fields. However, pure Ti also displays a modest strength and limited wear resistance. Therefore, several studies have explored the incorporation of reinforcing phases, such as ceramics and carbides, leading to the development of metal matrix composites. This study investigates the fabrication of CP Ti-WC composites using an additive manufacturing process and explores the effect of the WC content on the microstructure, mechanical properties, and corrosion resistance. Regarding the mechanical properties, the tensile strength and hardness progressively increase with increasing WC content owing to microstructural refinement and solid solution strengthening caused by W. The alloy containing 5 wt% WC displays the respective maximum strength and hardness of 1042 MPa and 362.2 HV. Furthermore, WC addition enhances the corrosion resistance of CP Ti in a 70 % H2SO4 solution. Compared to those of the other samples, the alloy with 5 wt% WC exhibits the lowest mass loss (0.00242 mg/cm2) and current density in the passivation region, which are attributed to the microstructural refinement aiding in the formation of a stable oxide layer. Thus, this research highlights the potential of CP Ti-WC composites, which exhibit improved mechanical performances and corrosion resistances for use in demanding applications, with insights into microstructural control and property enhancement

A systematic survey of floral nectaries

The construction of classifications, as well as the understanding of biological diversity, depends upon a careful comparison of attributes of the organisms studied (Stuessy, 1990). It is widely known that data from diverse sources showing differences from taxon to taxon are of systematic significance. Dur-ing the 20th century, systematists have emphasized that their discipline involves a synthesis of all knowledge (Stevens, 1994) or, in other words, the variation of as many relevant characters as possible should be incorporated into the natural system to be constructed. The extent to which particular characters are constant or labile will determine their usefulness to syste-matics. In general, more conservative characters will be valuable in defining families and orders, whereas more labile characters may be useful at the ge-neric and specific levels (Webb, 1984). There is no doubt that floral characters are among the most used in the classification of flowering plants. At the same time, they constitute essential features in diagnostic keys to taxa in both taxonomic treatments and Floras (Cronquist, 1981, 1988).Fil: Bernardello, Gabriel Luis Mario. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Córdoba. Instituto Multidisciplinario de Biología Vegetal. Universidad Nacional de Córdoba. Facultad de Ciencias Exactas Físicas y Naturales. Instituto Multidisciplinario de Biología Vegetal; Argentin