Khikmah Nur Rikhy Stulasti scite author profile

Khikmah Nur Rikhy Stulasti

4Publications

20Citation Statements Received

176Citation Statements Given

How they've been cited

How they cite others

245

176

Affiliations

Sebelas Maret University

Publications

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Review of various sulfide electrolyte types for solid-state lithium-ion batteries

Suci

Aliwarga²,

Azinuddin

et al. 2022

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The high sulfide ion polarization is known to cause increased ionic conductivity in the solid sulfide-type electrolytes. Three groups of sulfide-based solid-state electrolytes, namely, Li-P-S, Li6PS5X (X: Cl, Br, and I), and Li x MP x S x (M: Sn, Si, and Al) were reviewed systematically from several aspects, such as conductivity, stability, and crystal structure. The advantages and disadvantages of each electrolyte were briefly considered and compared. The method of the preparation was presented with experimental and theoretical studies. The analysis that has been carried out showed that the solid electrolyte Li10GeP2S12 is superior to others with an ionic conductivity of 12 × 10−2 S cm−1. This conductivity is comparable to that of conventional liquid electrolytes. However, the availability and high price of Ge are the problems encountered. Furthermore, because sulfide-based solid electrolytes have low chemical stability in ambient humidity, their handling is restricted to inert gas environments. When solid sulfide electrolytes are hydrolyzed, structural changes occur and H2S gas is produced. The review’s objective includes presenting a complete knowledge of sulfide-solid electrolyte synthesis method, characteristics, such as conductivity, structure, and stability, as well as generating more efficient and targeted research in enhancing the performance of the chemical substance.

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Sodium-ion battery from sea salt: a review

Nurohmah

Nisa

Stulasti

et al. 2022

Mater Renew Sustain Energy

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The electrical energy storage is important right now, because it is influenced by increasing human energy needs, and the battery is a storage energy that is being developed simultaneously. Furthermore, it is planned to switch the lithium-ion batteries with the sodium-ion batteries and the abundance of the sodium element and its economical price compared to lithium is the main point. The main components anode and cathode have significant effect on the sodium battery performance. This review briefly describes the components of the sodium battery, including the anode, cathode, electrolyte, binder, and separator, and the sources of sodium raw material is the most important in material synthesis or installation. Sea salt or NaCl has potential ability as a raw material for sodium battery cathodes, and the usage of sea salt in the cathode synthesis process reduces production costs, because the salt is very abundant and environmentally friendly as well. When a cathode using a source of Na2CO3, which was synthesized independently from NaCl can save about 16.66% after being calculated and anode with sodium metal when synthesized independently with NaCl can save about 98% after being calculated, because sodium metal is classified as expensive matter.

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Production of LiNi0.6Mn0.2Co0.2.2O2 via fast oxalate precipitation for Li-ion

Jumari¹,

Stulasti²,

Halimah³

et al. 2020

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A Novel Synthesis of Cathode Material NaNi0.5Ti0.5O2 for Sodium-Ion Batteries

Nurohmah

Stulasti

Suci

et al. 2022

KEM

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The storage of electrical energy is an important thing today because it is influenced by the increasing human energy needs. Batteries are one of the energy storage that continues to be explored. Sodium-ion batteries are batteries that are planned to replace lithium-ion batteries. The abundance of sodium elements and their more economical price than lithium are the main attractions. The main constituent components of sodium batteries are anodes and cathodes. Both have a significant influence on the performance of sodium batteries. Currently, several cathodes have been developed but have some challenges especially their instability to air exposure. NaNi0.5Ti0.5O2 is a transition metal oxide-based cathode that has been known to have good structural stability. In this study, NaNi0.5Ti0.5O2 has successfully developed using a combination method of co-precipitation and solid-state. The precipitant is oxalic acid, while the chelating agent is ammonia. The obtained oxalate precursor was sintered in the airstream. Characterization of NaNi0.5Ti0.5O2 is carried out. XRD patterns demonstrate a hexagonal-layered material structure. The material was achieved after the sintering process, according to FTIR analysis. XRF analysis confirmed the composition of the final product in the form of Ni 54.7% and Ti 45.26%. The SEM test showed uniform particles with an average size of 3 microns. Small particle size, which allows greater diffusion of Na ions thereby improving electrochemical performance. This structure characterization result shown that the used method has been succeed. The obtained EIS graph is a semi-circle and slope that shows the process of charge transfer of lithium ions on the surface of the material and electrolyte.

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