Intercalation pathway in many-particle LiFePO4 electrode revealed by nanoscale state-of-charge mapping.

The intercalation pathway of lithium iron phosphate (LFP) in the positive electrode of a lithium-ion battery was probed at the ∼40 nm length scale using oxidation-state-sensitive X-ray microscopy. Combined with morphological observations of the same exact locations using transmission electron microscopy, we quantified the local state-of-charge of approximately 450 individual LFP particles over nearly the entire thickness of the porous electrode. With the electrode charged to 50% state-of-charge in 0.5 h, we observed that the overwhelming majority of particles were either almost completely delithiated or lithiated. Specifically, only ∼2% of individual particles were at an intermediate state-of-charge. From this small fraction of particles that were actively undergoing delithiation, we conclude that the time needed to charge a particle is ∼1/50 the time needed to charge the entire particle ensemble. Surprisingly, we observed a very weak correlation between the sequence of delithiation and the particle size, contrary to the common expectation that smaller particles delithiate before larger ones. Our quantitative results unambiguously confirm the mosaic (particle-by-particle) pathway of intercalation and suggest that the rate-limiting process of charging is initiating the phase transformation by, for example, a nucleation-like event. Therefore, strategies for further enhancing the performance of LFP electrodes should not focus on increasing the phase-boundary velocity but on the rate of phase-transformation initiation.

[1]  Yong‐Sheng Hu,et al.  Phase transformation and lithiation effect on electronic structure of Li(x)FePO4: an in-depth study by soft X-ray and simulations. , 2012, Journal of the American Chemical Society.

[2]  N. Sharma,et al.  Direct evidence of concurrent solid-solution and two-phase reactions and the nonequilibrium structural evolution of LiFePO4. , 2012, Journal of the American Chemical Society.

[3]  X. Sun,et al.  Soft X-ray XANES studies of various phases related to LiFePO4 based cathode materials , 2012 .

[4]  Yuki Yamada,et al.  Kinetics of Nucleation and Growth in Two-Phase Electrochemical Reaction of LixFePO4 , 2012 .

[5]  A. Yamada,et al.  Resonant Photoemission Spectroscopy of the Cathode Material LixFePO4for Lithium Ion Battery , 2011 .

[6]  Daniel A. Cogswell,et al.  Coherency strain and the kinetics of phase separation in LiFePO4 nanoparticles. , 2011, ACS nano.

[7]  E. F. Rauch,et al.  Confirmation of the domino-cascade model by lifepo4/fepo 4 precession electron diffraction , 2011 .

[8]  Michel Trudeau,et al.  In situ high-resolution transmission electron microscopy synthesis observation of nanostructured carbon coated LiFePO4 , 2011 .

[9]  Daniel A. Cogswell,et al.  Suppression of phase separation in LiFePO₄ nanoparticles during battery discharge. , 2011, Nano letters.

[10]  Rahul Malik,et al.  Kinetics of non-equilibrium lithium incorporation in LiFePO4. , 2011, Nature materials.

[11]  Wei Lai,et al.  Electrochemical modeling of single particle intercalation battery materials with different thermodynamics , 2011 .

[12]  Xiao‐Qing Yang,et al.  Investigation of the structural changes in Li1−xFePO4 upon charging by synchrotron radiation techniques , 2011 .

[13]  L. Nazar,et al.  Direct synthesis of nanocrystalline Li0.90FePO4: observation of phase segregation of anti-site defects on delithiation , 2011 .

[14]  Lin Gu,et al.  Direct observation of lithium staging in partially delithiated LiFePO4 at atomic resolution. , 2011, Journal of the American Chemical Society.

[15]  M. Safari,et al.  Mathematical Modeling of Lithium Iron Phosphate Electrode: Galvanostatic Charge/Discharge and Path Dependence , 2011 .

[16]  W. Craig Carter,et al.  Overpotential-Dependent Phase Transformation Pathways in Lithium Iron Phosphate Battery Electrodes , 2010 .

[17]  Thomas J. Richardson,et al.  Visualization of Charge Distribution in a Lithium Battery Electrode , 2010 .

[18]  Wolfgang Dreyer,et al.  The thermodynamic origin of hysteresis in insertion batteries. , 2010, Nature materials.

[19]  Krishna Garikipati,et al.  The Role of Coherency Strains on Phase Stability in LixFePO4: Needle Crystallites Minimize Coherency Strain and Overpotential , 2009 .

[20]  Marnix Wagemaker,et al.  The Role of Surface and Interface Energy on Phase Stability of Nanosized Insertion Compounds , 2009, Advanced materials.

[21]  Damian Burch,et al.  Size-dependent spinodal and miscibility gaps for intercalation in nanoparticles. , 2009, Nano letters.

[22]  Linda F Nazar,et al.  Proof of intercrystallite ionic transport in LiMPO(4) electrodes (M = Fe, Mn). , 2009, Journal of the American Chemical Society.

[23]  Alain Mauger,et al.  Study of the Li-insertion/extraction process in LiFePO4/FePO4 , 2009 .

[24]  Martin Z. Bazant,et al.  Intercalation dynamics in rechargeable battery materials : General theory and phase-transformation waves in LiFePO4 , 2008 .

[25]  W. Craig Carter,et al.  Electrochemically Induced Phase Transformation in Nanoscale Olivines Li1−xMPO4 (M = Fe, Mn) , 2008 .

[26]  C. Delmas,et al.  Lithium deintercalation in LiFePO4 nanoparticles via a domino-cascade model. , 2008, Nature materials.

[27]  Jeff Wolfenstine,et al.  Kinetic Study of the Electrochemical FePO 4 to LiFePO 4 Phase Transition , 2007 .

[28]  M. Wagemaker,et al.  Large impact of particle size on insertion reactions. A case for anatase Li(x)TiO2. , 2007, Journal of the American Chemical Society.

[29]  Charles Delacourt,et al.  Study of the LiFePO4/FePO4 Two-Phase System by High-Resolution Electron Energy Loss Spectroscopy , 2006 .

[30]  Thomas J. Richardson,et al.  Electron Microscopy Study of the LiFePO4 to FePO4 Phase Transition , 2006 .

[31]  Y. Chiang,et al.  Electronic structures of LiFePO 4 and FePO 4 studied using resonant inelastic x-ray scattering , 2006 .

[32]  Jinghua Guo,et al.  Electronic structure of phospho-olivines Li(x)FePO4 (x = 0, 1) from soft-x-ray-absorption and -emission spectroscopies. , 2005, The Journal of chemical physics.

[33]  Gerbrand Ceder,et al.  Electrochemical modeling of intercalation processes with phase field models , 2004 .

[34]  E. Anderson,et al.  Interferometer-controlled scanning transmission X-ray microscopes at the Advanced Light Source. , 2003, Journal of synchrotron radiation.

[35]  J. Dahn,et al.  Reducing Carbon in LiFePO4 / C Composite Electrodes to Maximize Specific Energy, Volumetric Energy, and Tap Density , 2002 .

[36]  A. Agui,et al.  The electronic structure of polyaniline and doped phases studied by soft X-ray absorption and emission spectroscopies , 1999, 1201.0976.

[37]  K. S. Nanjundaswamy,et al.  Phospho‐olivines as Positive‐Electrode Materials for Rechargeable Lithium Batteries , 1997 .

[38]  Koichi Eguchi,et al.  Effects of Anode Material and Fuel on Anodic Reaction of Solid Oxide Fuel Cells , 1992 .