Bilayer heterojunction electrode to realize multivalent ion in bifunctional devices: aqueous aluminum electrochromic supercapacitor with transparent nanostructured titania/molybdenum oxide was written by Ezhilmaran, Bhuvaneshwari;Bhat, S. Venkataprasad. And the article was included in Chemical Engineering Journal (Amsterdam, Netherlands) in 2022.Related Products of 7447-41-8 The following contents are mentioned in the article:
Bifunctional electrochromic energy storage devices are of great potential in energy-efficient technologies. Present electrochromic capacitors utilize monovalent ion intercalation, and switching to a multivalent ion such as Al3+ is sought to sustainably overcome the prevailing performance limitations. However, the realization of such a bifunctional device has remained a challenge, owing to the strong electrostatic interaction of multivalent ions with the electrode material. To cross this hurdle, we present here a nanostructured transparent anatase TiO2/α-MoO3 bi-layer electrode having a host with wide lattice spacing and forming a type II heterojunction at the interface. The favorable features offered by MoO3 and the built-in potential at the heterojunction interface resulted in a superior and stable performance in terms of coloration efficiency (128 cm2/C), transmittance change (54%), switching time (∼1s) and areal capacitance (218.8 mF/cm2). Thus, a new approach of electrode design for achieving multivalent ion intercalation in bifunctional devices is exemplified with an aqueous aluminum electrochromic supercapacitor, and the best-in-class bifunctional performance of the TiO2/MoO3 bilayer heterojunction electrode proves its potential to be used in energy-saving technologies of the future. This study involved multiple reactions and reactants, such as Lithium chloride (cas: 7447-41-8Related Products of 7447-41-8).
Lithium chloride (cas: 7447-41-8) belongs to organic chlorides. Chlorination modifies the physical properties of hydrocarbons in several ways. These compounds are typically denser than water due to the higher atomic weight of chlorine versus hydrogen. Organochlorine compounds are lipophylic, meaning they are more soluble in fat than in water. This gives them a high tenancy to accumulate in the food chain (biomagnification).Related Products of 7447-41-8
Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics