Energy storage and water splitting applications of self-grown Na 2 O-NiCl 2 upright standing nanoplates: a process of 3D nickel surface modification using seawater.
Sukhvinder Kaur SukhmaniRajaram S ManeTabassum A J SiddiquiShoyebmohamad Fattemohamad ShaikhSajjad HussainPublished in: Dalton transactions (Cambridge, England : 2003) (2023)
The recent trend in research fosters the use of abundant seawater for modifying metal surfaces as electrode materials for energy generation, storage, transport, and water-splitting technologies. Economic and ecofriendly seawater is used as a solvent for modifying the surface of 3D nickel-foam (NiF) to Na 2 O-NiCl 2 @NiF as an electrode material in electrochemical supercapacitors and water-splitting electrocatalysis applications. The phase of the as-obtained Na 2 O-NiCl 2 is confirmed from the proposed reaction mechanism, followed various physical measurement tests such as X-ray photoelectron spectroscopy and Fourier transform infrared analysis. The formation of Na 2 O-NiCl 2 is caused by a high operation temperature and pressure of seawater solvent, the presence of lone pair electrons on oxygen, and more reactivity of Na for combining with dissolved oxygen than the lone-pair free Cl (towards Ni). In addition to exceptional HER and OER electrocatalytic activities, i.e. , 146.3 mV cm -2 and 217 mV cm -2 at a scan rate of 5 mV s -1 to attain the 10 mA cm -2 current density, the Na 2 O-NiCl 2 has demonstrated moderate energy storage ability with considerable durability, i.e. , 2533 F g -1 specific capacitance at 3 A g -1 current density even after 2000 redox cycles. The as-assembled Na 2 O-NiCl 2 //Na 2 O-NiCl 2 symmetric electrochemical supercapacitor device has ignited a " CNED " panel consisting of nearly forty LEDs with full brightness, offering applied importance in home appliances. In nutshell, seawater-modified metal surfaces can be used for energy storage and water-splitting applications.