Microbial electrolysis cell (MEC) holds the flexible potentials for waste biorefinery, pollutants
removal, CO 2 capture, and bioelectrosynthesis of clean and renewable electrofuels or …

Developing sustainable hydrogen production by efficient conversion technologies is vital to
address environmental and energy challenges. Microbial electrolysis cells (MECs) can …

Electrode potential–pH (Pourbaix) diagrams provide a phase map of the most stable
compounds of a metal, its corrosion products, and associated ions in solution. The utility of …

Cathode materials are critical for microbial electrolysis cell (MEC) development and its
contribution to achieving a circular hydrogen economy. There are numerous reports on the …

Despite the rich coordination chemistry, hydroxylamines are rarely used as ligands for
transition metal coordination compounds. This is partially because of the instability of these …

Portable and flexible energy devices demand lightweight and highly efficient catalytic
materials for use in energy devices. An efficient water splitting electrocatalyst is considered …

Hydrogen gas is a green energy carrier with great environmental benefits. Microbial
electrolysis cells (MECs) can convert low‐grade organic matter to hydrogen gas with low …

The stabilities of Ni metal and its derived compounds, including oxides, hydroxides, and
oxyhydroxides under electrochemical conditions, can be readily predicted from the Ni …

Abstract Well dispersed Pd-NiO nanoparticles (Pd-NiO NP's) formed over zeolite-NaY was
found to be highly efficient catalyst for the Suzuki-Miyaura cross-coupling reaction of aryl …

The electrochemical stabilities of nanofilms of Ni oxides and hydroxides are of special
importance to the diverse fields of catalysis, energy storage and conversion, and alloy …