The lithium iron phosphate (LiFePO₄) battery, also called LFP battery (with "LFP" standing for "lithium ferrophosphate"), is a type of rechargeable battery, specifically a lithium-ion battery, which uses LiFePO₄ as a cathode material. LiFePO₄ batteries have somewhat lower energy density than the more common LiCoO₂ design found in consumer electronics, but offers longer lifetimes, better power density (the rate that energy can be drawn from them) and are inherently safer. LiFePO₄ is finding a number of roles in vehicle use and backup power.

History [edit]

LiFePO₄ is a natural mineral of the olivine family. Its use as a battery electrode was first described in published literature by John Goodenough's research group at the University of Texas in 1996,^[1][2] as a cathode material for rechargeable lithium batteries. Because of its low cost, non-toxicity, the high abundance of iron, its excellent thermal stability, safety characteristics, electrochemical performance, and specific capacity (170 mA·h/g, or 610 C/g) it gained some market acceptance.^[3][4]

Its key barrier to commercialization was intrinsically low electrical conductivity. This problem, however, was then overcome by reducing the particle size, coating the LiFePO₄ particles with conductive materials such as carbon, and doping^[3] the result with cations of materials such as aluminium, niobium, and zirconium. This approach was developed by Yet-Ming Chiang and his coworkers at MIT. Products are now in mass production and are used in industrial products by major corporations including Black and Decker's DeWalt brand, the Fisker Karma, Daimler, Cessna and BAE Systems.^{[citation needed]}

MIT has introduced a new coating that allows the ions to move more easily within the battery. The "Beltway Battery" utilizes a bypass system that allows the lithium-ions to enter and leave the battery at a speed great enough to fully charge a battery in under a minute. The scientists discovered that by coating particles of lithium iron phosphate in a glassy material called lithium pyrophosphate, ions bypass the channels and move faster than in other batteries. Rechargeable batteries store up and discharge energy as charged atoms, known as ions, from between two electrodes called the anode and the cathode. Their charge and discharge rate are restricted by the speed with which these ions move. Such technology could reduce the weight and size of the batteries. A small prototype battery cell has been developed that can fully charge in 10 to 20 seconds, compared with six minutes for standard battery cells.^[5]

Advantages and disadvantages [edit]

This article contains a pro and con list. Please help improve it by integrating both sides into a more neutral presentation. (November 2012)

The LiFePO₄ battery uses a lithium-ion-derived chemistry and shares many advantages and disadvantages with other Lithium-ion battery chemistries. However, there are significant differences.

LFP chemistry offers a longer cycle life than other lithium-ion approaches.^[6]

The use of phosphates avoids cobalt's cost and environmental concerns, particularly concerns about cobalt entering the environment through improper disposal.^[6]

LiFePO₄ has higher current or peak-power ratings than LiCoO₂.^[7]

The energy density (energy/volume) of a new LFP battery is some 14% lower than that of a new LiCoO₂ battery.^[8] Also, many brands of LFPs have a lower discharge rate than lead-acid or LiCoO₂. Since discharge rate is a percentage of battery capacity a higher rate can be achieved by using a larger battery (more ampère-hours).

LiFePO₄ cells experience a slower rate of capacity loss (aka greater calendar-life) than lithium-ion battery chemistries such as LiCoO₂ cobalt or LiMn₂O₄ manganese spinel lithium-ion polymer batteries or lithium-ion batteries.^[9][10] After one year on the shelf, a LiFePO₄ cell typically has approximately the same energy density as a LiCoO₂ Li-ion cell, because of LFP's slower decline of energy density. Thereafter, LiFePO₄ likely has a higher density.

Safety [edit]

One important advantage over other lithium-ion chemistries is thermal and chemical stability, which improves battery safety.^[6] LiFePO₄ is an intrinsically safer cathode material than LiCoO₂ and manganese spinel. The Fe-P-O bond is stronger than the Co-O bond, so that when abused, (short-circuited, overheated, etc.) the oxygen atoms are much harder to remove. This stabilization of the redox energies also helps fast ion migration.^{[citation needed]}

As lithium migrates out of the cathode in a LiCoO₂ cell, the CoO₂ undergoes non-linear expansion that affects the structural integrity of the cell. The fully lithiated and unlithiated states of LiFePO₄ are structurally similar which means that LiFePO₄ cells are more structurally stable than LiCoO₂ cells.^{[citation needed]}

No lithium remains in the cathode of a fully charged LiFePO₄ cell—in a LiCoO₂ cell, approximately 50% remains in the cathode. LiFePO₄ is highly resilient during oxygen loss, which typically results in an exothermic reaction in other lithium cells.^[4]

As a result, lithium iron phosphate cells are much harder to ignite in the event of mishandling especially during charge, although any battery, once fully charged, can only dissipate overcharge energy as heat. Therefore failure of the battery through misuse is still possible. It is commonly accepted that LiFePO4 battery does not decompose at high temperatures.^[6] The difference between LFP and the LiPo battery cells commonly used in the aeromodeling hobby is particularly notable.^{[citation needed]}

Specifications [edit]

