Sulu Çinko İyon Bataryalar: Mangan Oksit Katot Aktif Malzemeleri

Year 2024, EARLY VIEW, 1 - 1

Mehmet Feryat Gülcan , Sebahattin Gürmen

https://doi.org/10.2339/politeknik.1525347

Abstract

Sürdürülebilirliğin arttırılmasın yolu karbon salınım değerlerinin azaltılmasından geçmektedir. Fosil kaynaklı enerji üretim yöntemlerinin kullanımlarının azaltıması ile karbon salınımının azaltılabilmesi, yenilenebilir enerji üretim sistemlerine geçişle sağlanması hedeflenmektedir. Ancak yenilenebilir sistemler enerji depolama uygulamaları olmadan kullanılamamaktadır. Enerji depolama sistemlerinin önemi ön plana çıkmaktadır. Enerji depolama sistemleri arasında lityum iyon bataryalar, 1990 yılında ticarileştikten sonra yaygın olarak kullanılsa da; lityum kaynaklarının miktarı, üretimi ve lityum iyon bataryaların güvenlik sorunları sebebiyle yeni arayışlara devam edilmektedir. Yeni arayışlar içerisinde farklı iyon bataryalardan sulu çinko iyon batarya sistemleri yüksek hacimsel kapasitesi, daha güvenili olması ve uygun maliyetli ile ön plana çıkmaktadır.
Bu çalışmada; yeni nesil iyon bataryalardan olan çinko iyon bataryaların çalışma prensibi ve kullanılan mangan oksit katot aktif malzemeleri, üretim-özellik-performans ilişkisi üzerine bir derleme gerçekleştirilmiştir.

Keywords

çinko, batarya, pozitif elektrot, mangan oksit

Supporting Institution

İstanbul Teknik Üniversitesi

Project Number

MGA-2024-44799

Thanks

MGA-2024-44799 numaralı projemizi destekleyen İstanbul Teknik Üniversitesine teşekkürlerimizi sunarız.

Aqueous Zinc Ion Batteries: Manganese Oxide Cathode Active Material Properties

Abstract

The ultimate goal is to decrease carbon emission levels in order to help improve sustainability. Yet, in order to utilize the desired renewable systems, it is imperative to incorporate energy storage technologies due to the discontinuation of fossil-based production techniques previously employed. At this juncture, the significance of energy storage systems becomes prominent. Despite the introduction of lithium-ion batteries in 1990 as a solution to this issue, ongoing research persists due to concerns over the availability of lithium resources, production challenges, and safety issues associated with lithium-ion batteries. Zinc ion batteries are notable among the several types of ion batteries now accessible because to their aqueous systems, high volumetric capacity, excellent durability, and cost-effectiveness.
This study focuses on elucidating the working mechanism of zinc ion batteries, which belong to the next generation of ion batteries. Additionally, it examines the characteristics of manganese oxide cathode active materials, with particular emphasis on the connection between production, properties, and performance.

Keywords

zinc, battery, positive electrode, manganese oxide

Project Number

MGA-2024-44799

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