Comparative analysis of ternary lithium batteries and lithium iron phosphate by Liu Ruoxuan

“…Ternary lithium batteries (TLB) and lithium iron phosphate batteries (LIPB) are two popular battery types in the current battery market. …”
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Study on the behavior of impurity removal from lithium-iron-phosphate slag using the ultrasonic-assisted sulphuric acid leaching by Zhao Y., Wang Y.-H., Wu J.-J., Ma W.-H.

“…The recovery of iron phosphate from the leaching slag of used lithium iron phosphate cathode materials is a crucial step to achieve closed-loop recovery of lithium iron phosphate, which has not yet been effectively accomplished. …”
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The change rule of smoke dispersion and temperature evolution in fires within lithium iron phosphate energy storage prefabricated cabin by ZHANG Yin, QIN Chaoqun, TIAN Shuangshuang, GE Zhichao, DONG Jun, ZHANG Xiaoxing

Subjects: “…lithium iron phosphate battery…”
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Recycling of Lithium Iron Phosphate (LiFePO₄) Batteries from the End Product Quality Perspective by Deise F. Barbosa de Mattos, Simon Duda, Martina Petranikova

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Data-driven modeling of open circuit voltage hysteresis for LiFePO4 batteries with conditional generative adversarial network by Lisen Yan, Jun Peng, Zeyu Zhu, Heng Li, Zhiwu Huang, Dirk Uwe Sauer, Weihan Li

Subjects: “…Lithium iron phosphate (LFP) batteries…”
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A Scenario-Based Simulation Study for Economic Viability and Widespread Impact Analysis of Consumption-Side Energy Storage Systems by Vedat Kiray

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Comparative Study on Environmental Impact of Electric Vehicle Batteries from a Regional and Energy Perspective by Ruiqi Feng, Wei Guo, Chenjie Zhang, Yuxuan Nie, Jiajing Li

“…In the realm of electric vehicles, ternary lithium batteries (NCM) and lithium iron phosphate batteries (LFP) are two widely used batteries. …”
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Robust Tracking Control of a Three-Phase Bidirectional Charger for Electric Vehicle by Chivon Choeung, Meng Leang Kry, Young-Il Lee

“…The efficacy of the proposed controller is verified through simulation and experimental results on 102.4 V Lithium iron phosphate (LiFePO4) batteries.…”
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State-of-Charge Estimation and Active Cell Pack Balancing Design of Lithium Battery Power System for Smart Electric Vehicle by Z. C. Gao, C. S. Chin, W. D. Toh, J. Chiew, J. Jia

“…This paper presents an integrated state-of-charge (SOC) estimation model and active cell balancing of a 12-cell lithium iron phosphate (LiFePO4) battery power system. The strong tracking cubature extended Kalman filter (STCEKF) gave an accurate SOC prediction compared to other Kalman-based filter algorithms. …”
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Lithium-Ion Battery Degradation Based on the CNN-Transformer Model by Yongsheng Shi, Leicheng Wang, Na Liao, Zequan Xu

“…The dataset used for training and validation consists of charge–discharge data from 124 lithium iron phosphate batteries. The experimental results include an analysis of the model training results for both single-battery and multiple-battery data, compared with commonly used models such as LSTM and Transformer. …”
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Energy Management Strategy for a Hybrid Power System for Ocean Engineering Vessels Based on an Improved Particle Swarm Optimisation Algorithm by Liu Kai, Zeng Xiangming, Yan Guohua

“…Post-conversion, the main diesel engine drives the propeller, and is supported by a lithium iron phosphate battery energy storage system in conjunction with the diesel engine and shaft generators to achieve certain energy efficiency and emission reduction goals. …”
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Optimizing Recycling Processes for Mixed LFP/NMC Lithium-Ion Batteries: A Comparative Study of Acid-Excess and Acid-Deficient Leaching by Pierric Hubert, Angelina Noclain, Safi Jradi, Alexandre Chagnes

“…This study explores the optimization of hydrometallurgical processes for recycling lithium-ion batteries (LIBs) containing a mixture of lithium iron phosphate (LFP) and nickel–manganese–cobalt (NMC) cathodes. …”
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Recovery of LiFePO4 cathodes: Criticalities and prospect towards a long-term eco-friendly solution by B. Visone, O. Senneca, P.P. Prosini, B. Apicella

“…Lithium iron phosphate batteries are currently getting increasing attention due to their low cost, good cycling stability and high safety characteristics. …”
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Design Analysis of 26650 and 18650 LFP Cells for High Power and Low Temperature Use Cases by Florian Wätzold, Anton Schlösser, Max Leistikow, Julia Kowal

“…This study investigates the design and geometric properties of high-power and low-temperature 18650 and 26650 lithium iron phosphate (LFP) cells. The analysis focuses on the geometry and components’ thicknesses and deriving CAD models for both cell formats. …”
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Recovery of pure lithium phosphate from sulfuric acid leaching solutions of spent LiFePO4 batteries by solvent extraction and chemical precipitation by Chen J., Tran T. T., Lee M. S.

“…With the increasing use of electric vehicles, the demand for lithium iron phosphate batteries (LiFePO4) has risen sharply. …”
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Identification of cell chemistries in lithium-ion batteries: Improving the assessment for recycling and second-life by Christopher Wett, Jörg Lampe, Dominik Görick, Thomas Seeger, Bugra Turan

“…The results especially demonstrate the effectiveness of the approach to distinguish between lithium iron phosphate (LFP) and lithium nickel manganese cobalt (NMC) cells.…”
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Impact of electric vehicle battery recycling on reducing raw material demand and battery life-cycle carbon emissions in China by Rui Jiang, Chengke Wu, Wei Feng, Kairui You, Jian Liu, Guangmin Zhou, Lujing Liu, Hui-Ming Cheng

“…Integrating a national-level vehicle stock turnover model with life-cycle carbon emission assessment, we found that replacing nickel-cobalt-manganese batteries with lithium iron phosphate batteries with battery recycling can reduce lithium, cobalt, and nickel demand between 2021 and 2060 by up to 7.8 million tons (Mt) (67%), 12.4 Mt (96%), and 37.2 Mt (93%), respectively, significantly decreasing reliance on import. …”
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Measurement of the temperature-dependent cross-plane thermal conductivity of the Li-ion battery pouch cell by Minjoo Kim, Dong-min Kim, Young-Beom Kim, Bong Jae Lee

“…This study presents an effective approach for precisely measuring the cross-plane thermal conductivity of Lithium Iron Phosphate (LFP) pouch cell by utilizing a guarded-hot-plate (GHP) method. …”
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Research on the Thermal Runaway Behavior and Flammability Limits of Sodium-Ion and Lithium-Ion Batteries by Changbao Qi, Hewu Wang, Minghai Li, Cheng Li, Yalun Li, Chao Shi, Ningning Wei, Yan Wang, Huipeng Zhang

“…This study investigates the thermal runaway characteristics of sodium-ion batteries (NIBs), lithium iron phosphate batteries (LFP), and lithium-ion batteries with NCM523 and NCM622 cathodes. …”
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Structural and Electrochemical Characterization of Pure LiFePO4 and Nanocomposite C-LiFePO4 Cathodes for Lithium Ion Rechargeable Batteries by Arun Kumar, R. Thomas, N. K. Karan, J. J. Saavedra-Arias, M. K. Singh, S. B. Majumder, M. S. Tomar, R. S. Katiyar

“…Pure lithium iron phosphate (LiFePO4) and carbon-coated LiFePO4 (C-LiFePO4) cathode materials were synthesized for Li-ion batteries. …”
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