• Cell voltage
  • Min. discharge voltage = 2.8 V
  • Working voltage = 3.0 ~ 3.3 V
  • Max. charge voltage = 3.6 V
• Volumetric energy density = 220 Wh/dm³ (790 kJ/dm³)
• Gravimetric energy density = >90 Wh/kg^[11] (>320 J/g)
• 100% DOD cycle life (number of cycles to 80% of original capacity) = 2,000–7,000^[12]
• Cathode composition (weight)
  • 90% C-LiFePO4, grade Phos-Dev-12
  • 5% Carbon EBN-10-10 (superior graphite)
  • 5% PVDF
• Cell Configuration
  • Carbon-coated aluminium current collector 15
  • 1.54 cm² cathode
  • Electrolyte: Ethylene carbonate-Dimethyl carbonate (EC-DMC) 1-1 LiClO₄ 1M
  • Anode: Graphite or Hard Carbon with intercalated Metallic lithium
• Experimental conditions:
  • Room temperature
  • Voltage limits: 2.0 – 3.65 V
  • Charge: Up to C/1 rate up to 3.6 V, then constant voltage at 3.6 V until I < C/24

Usage [edit]

Garden lights [edit]

LFP cells are now used in some solar powered path lights instead of NiCd. Their higher working voltage allows a single cell to drive an LED without needing a step-up circuit. Some models that claim to be 24x brighter than baseline path lights.^{[citation needed]}

One Laptop per Child [edit]

This type of battery technology is used on the One Laptop per Child (OLPC) project.^[13] The batteries are manufactured by BYD Company of Shenzhen, China, the world's largest producer of Li-ion batteries.

OLPC uses LFP batteries in its XO laptops because they contain no toxic heavy metals in compliance with the European Union's Restriction of Hazardous Substances Directive.^[14]

Vehicles [edit]

LFP batteries were featured on the November 5, 2008 episode of Prototype This!. They were used as the power source for a hexapod (walking) vehicle.^{[citation needed]}

This battery is used in the electric cars made by Aptera^[15] and QUICC.^[16]

KillaCycle, the worlds fastest electric motorcycle, uses lithium iron phosphate batteries.^[17]

Many home EV conversions use the large format versions as the car's traction pack. With the efficient power to weight ratios, high safety features and the chemistry's refusal to go into thermal runaway, there are few barriers for use by amateur home "makers".

Roehr Motorcycle Company, uses a 5.8 kW·h capacity LFP battery pack to power its supersport electric motorcycle.^{[citation needed]}

LFP batteries are used by electric vehicles manufacturer Smith Electric Vehicles to power its products.^{[citation needed]}

ZBoard electric skateboards use LFP batteries, offering ranges up to 20 miles.

Golfskatecaddy Golf Skate Caddy electric single person golf vehicle use LFP batteries, allowing a full 18 holes of golf.

BYD, also a car manufacturer, plans to use its lithium iron phosphate batteries to power its PHEV, the F3DM and F6DM (Dual Mode), which will be the first commercial dual-mode electric car in the world. It plans to mass-produce the cars in 2009.^[18]

In May 2007 Lithium Technology Corp. announced a Lithium Iron Phosphate battery with cells large enough for use in hybrid cars, claiming they are "the largest cells of their kind in the world.".^[19]

Some electronic cigarettes use these types of batteries.[1]

Shorai Inc. makes lithium-iron batteries for a variety of powersport vehicles (motorcycles, ATVs, etc...)

Rimac Automobili have developed an advanced LFP battery system with integrated battery management and liquid cooling systems, primarily for their Concept One electric supercar which will enter production but also for commercial availability of the battery system.

RC model cars may use these batteries, especially as RX and TX packs as a direct replacement of NiMh packs or LiPo packs without need for voltage regulator, as they provide 6.6v nominal voltage over 7.4v of LiPo packs, which is little higher and may require to be regulated down to 6.0v.

See also [edit]

• Lithium battery
• Lithium-titanate battery
• Lithium–air battery
• Lithium-ion polymer battery
• Nanowire battery
• Phosphate
• Power-to-weight ratio
• Super iron battery
• Vanadium

References [edit]

v t e Galvanic cells Types Voltaic pile Battery Flow battery Trough battery Concentration cell Fuel cell Primary cell (non-rechargable) Alkaline Aluminium–air Bunsen Chromic acid Clark Daniell Dry Grove Leclanché Lithium Mercury Nickel oxyhydroxide Silicon–air Silver oxide Weston Zamboni Zinc–air Zinc–carbon Secondary cell (rechargeable) Automotive Lead–acid gel / VRLA Lithium–air Lithium–ion Lithium polymer Lithium iron phosphate Lithium–sulfur Lithium titanate Nanowire Nickel–cadmium Nickel–hydrogen Nickel–iron Nickel–lithium Nickel–metal hydride Nickel–zinc Polysulfide bromide Potassium-ion Rechargeable alkaline Sodium-ion Sodium–sulfur Vanadium redox Zinc–bromine Zinc–cerium Cell parts Anode Catalyst Cathode Electrolyte Half-cell Ions Salt bridge Semipermeable membrane