High-performance, nano-structured LiMnPO4 synthesized via a polyol method

“…One such example is LiMnPO4 [447][448][449][450][451][452][453][454][455][456][457][458], which is isostructural to that of olivine LiFePO4, while possessing a higher operating voltage (4.1 vs. 3.5 V, respectively) [378,448], and hence energy densities which could exceed 700 Wh kg -1 . At this point, it should be suggested that LiMnPO4 represents a more realistic candidate compared to LiCoPO4 or LiNiPO4, since the working voltage of LiCoPO4 or LiNiPO4 electrodes (4.9 and 5.1 V, respectively), currently lies outside regions of stability of the commonly-employed organic (carbonate) electrolytes [378].…”

Evaluating the performance of nanostructured materials as lithium-ion battery electrodes

“…One such example is LiMnPO4 [447][448][449][450][451][452][453][454][455][456][457][458], which is isostructural to that of olivine LiFePO4, while possessing a higher operating voltage (4.1 vs. 3.5 V, respectively) [378,448], and hence energy densities which could exceed 700 Wh kg -1 . At this point, it should be suggested that LiMnPO4 represents a more realistic candidate compared to LiCoPO4 or LiNiPO4, since the working voltage of LiCoPO4 or LiNiPO4 electrodes (4.9 and 5.1 V, respectively), currently lies outside regions of stability of the commonly-employed organic (carbonate) electrolytes [378].…”

Evaluating the performance of nanostructured materials as lithium-ion battery electrodes

“…The drawback of LiFePO 4 is a low potential (3.6 V vs. Li þ /Li), leading to a maximum energy density of 578 Wh kg À1 (170 mAh g À1 Â 3.6 V). In contrast, LiMnPO 4 has a higher potential (4.1 V vs. Li þ /Li) with 171 mAh g À1 theoretical capacity, thus providing a potentially 20% higher energy density of 701 Wh kg À1 (170 mAh g À1 Â 4.1 V) than that of LiFePO 4 . LiCoPO 4 and LiNiPO 4 have even higher cell potentials of 4.8 and 5.1 vs. Li þ /Li, respectively, but a lack of stable electrolytes at such high potentials, preventing their commercial application [7e9].…”

“…A twopronged approach in reducing the particle size of LiMnPO 4 on one hand and having a carbon coating on the surface of LiMnPO 4 particles on the other hand are most promising ways to obtain the high capacity due to the improvement of both ionic and electronic conductivity. Recently, Hatta et al reported a high rate capability using pyrolytic carbon and Li 3 PO 4 coating on rod shaped LiMnPO 4 nanoparticles, providing 160 and 145 mAh g À1 at 0.1C and 1C, respectively [10]. Platelet shaped LiMnPO 4 was reported to have a discharge capacity of 100 and 113 mAh g À1 at 1C at room temperature and 50 C, respectively [4].…”

“…Recently, Hatta et al reported a high rate capability using pyrolytic carbon and Li 3 PO 4 coating on rod shaped LiMnPO 4 nanoparticles, providing 160 and 145 mAh g À1 at 0.1C and 1C, respectively [10]. Platelet shaped LiMnPO 4 was reported to have a discharge capacity of 100 and 113 mAh g À1 at 1C at room temperature and 50 C, respectively [4].…”

“…Olivines typically consist of slightly distorted LiO 6 and MO 6 octahedra and PO 4 tetrahedra in the crystal structure [1,11,12]. For LiMnPO 4 with space group Pnma, the Li þ ion diffusion occurs in a zigzag-ed path along the b axis via edge sharing LiO 6 octahedra [13,14]. One way to improve the rate capability is thus to shorten the [010] diffusion path for Li þ ion release and insertion.…”

Nanoparticle shapes of LiMnPO4, Li+ diffusion orientation and diffusion coefficients for high volumetric energy Li+ ion cathodes

Synthesis of High Performance LiMn _0.8 Fe _0.2 PO ₄ /C Cathode Material for Lithium Ion Batteries: Effect of Calcination Temperature