Spinel structured LiMn₂O₄ prepared by laser annealing

“…Consequently, the prepared full cells have improved energy densities and rate capabilities. In addition, previous studies have confirmed that rapid laser annealing is a promising tool for obtaining the desired crystal structure of ceramic CAMs [40–43] …”

“…In addition, previous studies have confirmed that rapid laser annealing is a promising tool for obtaining the desired crystal structure of ceramic CAMs. [40][41][42][43] In this review, we present the recent progress of laser-based technologies to address the interfacial stability issues of SSBs. The overview of the interfacial problems and proposed approaches are briefly outlined in Section 2.…”

Laser‐Assisted Interfacial Engineering for High‐Performance All‐Solid‐State Batteries

“…Consequently, the prepared full cells have improved energy densities and rate capabilities. In addition, previous studies have confirmed that rapid laser annealing is a promising tool for obtaining the desired crystal structure of ceramic CAMs [40–43] …”

“…In addition, previous studies have confirmed that rapid laser annealing is a promising tool for obtaining the desired crystal structure of ceramic CAMs. [40][41][42][43] In this review, we present the recent progress of laser-based technologies to address the interfacial stability issues of SSBs. The overview of the interfacial problems and proposed approaches are briefly outlined in Section 2.…”

Laser‐Assisted Interfacial Engineering for High‐Performance All‐Solid‐State Batteries

“…21 For the manganite-based layered heterostructure NaMnO 2 , most work has focused on enhancing sodium ion storage. [22][23][24][25] As one of the cathodes for sodium ion batteries (SIBs), the manganitebased layered NaMnO 2 exhibits excellent electrochemical performance. However, most work has focused on enhancing sodium ion storage of NaMnO 2 , [26][27][28][29] while its lithium storage behavior has been less studied.…”

A layered-spinel heterostructure 0.5NaMnO₂–0.5Li_0.5Mn₂O₄ cathode for advanced lithium ion batteries

“…(Kalluri, Yoon et al 2017), (Kwak, Lim et al 2020), (Park, Kim et al 2010); (Li, Zhu et al 2019) On the other hand, cobalt-oxide based cathode electrodes suffer from environmental issues and the costly market price of cobalt. (Gong and Yang 2011); (Shi, Xiao et al 2018) These drawbacks have been urged to discover alternative cathode materials in replacement of LiCoO2 for Li-ion batteries such as layered rock salt structured LiCoO2 (Nayaka, Zhang et al 2018), spinel structured LiMn2O4, (Yan, Lin et al 2020) layered Li[Ni1/3Co1/3Mn1/3]O2, (Jo, Ku et al 2018) and olivine structured LiFePO4, (Gong, Xue et al 2016)etc. Among these materials, layered Li[NixCoyMn1−x−y]O2 is the most fascinating replacements of LiCoO2 due to high discharge capacity, operating voltage, high rate capability, proper structural and thermal resistivity, cycle-ability..…”

YEŞİL YÖNTEM İLE KÜRESEL Ni1/3Co1/3Mn1/3CO3 PARÇACIKLARIN SENTEZİ