Atomic spectrometry update: Review of advances in the analysis of metals, chemicals and materials

There has been a large increase in the number of papers published that are relevant to this review over this review period. The growth in popularity of LIBS is rapid, with applications being published for most sample types. This is undoubtedly because of its capability to analyse in situ on a production line (hence saving time and money) and its minimally destructive nature meaning that both forensic and cultural heritage samples may be analysed. It also has a standoff analysis capability meaning that hazardous materials, e.g. explosives or nuclear materials, may be analysed from a safe distance. The use of mathematical algorithms in conjunction with LIBS to enable improved accuracy has proved a popular area of research. This is especially true for ferrous and non-ferrous samples. Similarly, chemometric techniques have been used with LIBS to aid in the sorting of polymers and other materials. An increase in the number of papers in the subject area of alternative fuels was noted. This was at the expense of papers describing methods for the analysis of crude oils. For nanomaterials, previous years have seen a huge number of single particle and field flow fractionation characterisations. Although several such papers are still being published, the focus seems to be switching to applications of the nanoparticles and the mechanistic aspects of how they retain or bind with other analytes. This is the latest review covering the topic of advances in the analysis of metals, chemicals and materials. It follows on from last year's review1-6 and is part of the Atomic Spectrometry Updates series

Platinum recycling going green via induced surface potential alteration enabling fast and efficient dissolution

The recycling of precious metals, for example, platinum, is an essential aspect of sustainability for the modern industry and energy sectors. However, due to its resistance to corrosion, platinum-leaching techniques rely on high reagent consumption and hazardous processes, for example, boiling aqua regia; a mixture of concentrated nitric and hydrochloric acid. Here we demonstrate that complete dissolution of metallic platinum can be achieved by induced surface potential alteration, an ‘electrode-less’ process utilizing alternatively oxidative and reductive gases. This concept for platinum recycling exploits the so-called transient dissolution mechanism, triggered by a repetitive change in platinum surface oxidation state, without using any external electric current or electrodes. The effective performance in non-toxic low-concentrated acid and at room temperature is a strong benefit of this approach, potentially rendering recycling of industrial catalysts, including but not limited to platinum-based systems, more sustainable

Recent advances in nanostructured intermetallic electrocatalysts for renewable energy conversion reactions

Highly active, stable, durable, and selective electrocatalysts for energy conversion devices are critical for securing a hydrogen-based clean and sustainable energy cycle. Recently, intermetallic nanostructures have emerged as a new class of advanced electrocatalysts. The ordered arrangement of constituent atoms with well-defined stoichiometry and crystal structure in the intermetallic nanostructures induces intensified ligand/strain effects and chemical stability compared to random alloy nanocatalysts, which results in improved catalytic activity and durability. In this review, we introduce recent advances in synthetic strategies for the generation of intermetallic nanostructures. We summarise representative examples that demonstrate enhanced catalytic performance by intermetallic structures in important renewable energy conversion reactions, including oxygen reduction, fuel oxidation, hydrogen evolution, oxygen evolution, and CO2 reduction. Finally, current issues and future perspectives of intermetallic nanocatalysts are presented