Liquid-Metal-Enabled Mechanical-Energy-Induced CO Conversion.

A green carbon capture and conversion technology offering scalability and economic viability for mitigating CO emissions is reported. The technology uses suspensions of gallium liquid metal to reduce CO into carbonaceous solid products and O at near room temperature. The nonpolar nature of the liquid gallium interface allows the solid products to instantaneously exfoliate, hence keeping active sites accessible.

Liquid-Metal-Templated Synthesis of 2D Graphitic Materials at Room Temperature.

Room-temperature synthesis of 2D graphitic materials (2D-GMs) remains an elusive aim, especially with electrochemical means. Here, it is shown that liquid metals render this possible as they offer catalytic activity and an ultrasmooth templating interface that promotes Frank-van der Merwe regime growth, while allowing facile exfoliation due to the absence of interfacial forces as a nonpolar liquid. The 2D-GMs are formed at low onset potential and can be in situ doped depending on the choice of organic precursors and the electrochemical set-up.

Liquid metal dispersion by self-assembly of natural phenolics.

Gallic acid, a natural phenolic compound, efficiently establishes surface complexes with liquid gallium leading to the formation of an aqueous gallium dispersion via sonication. The surface functionalised gallium particles thus obtained were easily impregnated into paper membranes that could be turned from insulating to conductive by pressure induced deformation of the embedded particles.

Pastes and hydrogels from carboxymethyl cellulose sodium salt as supporting electrolyte of solid electrochemical supercapacitors.

Different carboxymethyl cellulose sodium salt (NaCMC)-based pastes and hydrogels, both containing a salt as supporting electrolyte, have been prepared and characterized as potential solid state electrolyte (SSE) for solid electrochemical supercapacitors (ESCs).The characteristics of the NaCMC-based SSEs have been optimized by examining the influence of five different factors in the capacitive response of poly(3,4-ethylenedioxythiophene) (PEDOT) electrodes: i) the chemical nature of the salt used as supporting electrolyte; ii) the concentration of such salt; iii) the concentration of cellulose used to prepare the paste; iv) the concentration of citric acid employed during NaCMC cross-linking; and v) the treatment applied to recover the supporting electrolyte after washing the hydrogel. The specific capacitance of the device prepared using the optimized hydrogel as SSE is 81.