| Original language | English |
|---|---|
| Title of host publication | ENCYCLOPEDIA OF ELECTROCHEMICAL POWER SOURCES |
| Editors | Chris Dyer, Patrick Moseley, Zempachi Ogumi, David Rand, Bruno Scrosati, Jurgen Garche |
| Place of Publication | Amsterdam |
| Publisher | Elsevier |
| Pages | 169-176 |
| Number of pages | 7 |
| ISBN (Electronic) | 978-0-444-52745-5 |
| ISBN (Print) | 978-0-444-52093-7 |
| Publication status | Published - Nov 2009 |
Abstract
Lithium ion polymer (LiPo or LiPoly) cells first appeared in consumer electronics in the mid-1990s. The technology for these devices evolved from previously established lithium ion (Li ion) cells. The difference between the two lies in the electrolyte; in Li ion batteries it consists of a lithium salt dissolved in a low molecular weight solvent, whereas a LiPo electrolyte is a polymer gel network.
Substitution of liquid electrolyte by a solid analog allows simplification of the cell structure, and many restrictions in terms of architecture and safety are eliminated. Three decades of R&D on solvent-free polyether-based electrolytes have seen many advances, but barriers still remain, restricting their commercial exploitation. Commercial viability was realized in polymer gel electrolytes, a compromise between the liquid and solvent-free systems.
The all-solid-state LiPo concept translates into a battery that can be shaped to suit the device it will power, is lighter, and can undergo denser packaging than its liquid electrolyte counterpart. The battery energy density is potentially much greater than that achieved by competing cell chemistries, including the Li ion cell. With recent advances in LiPo cell technology, the commercial balance between the Li ion and LiPo systems is expected to shift in favor of the latter.
Substitution of liquid electrolyte by a solid analog allows simplification of the cell structure, and many restrictions in terms of architecture and safety are eliminated. Three decades of R&D on solvent-free polyether-based electrolytes have seen many advances, but barriers still remain, restricting their commercial exploitation. Commercial viability was realized in polymer gel electrolytes, a compromise between the liquid and solvent-free systems.
The all-solid-state LiPo concept translates into a battery that can be shaped to suit the device it will power, is lighter, and can undergo denser packaging than its liquid electrolyte counterpart. The battery energy density is potentially much greater than that achieved by competing cell chemistries, including the Li ion cell. With recent advances in LiPo cell technology, the commercial balance between the Li ion and LiPo systems is expected to shift in favor of the latter.