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Advances in Chemical Engineering and Science

Advances in Chemical Engineering and Science

Advances in Chemical Engineering and Science

ISSN Print: 2160-0392
ISSN Online: 2160-0406
www.scirp.org/journal/aces
E-mail: aces@scirp.org
"An Effective Mixing for Lithium Ion Battery Slurries"
written by Darjen Liu, Li-Chun Chen, Ta-Jo Liu, Tan Fan, Erh-Yeh Tsou, Carlos Tiu,
published by Advances in Chemical Engineering and Science, Vol.4 No.4, 2014
has been cited by the following article(s):
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[2] Data specifications for battery manufacturing digitalization: Current status, challenges, and opportunities
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[3] Understanding slurry formulations to guide solution-processing of solid electrolytes
Journal of Power …, 2022
[4] Model fluid for coating flows of Li-ion battery anode slurry
Journal of Materials Science, 2022
[5] Roadmap on Li-ion battery manufacturing research
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[6] Rheological interpretation of the structural change of LiB cathode slurry during the preparation process
JCIS Open, 2022
[7] Electrode fabrication process and its influence in lithium-ion battery performance: State of the art and future trends
Méndez, CM Costa - Electrochemistry …, 2022
[8] Advanced manufacturing approaches for electrochemical energy storage devices
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[9] Process‐Structure‐Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review
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[10] Viscosity Analysis of Battery Electrode Slurry
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[11] Quality Improvements for Anode Coating in Lithium-Ion Battery Cell Manufacturing: A Case Study at Northvolt Labs
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[12] Frequency transducers of gas concentration for the diagnosis of strains of bacteria Helicobacter pylori
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[13] Investigation of Lithium-Ion Battery Electrode Fabrication Through a Predictive Particle-Scale Model Validated by Experiments
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[14] JCIS Open
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[15] Einfluss der Kompaktierung auf die Elektrodenmikrostruktur und elektrochemische Performance bei Lithium-Ionen-Zellen
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[16] The Role of Pilot Lines in Bridging the Gap Between Fundamental Research and Industrial Production for Lithium‐Ion Battery Cells Relevant to Sustainable …
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[17] Machine Learning-Based on Assessment of the Impact of the Manufacturing Process on Battery Electrode Heterogeneity
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[18] Effect of calendering on rate performance of Li 4 Ti 5 O 12 anodes for lithium-ion batteries
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[19] Optimized printed cathode electrodes for high performance batteries
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[20] Current and future lithium-ion battery manufacturing
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[21] Opportunities for the State-of-the-Art Production of LIB Electrodes—A Review. Energies 2021, 14, 1406
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[22] Advanced electrode processing of lithium ion batteries: A review of powder technology in battery fabrication
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[23] Opportunities for the State-of-the-Art Production of LIB Electrodes—A Review
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[24] 8.5 Analytical studies of piston pulsation homogenization of milk
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[25] A Model for Investigating Sources of Li-Ion Battery Electrode Heterogeneity: Part I. Electrode Drying and Calendering Processes
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[26] Functional TEMPO-containing Polymers: Synthesis and Application in Organic Radical Batteries
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[27] A Thermodynamic and Feasibility Study of Green Solvents for the Fabrication of Water Treatment Membranes
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[28] High Energy Li‐Ion Electrodes Prepared via a Solventless Melt Process
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[29] Effects of Extended Aqueous Processing on Structure, Chemistry, and Performance of Polycrystalline LiNixMnyCozO2 Cathode Powders
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[30] Surface‐Functionalized Graphite as Long Cycle Life Anode Materials for Lithium‐ion Batteries
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[31] Characterization of the Effects of Solid Binding Peptides on the Synthesis of Lithium Cobalt Phosphate and Lithium Ion Electrode Assembly
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[32] The Effect of Crystalline Microstructure of PVDF Binder on Mechanical and Electrochemical Performance of Lithium-Ion Batteries Cathode
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[33] Understanding the Relationships between Ion Transport, Electrode Heterogeneity, and Li-Ion Cell Degradation Through Modeling and Experiment
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[34] High Energy Li− Ion Electrodes Prepared via a Solventless Melt Process
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[35] Simple Approach: Heat Treatment to Improve the Electrochemical Performance of Commonly Used Anode Electrodes for Lithium-Ion Batteries
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[36] Strategy for Long Cycling Performance of Graphite/LiNi1/3Mn1/3Co1/3O2 Full-Cell Through High-Efficiency Slurry Preparation
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[40] Na-ion battery development: from electrode processing studies to heat generation model of a monolayer pouch cell
