Keywords: فسفات آهن لیتیم; Lithium-ion cell; Entropy; Cooling; Lithium iron phosphate; Graphite;
مقالات ISI فسفات آهن لیتیم (ترجمه نشده)
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Keywords: فسفات آهن لیتیم; Automotive battery; Carbon-enhanced lead-acid; Dynamic Charge Acceptance; Hybrid Electric Vehicle; Lithium iron phosphate; Test regime;
High volumetric energy density of LiFePO4/C microspheres based on xylitol-polyvinyl alcohol complex carbon sources
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Volumetric energy density; Microspheres; Complex carbon source; Carbon coating;
Influence of synthesis parameters on the physicochemical and electrochemical properties of LiFePO4 for Li-ion battery
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Solution combustion; Fuel; Graphene oxide and electrochemical performance;
Cold sintering approach to fabrication of high rate performance binderless LiFePO4 cathode with high volumetric capacity
Keywords: فسفات آهن لیتیم; Cold sintering process; Lithium iron phosphate; Electrode density; Volumetric capacity; Rate performance;
Graphene foam supported LiFePO4 nanosheets composite as advanced cathode for lithium ion batteries
Keywords: فسفات آهن لیتیم; Porous materials; Thin films; Li ion batteries; Lithium iron phosphate; Energy storage and conversion;
Identifying compatibility of lithium salts with LiFePO4 cathode using a symmetric cell
Keywords: فسفات آهن لیتیم; Lithium-ion battery; Electrolyte; Lithium iron phosphate; Cathode electrolyte interphase; Symmetric cell;
Integrated carbon cloth supported LiFePO4/N-C films as high-performance cathode for lithium ion batteries
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Porous materials; Energy storage and conversion; Lithium ion batteries; Thin films;
Effect of negative/positive capacity ratio on the rate and cycling performances of LiFePO4/graphite lithium-ion batteries
Keywords: فسفات آهن لیتیم; Lithium ion battery; N/P ratio; Cell design; Capacity balancing; Lithium iron phosphate; Graphite;
Activation and degradation of electrospun LiFePO4 battery cathodes
Keywords: فسفات آهن لیتیم; Electrospinning; Lithium iron phosphate; Lithium-ion battery; Aging; Electrode structuring; LiFePO4;
Hydrothermal preparation and performance of LiFePO4 by using Li3PO4 recovered from spent cathode scraps as Li source
Keywords: فسفات آهن لیتیم; Lithium-ion batteries; Lithium iron phosphate; Recycling; Lithium phosphate; Hydrothermal process;
Hybrid lithium-ion capacitor with LiFePO4/AC composite cathode - Long term cycle life study, rate effect and charge sharing analysis
Keywords: فسفات آهن لیتیم; Hybrid energy storage device; Composite cathode; Li-ion capacitor; Lithium iron phosphate; Pre-lithiation; Long cycle life;
Size-dependent phase morphologies in LiFePO4 battery particles
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Two-phase equilibrium; Coherency strain; Phase-field model; Spinodal decomposition; Electro-autocatalysis;
An integrated reduced order model considering degradation effects for LiFePO4/graphite cells
Keywords: فسفات آهن لیتیم; Extended Kalman Filter; Lithium iron phosphate; Reduced order model; Side reaction;
Ultrathin LiFePO4/C cathode for high performance lithium-ion batteries: Synthesis via solvothermal transformation of iron hydroxyl phosphate Fe3(PO4)2(OH)2 nanosheet
Keywords: فسفات آهن لیتیم; Lithium-ion batteries; Lithium iron phosphate; In-situ carbon coating; Solvothermal; Nanosheet;
A comparative study on LiFePO4/C by in-situ coating with different carbon sources for high-performance lithium batteries
Keywords: فسفات آهن لیتیم; Lithium-ion batteries; Ionic liquid; In-situ coating; Lithium iron phosphate; Graphitized carbon films;
Concentration-controlled morphology of LiFePO4 crystals with an exposed (100) facet and their enhanced performance for use in lithium-ion batteries
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Lithium-ion batteries; Solvothermal; Crystal morphology;
A facile chemical route to synthesize copper particles-modified LiFe0.95Mo0.05PO4 for lithium-ion batteries
