Alkaline
zinc–air batteries are promising energy storage
technologies with the advantages of low cost, ecological friendliness,
and high energy density. However, the rechargeable zinc–air
battery has not been used on a commercial scale because the zinc electrode
suffers from critical problems such as passivation, dendrite growth,
and hydrogen evolution reaction, which limit the practical applications
of zinc–air batteries. Herein, the Perspective summaries the
solutions to minimize the negative effects of zinc electrodes on discharge
performance, cycling life, and shelf life. The future direction of
academic research based on current studies of the existing challenges
is proposed.
Grid-level large-scale electrical energy storage (GLEES) is an essential approach for balancing the supply-demand of electricity generation, distribution, and usage. Compared with conventional energy storage methods, battery technologies are desirable energy storage devices for GLEES due to their easy modularization, rapid response, flexible installation, and short construction cycles. In general, battery energy storage technologies are expected to meet the requirements of GLEES such as peak shaving and load leveling, voltage and frequency regulation, and emergency response, which are highlighted in this perspective. Furthermore, several types of battery technologies, including lead-acid, nickel-cadmium, nickel-metal hydride, sodium-sulfur, lithium-ion, and flow batteries, are discussed in detail for the application of GLEES. Moreover, some possible developing directions to facilitate efforts in this area are presented to establish a perspective on battery technology, provide a road map for guiding future studies, and promote the commercial application of batteries for GLEES.
Flexible zinc−air batteries (ZABs) have been considered as one of the most outstanding energy storage devices for flexible and portable electronics because of their superior energy density and environmental friendliness. As the "blood" of flexible ZABs, electrolytes play a significant role in determining their performance, such as discharge working time, cycling property, and shelf life. Herein, a novel polymer electrolyte based on quaternary ammonium hydroxides is first applied in flexible zinc−air batteries. Tetraethylammonium hydroxide (TEAOH) is innovatively used as the ionic conductor with poly(vinyl alcohol) (PVA) as the polymer host in the polymer electrolyte and exhibits a good water retention capability, resulting in not only a good shelf life but also a good working life of the flexible zinc−air batteries. The fabricated polymer electrolyte maintains its high ionic conductivity of 30 mS cm −1 even after 2 weeks. In addition, the as-assembled zinc−air batteries based on the TEAOH−PVA electrolyte exhibit excellent discharge performance and cycling life compared to those based on the commonly used KOH−PVA electrolyte, and no notable degradation is observed after 2 weeks. Furthermore, flexible TEAOH−PVA-based zinc−air batteries can power a light-emitting diode (LED) electronic watch, a mobile phone, and an LED screen, indicating the very large potential of the high-performance zinc−air batteries that are safe, cost-effective, and remarkably flexible.
The Internet of Everything (IoE), which aims to realize information exchange and communications for anything with the Internet, has revolutionized our modern world. Serving as the driving force for devices in the IoE network, power supply systems play a fundamental role in the development of the IoE. However, due to the complexity, multifunctionality and wide‐scale deployment of diverse applications, power supply systems face great challenges, including distribution, connection, charging technologies, and management. In this review, some challenges and advances in the development of both power supply systems and their units are presented. In the overall system‐level field, establishing sustainable and maintenance‐free power supply systems through wireless connections, efficient power management and integrated energy harvesting and storage systems is highlighted. Additionally, the main performance metrics of power supply units are discussed, including energy density, service life, and self‐power ability. In addition, some directions of power quality assessment for both the system and unit levels of power supply systems are presented, aiming to provide insight into the future development of high‐performance power supply systems for the IoE.
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