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[41] Nano-/Micro-engineering for Future Li–Ion Batteries
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[42] On the study of mixing and drying on electrochemical performance of spinel LiMn2O4 cathodes
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[43] Composite Electrode Ink Formulation for All Solid-State Batteries
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[44] Recycled silicon powder coated on carbon paper used as the anode of lithium ion batteries
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[45] Microstructural Influence on Electrochemical Properties of LiFePO4/C/Reduced Graphene Oxide Composite Cathode
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[48] Pulvertechnisch hergestellte Werkstoffe für die Elektromobilität—Teil 1: Batterien
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[49] Current status and challenges for automotive battery production technologies
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[50] Polymer Based Nanocomposites as Multifunctional Structure for Space Radiation Shielding: A Study of Nanomaterial Fabrications and Evaluations
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[51] Poly (Styrene-Butene/Ethylene-Styrene): a New Polymer Binder for High Performance Printable Lithium-Ion Battery Electrodes
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[52] Investigation of the Use of a Bio-Derived Solvent for Non-Solvent-Induced Phase Separation (NIPS) Fabrication of Polysulfone Membranes
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[53] The Influence of Slurry Rheology on Lithium‐ion Electrode Processing
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[54] Simulation and Experiments to Understand the Manufacturing Process, Microstructure and Transport Properties of Porous Electrodes
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[55] Effect of viscosity of vathode slurry on automotive power battery
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[56] Percolation behaviors of model carbon black pastes
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[57] 3D Printable Lithium Ion Batteries and the Effect of Aspect Ratio of CuAg Nanowires on
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[58] Production requirements for 35 GWh lithium-ion battery factory
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[59] The Influence of Slurry Rheology on Lithium-ion Electrode Processing
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[60] UNDERSTANDING AND IMPROVING MANUFACTURING PROCESSES FOR MAKING LITHIUM-ION BATTERY ELECTRODES
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[61] 用于锂离子电池的石墨烯导电剂: 缘起, 现状及展望
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[62] All‐Printed, Stretchable Zn‐Ag2O Rechargeable Battery via Hyperelastic Binder for Self‐Powering Wearable Electronics
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[63] Effect of Composite Electrode Slurry Preparation Method on Electrochemical Characteristics of LiFePO4/C Based Li-ion Cell
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[64] KAJIAN APLIKASI BAHAN DENGAN KONDUKTIVITAS LISTRIK TINGGI UNTUK MENINGKATKAN UNJUK KERJA BATERAI ION LITIUM
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[65] Optimization of Microwave Synthesized Carbon Coated Nano LiFePO4 Active Cathode Material Composition for Li-Ion Batteries
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[66] Understanding Interfacial‐Energy‐Driven Dry Powder Mixing for Solvent‐Free Additive Manufacturing of Li‐Ion Battery Electrodes
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[67] Simulation Of Li-Ion Coin Cells Using Comsol Multiphysics
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[68] Simulation of Micro/Nanopowder Mixing Characteristics for Dry Spray Additive Manufacturing of Li-Ion Battery Electrodes
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[69] Scalable Dry Printing Manufacturing to Enable Long‐Life and High Energy Lithium‐Ion Batteries
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[70] Powder-Based Additive Manufacturing of Li-Ion Batteries and Micropowder Mixing Characteristics
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[71] Morphological Structure Characterizations in Lithium-Ion Battery (LIB) Slurry under Shear Rotational Conditions by On-Line Dynamic Electrochemical Impedance …
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[72] Rheological and adhesive properties of Li-ion battery slurry from capillary suspension
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[73] Graphene conductive additives for lithium ion batteries: Origin, progress and prospect
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[74] Conveying Advanced Li‐ion Battery Materials into Practice The Impact of Electrode Slurry Preparation Skills
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[75] Improvement of Lithium‐ion Batteries Performance by Two‐layered Slot‐Die Coating Operation
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[76] Viscoelastic Analysis of Dispersion Process of Highly Concentrated Suspension for LiB Cathodes
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[77] 鋰電池極板製作之分析: 混漿與塗佈
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[78] Experiment and simulation of the fabrication process of lithium-ion battery cathodes for determining microstructure and mechanical properties
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[79] Improvement of lithium-ion battery performance using a two-layered cathode by simultaneous slot-die coating
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[80] Solvent-Free Manufacturing of Electrodes for Lithium-ion Batteries
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[82] Design and Fabrication of a Li-Ion Battery Electrode Coating Fixture
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