Keywords: فسفات آهن لیتیم; Energy storage and conversion; Composite materials; Lithium iron phosphate; Copper particles; Surface modification;
Surfactant assisted solvothermal synthesis of LiFePO4 nanorods for lithium-ion batteries
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Lithium-ion battery; Surfactant; Nanorods; Solvothermal synthesis;
Suppressing the formation of Fe2P: Thermodynamic study on the phase diagram and phase transformation for LiFePO4 synthesis
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Iron phosphide; Decomposition; Carbothermal reduction; Thermodynamics;
New method evaluating currents keeping the voltage constant for fast and highly resolved measurement of Arrhenius relation and capacity fade
Keywords: فسفات آهن لیتیم; Floating currents; LFP; LiPF6; Calendaric aging; Floating current analysis; FCE; full cycle equivalents; EC; ethylene carbonate; DMC; dimethylene carbonate; EMC; ethylene-methylene carbonate; DEC; diethylene carbonate; LFP; lithium iron phosphate; SEI; so
Enhanced electrochemical performance of LiFePO4 cathode with synergistic modification of Na3V2(PO4)3 and carbon network
Keywords: فسفات آهن لیتیم; Hybrid cathode material; Sodium vanadium phosphates; Lithium iron phosphate;
Synthesis and electrochemical properties of xLiFePO4·(1âx)Na3V2(PO4)2F3/C composite for lithium-ion batteries
Keywords: فسفات آهن لیتیم; Hybrid cathode material; Sodium vanadium fluorophosphates; Lithium iron phosphate;
Enhancing electrochemical performance of LiFePO4 by vacuum-infiltration into expanded graphite for aqueous Li-ion capacitors
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; nanocomposites; supercapacitors; li-ion capacitors; aqueous electrolytes;
Electrochemical performance of all-solid-state lithium batteries using inorganic lithium garnets particulate reinforced PEO/LiClO4 electrolyte
Keywords: فسفات آهن لیتیم; All-solid-state battery; solid composite electrolyte; Lithium; Interfacial resistance; Lithium iron phosphate;
Physicochemical and electrochemical performance of LiFe1âxNixPO4 (0â¤xâ¤1.0) solid solution as potential cathode material for rechargeable lithium-ion battery
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Ni-substitution; Solid-solution; Conductivity; Ragone plot;
Electrochemical impedance spectroscopy characterization of LiFePO4 cathode material with carboxymethylcellulose and poly-3,4-ethylendioxythiophene/polystyrene sulfonate
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Li-ion batteries; conducting polymer; impedance spectroscopy; binder;
PVDF-HFP/PET/PVDF-HFP composite membrane for lithium-ion power batteries
Keywords: فسفات آهن لیتیم; Electrospinning; Solution casting; PVDF-HFP; Quaternary ammonium-containing SiO2 nanoparticles modified PET nanofibrous nonwoven; Lithium-ion battery; Lithium iron phosphate;
LiFePO4/C nanocomposites for lithium-ion batteries
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; LiFePO4/C; Lithium-ion battery; Cathode material; Core-shell; Pseudocapacitance;
Effect of operating parameters on synthesis of lithium iron phosphate (LiFePO4) particles in near- and super-critical water
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Hydrothermal synthesis; Cathode material; Pressure;
High lithium ion conductivity in mechanically milled Nb-doped m-Li3Fe2(PO4)3
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Solid electrolyte; Mechanical milling; Ionic conduction; Lithium ion battery;
New liquid carbon dioxide based strategy for high energy/power density LiFePO4
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Liquid carbon dioxide; Uniform carbon coating; Hierarchical structure lithium ion batteries;
Nano-sized cathode material LiMn0.5Fe0.5PO4/C synthesized via improved sol-gel routine and its magnetic and electrochemical properties
Keywords: فسفات آهن لیتیم; lithium ion battery; cathode material; lithium manganese phosphate; lithium iron phosphate; magnetic property;
Synthesis and characterization of grape-like LiFe0.97M0.03PO4/C (M=Ni, CO, Mn) composites
Keywords: فسفات آهن لیتیم; Composite material; Lithium iron phosphate; Multi-doping; Grape-like;
Rapid photodegradation of methyl orange by oxalic acid assisted with cathode material of lithium ion batteries LiFePO4
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Oxalic acid; Photocatalytic degradation; Methyl orange
Electrochemical properties of V and Ti co-doping Li1.02FePO4/C material prepared by solid-state synthesis route
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; V and Ti co-doping; Phloroglucinol; Electrochemical properties;
Ionic Conducting and Surface Active Binder of Poly (ethylene oxide)-block-poly(acrylonitrile) for High Power Lithium-ion Battery
Keywords: فسفات آهن لیتیم; Lithium ion battery; Lithium iron phosphate; Poly(acrylonitrile); Poly(ethylene oxide); binder;
Dispersion, agglomeration, and gelation of LiFePO4 in water-based slurry
Keywords: فسفات آهن لیتیم; Cathode; Lithium iron phosphate; Slurry; Carbon coating; Dispersion; Gelation;
Truly quasi-solid-state lithium cells utilizing carbonate free polymer electrolytes on engineered LiFePO4
Keywords: فسفات آهن لیتیم; polymer electrolyte; PEDOT; lithium iron phosphate; corrosion protection; lithium battery;
Controllable synthesis of Li3PO4 hollow nanospheres for the preparation of high performance LiFePO4 cathode material
Keywords: فسفات آهن لیتیم; Lithium phosphate; Hollow sphere; Microreactor; Lithium iron phosphate;
Fast charging technique for high power LiFePO4 batteries: A mechanistic analysis of aging
Keywords: فسفات آهن لیتیم; Fast charging; Battery degradation modes; Lithium iron phosphate; Incremental capacity analysis; Mechanistic model simulations
Li3V2(PO4)3/LiFePO4 composite hollow microspheres for wide voltage lithium ion batteries
Keywords: فسفات آهن لیتیم; Lithium ion battery; Cathode; Heterogeneous isomorphism; Lithium iron phosphate; Lithium vanadium phosphate;
The low temperature electrochemical performances of LiFePO4/C/graphene nanofiber with 3D-bridge network structure
Keywords: فسفات آهن لیتیم; Lithium-ion battery; Graphene nanofiber; Lithium iron phosphate; Electrochemical performance; Low temperature;
Analysis of Thermal Aging Paths for Large-Format LiFePO4/Graphite Battery
Keywords: فسفات آهن لیتیم; Lithium iron phosphate; Capacity fading; Thermal aging paths; Temperature distribution;
Evaluation of apparent lithium-ion diffusion coefficients in FePO4/LiFePO4 cathode material particles from linear non-equilibrium thermodynamics and principle of electroneutrality
Keywords: فسفات آهن لیتیم; Lithium ion; Insertion electrode; Apparent diffusion coefficient; Lithium iron phosphate; Non-equilibrium thermodynamics; Electroneutrality
Electrospun carbon-based nanostructured electrodes for advanced energy storage - A review
Keywords: فسفات آهن لیتیم; 1D; one-dimensional; EVs; electric vehicles; HEVs; hybrid electric vehicles; LIB; lithium-ion battery; NIBs; Na-ion batteries; LSBs; Li-S batteries; NSBs; Na-S batteries; SCs; supercapacitors; EDLC; electrochemical double layer capacitors; CNFs; carbon na
Metal tetrabromophthalocyanines mediate the structure and electrochemical performance of lithium iron phosphate as cathode materials for lithium-ion batteries
Keywords: فسفات آهن لیتیم; Lithium-ion batteries; Lithium iron phosphate; Metal tetrabromophthalocyanines; Solvothermal process; Calcination method
Improved performance of porous LiFePO4/C as lithium battery cathode processed by high energy milling comparison with conventional ball milling
Keywords: فسفات آهن لیتیم; Electrochemical properties; Precipitation; Coatings; Amorphous materials; Lithium iron phosphate
Effects of sodium and vanadium co-doping on the structure and electrochemical performance of LiFePO4/C cathode material for lithium-ion batteries
Keywords: فسفات آهن لیتیم; Lithium-ion batteries; Cathode material; Lithium iron phosphate; Sodium and vanadium co-doping; Electrochemical performance
Electrochemical performance of microdisc-shaped carbon-coated lithium iron phosphate with preferentially exposed (0 1 0) planes in lithium sulfate aqueous solution
Keywords: فسفات آهن لیتیم; Microdisc; Lithium iron phosphate; Precursors; Precipitation; Aqueous solution